8-hydroxyguanine and purine

Replicative DNA polymerases are high fidelity enzymes that misincorporate nucleotides into nascent DNA with a frequency lower than [1/10(5)], and this precision is improved to about [1/10(7)] by their proofreading activity. Because this fidelity is insufficient to replicate most genomes without error, nature evolved postreplicative mismatch repair (MMR), which improves the fidelity of DNA replication by up to 3 orders of magnitude through correcting biosynthetic errors that escaped proofreading. MMR must be able to recognize non-Watson-Crick base pairs and excise the misincorporated nucleotides from the nascent DNA strand, which carries by definition the erroneous genetic information. In eukaryotes, MMR is believed to be directed to the nascent strand by preexisting discontinuities such as gaps between Okazaki fragments in the lagging strand or breaks in the leading strand generated by the mismatch-activated endonuclease of the MutL homologs PMS1 in yeast and PMS2 in vertebrates. We recently demonstrated that the eukaryotic MMR machinery can make use also of strand breaks arising during excision of uracils or ribonucleotides from DNA. We now show that intermediates of MutY homolog-dependent excision of adenines mispaired with 8-oxoguanine (G(O)) also act as MMR initiation sites in extracts of human cells or Xenopus laevis eggs. Unexpectedly, G(O)/C pairs were not processed in these extracts and failed to affect MMR directionality, but extracts supplemented with exogenous 8-oxoguanine DNA glycosylase (OGG1) did so. Because OGG1-mediated excision of G(O) might misdirect MMR to the template strand, our findings suggest that OGG1 activity might be inhibited during MMR.

Topics: Adenosine Triphosphatases; Animals; Base Pair Mismatch; Base Sequence; Carrier Proteins; DNA; DNA Damage; DNA Glycosylases; DNA Mismatch Repair; DNA Repair Enzymes; DNA Replication; DNA-Binding Proteins; DNA-Directed DNA Polymerase; Female; Guanine; HCT116 Cells; Humans; Mismatch Repair Endonuclease PMS2; Molecular Sequence Data; MutL Proteins; Oocytes; Oxidation-Reduction; Purines; Saccharomyces cerevisiae Proteins; Xenopus laevis

A theoretical density functional theory (DFT, B3LYP) investigation has been carried out on the catalytic cycle responsible for the glycosylase activity of the human DNA repair protein hOGG1: enzyme activation, cleavage of the glycosidic bond, and expulsion of the damaged base. An unprecedented large quantum mechanics (QM) model system has been used, which includes a complete oxoG molecule, the deoxyribose ring bonded to the phosphate groups, and most of the surrounding residues that simulate the protein binding pocket. It has been found that Asp268 does not play any role in Lys249 activation and that the oxoG basis acts as a coenzyme, triggering nucleophile activation by Lys249 deprotonation. An SN2 nucleophilic attack by Lys249 on the anomeric carbon then follows. This is the rate-determining step of the process with an activation barrier of 16.7 kcal mol(-1) in good agreement with the experimental value of 17.1 kcal mol(-1). The expelled oxoG plays again as an enzyme cofactor at the end of the process by activating (via proton transfer) ribose ring opening and Schiff base formation. This study suggests a recurring catalytic strategy in the enzymatic cleavage of purine nucleoside where the activation of the leaving group by protonation of the nucleoside base (via an enzymatic general acid) triggers the cleavage of the glycosidic bond.

Topics: Binding Sites; Computer Simulation; Crystallography, X-Ray; DNA Glycosylases; DNA Repair; Guanine; Humans; Models, Chemical; Models, Molecular; Molecular Conformation; N-Glycosyl Hydrolases; Protein Conformation; Purines

Human DNA polymerase iota (Pol iota) differs from other DNA polymerases in that it exhibits a marked template specificity, being more efficient and accurate opposite template purines than opposite pyrimidines. The crystal structures of Pol iota with template A and incoming dTTP and with template G and incoming dCTP have revealed that in the Pol iota active site, the templating purine adopts a syn conformation and forms a Hoogsteen base pair with the incoming pyrimidine which remains in the anti conformation. By using 2-aminopurine and purine as the templating residues, which retain the normal N7 position but lack the N(6) of an A or the O(6) of a G, here we provide evidence that whereas hydrogen bonding at N(6) is dispensable for the proficient incorporation of a T opposite template A, hydrogen bonding at O(6) is a prerequisite for C incorporation opposite template G. To further analyze the contributions of O(6) and N7 hydrogen bonding to DNA synthesis by Pol iota, we have examined its proficiency for replicating through the (6)O-methyl guanine and 8-oxoguanine lesions, which affect the O(6) and N7 positions of template G, respectively. We conclude from these studies that for proficient T incorporation opposite template A, only the N7 hydrogen bonding is required, but for proficient C incorporation opposite template G, hydrogen bonding at both the N7 and O(6) is an imperative. The dispensability of N(6) hydrogen bonding for proficient T incorporation opposite template A has important biological implications, as that would endow Pol iota with the ability to replicate through lesions which impair the Watson-Crick hydrogen bonding potential at both the N1 and N(6) positions of templating A.

Topics: Base Pairing; Cytosine; DNA Damage; DNA Polymerase iota; DNA Primers; DNA-Directed DNA Polymerase; Guanine; Humans; Hydrogen Bonding; Kinetics; Purines; Templates, Genetic; Thymine