8-hydroxyguanine and 2--deoxyadenosine-triphosphate

8-Oxoguanine (8-oxoG) is a common oxidative lesion frequently encountered by DNA polymerases such as the repair enzyme DNA polymerase beta (pol beta). To interpret in atomic and energetic detail how pol beta processes 8-oxoG, we apply transition path sampling to delineate closing pathways of pol beta 8-oxoG complexes with dCTP and dATP incoming nucleotides and compare the results to those of the nonlesioned G:dCTP and G:dATPanalogues.. Our analyses show that the closing pathways of the 8-oxoG complexes are different from one another and from the nonlesioned analogues in terms of the individual transition states along each pathway, associated energies, and the stability of each pathway's closed state relative to the corresponding open state. In particular, the closed-to-open state stability difference in each system establishes a hierarchy of stability (from high to low) as G:C > 8-oxoG:C > 8-oxoG:A > G:A, corresponding to -3, -2, 2, 9 kBT, respectively. This hierarchy of closed state stability parallels the experimentally observed processing efficiencies for the four pairs. Network models based on the calculated rate constants in each pathway indicate that the closed species are more populated than the open species for 8-oxoG:dCTP, whereas the opposite is true for 8-oxoG:dATP.. These results suggest that the lower insertion efficiency (larger Km) for dATP compared to dCTP opposite 8-oxoG is caused by a less stable closed-form of pol beta, destabilized by unfavorable interactions between Tyr271 and the mispair. This stability of the closed vs. open form can also explain the higher insertion efficiency for 8-oxoG:dATP compared to the nonlesioned G:dATP pair, which also has a higher overall conformational barrier. Our study offers atomic details of the complexes at different states, in addition to helping interpret the different insertion efficiencies of dATP and dCTP opposite 8-oxoG and G.

Topics: Binding Sites; Deoxyadenine Nucleotides; Deoxycytosine Nucleotides; DNA Polymerase beta; Guanine; Kinetics; Nucleic Acid Conformation; Templates, Genetic; Tyrosine

Specialized DNA polymerases (DNA pols) are required for lesion bypass in human cells. Auxiliary factors have an important, but so far poorly understood, role. Here we analyse the effects of human proliferating cell nuclear antigen (PCNA) and replication protein A (RP-A) on six different human DNA pols--belonging to the B, Y and X classes--during in vitro bypass of different lesions. The mutagenic lesion 8-oxo-guanine (8-oxo-G) has high miscoding potential. A major and specific effect was found for 8-oxo-G bypass with DNA pols lambda and eta. PCNA and RP-A allowed correct incorporation of dCTP opposite a 8-oxo-G template 1,200-fold more efficiently than the incorrect dATP by DNA pol lambda, and 68-fold by DNA pol eta, respectively. Experiments with DNA-pol-lambda-null cell extracts suggested an important role for DNA pol lambda. On the other hand, DNA pol iota, together with DNA pols alpha, delta and beta, showed a much lower correct bypass efficiency. Our findings show the existence of an accurate mechanism to reduce the deleterious consequences of oxidative damage and, in addition, point to an important role for PCNA and RP-A in determining a functional hierarchy among different DNA pols in lesion bypass.

Topics: Animals; Deoxyadenine Nucleotides; Deoxycytosine Nucleotides; DNA Damage; DNA Replication; DNA-Directed DNA Polymerase; Fibroblasts; Guanine; Humans; Mice; Oxidation-Reduction; Proliferating Cell Nuclear Antigen; Replication Protein A; Substrate Specificity; Templates, Genetic

8-OxoGua (8-oxo-7,8-dihydroguanine) is produced in nucleic acids as well as in nucleotide pools of cells, by reactive oxygen species normally formed during cellular metabolic processes. MutT protein of Escherichia coli specifically degrades 8-oxoGua-containing deoxyribo- and ribonucleoside triphosphates to corresponding nucleoside monophosphates, thereby preventing misincorporation of 8-oxoGua into DNA and RNA, which would cause mutation and phenotypic suppression, respectively. Here, we report that the MutT protein has additional activities for cleaning up the nucleotide pools to ensure accurate DNA replication and transcription. It hydrolyzes 8-oxo-dGDP to 8-oxo-dGMP with a K(m) of 0.058 microM, a value considerably lower than that for its normal counterpart, dGDP (170 microM). Furthermore, the MutT possesses an activity to degrade 8-oxo-GDP to the related nucleoside monophosphate, with a K(m) value 8000 times lower than that for GDP. These multiple enzyme activities of the MutT protein would facilitate the high fidelity of DNA and RNA syntheses.

Topics: Deoxyadenine Nucleotides; Deoxycytosine Nucleotides; Deoxyguanine Nucleotides; DNA Replication; DNA, Bacterial; Escherichia coli Proteins; Guanine; Guanosine Triphosphate; Hydrolysis; Kinetics; Multienzyme Complexes; Phosphoric Monoester Hydrolases; Pyrophosphatases; RNA, Bacterial; Thymine Nucleotides; Transcription, Genetic

Oxidative damage to DNA generates 8-oxo-7,8-dihydro-2'-deoxyguanosine (8-oxodG). During DNA replication and repair synthesis, 8-oxodG can pair with cytosine or adenine. The ability to accurately replicate through this lesion depends on the DNA polymerase. We report the first structure of a polymerase with a promutagenic DNA lesion, 8-oxodG, in the confines of its active site. The modified guanine residue is in an anti conformation and forms Watson-Crick hydrogen bonds with an incoming dCTP. To accommodate the oxygen at C8, the 5'-phosphate backbone of the templating nucleotide flips 180 degrees. Thus, the flexibility of the template sugar-phosphate backbone near the polymerase active site is one parameter that influences the anti-syn equilibrium of 8-oxodG. Our results provide insights into the mechanisms employed by polymerases to select the complementary dNTP.

Topics: Binding Sites; Deoxyadenine Nucleotides; DNA Damage; DNA Polymerase beta; DNA Repair; DNA Replication; Guanine; Humans; Models, Molecular; Molecular Structure; Nucleic Acid Conformation; Protein Structure, Tertiary

Escherichia coli polymerases (pol) I exo-(KF-) and pol II exo- (pol II-) were used as model enzymes with a DNA primer/template complex (12/16-mer) to examine the kinetics of incorporation of dCTP and dATP at the site of an 8-oxo-7,8-dihydroguanine (8-oxoGua) residue; compared to guanine (Gua). In steady-state assays (with DNA in excess) the rate of incorporation (kcat) was dCTP > dATP and the K(m),dATP < K(m),dCTP during incorporation opposite 8-oxoGua with both polymerases. Pre-steady-state kinetic curves (rapid-quench analysis) for the addition of C opposite 8-oxoGua or Gua by KF- and pol II- were all biphasic, with a rapid initial single-turnover burst followed by a slower multiple turnover rate, while addition of A opposite 8-oxoGua did not display burst kinetics with either enzyme. Reduced rates of incorporation of the dCTP alpha S and dATP alpha S phosphorothioate analogs suggest that the rates of incorporation of A and C opposite 8-oxoGua are limited during polymerization by the rate of phosphodiester bond formation. Neither polymerase appears to discriminate between adducted and nonadducted DNA substrate for binding. Kinetic assays performed with varying dCTP concentrations indicate that dCTP has a higher K(d) and lower k(p) (polymerization rate) for incorporation opposite 8-oxoGua compared to Gua. Furthermore, the dATP binding affinities with KF- and pol II- were approximately 10- and approximately 3-fold lower, respectively, than that of dCTP as determined in competition assays with mixtures of dCTP and dATP. Microscopic rate constants were estimated by mathematical analysis of dNTP concentration dependence curves. Both polymerases preferentially extended the A:8-oxoGua pair while extension of the C:8-oxoGua pair was greatly impaired. Based on these findings, the fidelity of KF- and pol II- during replication of 8-oxoGua depends on contributions from nucleotide binding, the rate of phosphodiester bond formation, and the ease of base pair extension.

Topics: Base Composition; Base Sequence; Deoxyadenine Nucleotides; Deoxycytosine Nucleotides; Deoxyribonucleotides; DNA Polymerase I; DNA Polymerase II; DNA Primers; DNA, Bacterial; Escherichia coli; Guanine; Kinetics; Molecular Sequence Data; Oligodeoxyribonucleotides; Substrate Specificity; Templates, Genetic