Project description:1,N(6)-Ethenodeoxyadenosine (1,N(6)-ϵdA) is the major etheno lesion formed in the reaction of DNA with epoxides substituted with good leaving groups (e.g. vinyl chloride epoxide). This lesion is also formed endogenously in DNA from lipid oxidation. Recombinant human DNA polymerase η (hpol η) can replicate oligonucleotide templates containing 1,N(6)-ϵdA. In steady-state kinetic analysis, hpol η preferred to incorporate dATP and dGTP, compared with dTTP. Mass spectral analysis of incorporation products also showed preferred purine (A, G) incorporation and extensive -1 frameshifts, suggesting pairing of the inserted purine and slippage before further replication. Five x-ray crystal structures of hpol η ternary complexes were determined, three at the insertion and two at the extension stage. Two insertion complexes revealed incoming non-hydrolyzable dATP or dGTP analogs not pairing with but instead in a staggered configuration relative to 1,N(6)-ϵdA in the anti conformation, thus opposite the 5'-T in the template, explaining the proclivity for frameshift misincorporation. In another insertion complex, dTTP was positioned opposite 1,N(6)-ϵdA, and the adduct base was in the syn conformation, with formation of two hydrogen bonds. At the extension stage, with either an incorporated dA or dT opposite 1,N(6)-ϵdA and 2'-deoxythymidine-5'-[(α,β)-imido]triphosphate opposite the 5'-A, the 3'-terminal nucleoside of the primer was disordered, consistent with the tendency not to incorporate dTTP opposite 1,N(6)-ϵdA. Collectively, the results show a preference for purine pairing opposite 1,N(6)-ϵdA and for -1 frameshifts.

Project description:Intrastrand cross-links (IaCL) connecting two purine nucleobases in DNA pose a challenge to high-fidelity replication in the cell. Various repair pathways or polymerase bypass can cope with these lesions. The influence of the phosphodiester linkage between two neighboring 2'-deoxyguanosine (dG) residues attached through the O(6) atoms by an alkylene linker on bypass with human DNA polymerase ? (hPol ?) was explored in vitro. Steady-state kinetics and mass spectrometric analysis of products from nucleotide incorporation revealed that although hPol ? is capable of bypassing the 3'-dG in a mostly error-free fashion, significant misinsertion was observed for the 5'-dG of the IaCL containing a butylene or heptylene linker. The lack of the phosphodiester linkage triggered an important increase in frameshift adduct formation across the 5'-dG by hPol ?, in comparison to the 5'-dG of IaCL DNA containing the phosphodiester group.

Project description:Studies of replicative DNA polymerases have led to the generalization that abasic sites are strong blocks to DNA replication. Here we show that yeast replicative DNA polymerase epsilon bypasses a model abasic site with comparable efficiency to Pol eta and Dpo4, two translesion polymerases. DNA polymerase epsilon also exhibited high bypass efficiency with a natural abasic site on the template. Translesion synthesis primarily resulted in deletions. In cases where only a single nucleotide was inserted, dATP was the preferred nucleotide opposite the natural abasic site. In contrast to translesion polymerases, DNA polymerase epsilon with 3'-5' proofreading exonuclease activity bypasses only the model abasic site during processive synthesis and cannot reinitiate DNA synthesis. This characteristic may allow other pathways to rescue leading strand synthesis when stalled at an abasic site.

Project description:Abasic sites in genomic DNA can be a significant source of mutagenesis in biological systems, including human cancers. Such mutagenesis requires translesion DNA synthesis (TLS) bypass of the abasic site by specialized DNA polymerases. The abasic site bypass specificity of TLS proteins had been studied by multiple means in vivo and in vitro, although the generality of the conclusions reached have been uncertain. Here, we introduce a set of yeast reporter strains for investigating the in vivo specificity of abasic site bypass at numerous random positions within chromosomal DNA. When shifted to 37°C, these strains underwent telomere uncapping and resection that exposed reporter genes within a long 3' ssDNA overhang. Human APOBEC3G cytosine deaminase was expressed to create uracils in ssDNA, which were excised by uracil-DNA N-glycosylase. During repair synthesis, error-prone TLS bypassed the resulting abasic sites. Because of APOBEC3G's strict motif specificity and the restriction of abasic site formation to only one DNA strand, this system provides complete information about the location of abasic sites that led to mutations. We recapitulated previous findings on the roles of REV1 and REV3. Further, we found that sequence context can strongly influence the relative frequency of A or C insertion. We also found that deletion of Pol32, a non-essential common subunit of Pols ? and ?, resulted in residual low-frequency C insertion dependent on Rev1 catalysis. We summarize our results in a detailed model of the interplay between TLS components leading to error-prone bypass of abasic sites. Our results underscore the utility of this system for studying TLS bypass of many types of lesions within genomic DNA.

Project description:REV1, a Y family DNA polymerase (pol), is involved in replicative bypass past DNA lesions, so-called translesion DNA synthesis. In addition to a structural role as a scaffold protein, REV1 has been proposed to play a catalytic role as a dCTP transferase in translesion DNA synthesis past abasic and guanine lesions in eukaryotes. To better understand the catalytic function of REV1 in guanine lesion bypass, purified recombinant human REV1 was studied with two series of guanine lesions, N(2)-alkylG adducts (in oligonucleotides) ranging in size from methyl (Me) to CH(2)(6-benzo[a]pyrenyl) (BP) and O(6)-alkylG adducts ranging from Me to 4-oxo-4-(3-pyridyl)butyl (Pob). REV1 readily produced 1-base incorporation opposite G and all G adducts except for O(6)-PobG, which caused almost complete blockage. Steady-state kinetic parameters (k(cat)/K(m)) were similar for insertion of dCTP opposite G and N(2)-G adducts but were severely reduced opposite the O(6)-G adducts. REV1 showed apparent pre-steady-state burst kinetics for dCTP incorporation only opposite N(2)-BPG and little, if any, opposite G, N(2)-benzyl (Bz)G, or O(6)-BzG. The maximal polymerization rate (k(pol) 0.9 s(-1)) opposite N(2)-BPG was almost the same as opposite G, with only slightly decreased binding affinity to dCTP (2.5-fold). REV1 bound N(2)-BPG-adducted DNA 3-fold more tightly than unmodified G-containing DNA. These results and the lack of an elemental effect ((S(p))-2'-deoxycytidine 5'-O-(1-thiotriphosphate)) suggest that the late steps after product formation (possibly product release) become rate-limiting in catalysis opposite N(2)-BPG. We conclude that human REV1, apparently the slowest Y family polymerase, is kinetically highly tolerant to N(2)-adduct at G but not to O(6)-adducts.

Project description:O?-Methylguanine (O?-MeG) is a mutagenic DNA lesion, arising from the action of methylating agents on guanine (G) in DNA. Dpo4, an archaeal low-fidelity Y-family DNA polymerase involved in translesion DNA synthesis (TLS), is a model for studying how human Y-family polymerases bypass DNA adducts. Previous work showed that Dpo4-mediated dTTP incorporation is favored opposite O?-MeG rather than opposite G. However, factors influencing the preference of Dpo4 to incorporate dTTP opposite O?-MeG are not fully defined. In this study, we investigated the influence of structural features of incoming dNTPs on their enzymatic incorporation opposite O?-MeG in a DNA template. To this end, we utilized a new fluorescence-based primer extension assay to evaluate the incorporation efficiency of a panel of synthetic dNTPs opposite G or O?-MeG by Dpo4. In single-dNTP primer extension studies, the synthetic dNTPs were preferentially incorporated opposite G, relative to O?-MeG. Moreover, pyrimidine-based dNTPs were generally better incorporated than purine-based syn-conformation dNTPs. The results suggest that hydrophobicity of the incoming dNTP appears to have little influence on the process of nucleotide selection by Dpo4, with hydrogen bonding capacity being a major influence. Additionally, modifications at the C2-position of dCTP increase the selectivity for incorporation opposite O?-MeG without a significant loss of efficiency.

Project description:DNA polymerase (pol) iota, a member of the mammalian Y-family of DNA polymerases involved in translesion DNA synthesis, has been previously suggested to peculiarly utilize Hoogsteen base pairing for DNA synthesis opposite template purines, unlike pols eta and kappa, which utilize Watson-Crick (W-C) base pairing. To investigate the possible roles of Hoogsteen, W-C, and wobble base-pairing modes in the selection of nucleotides opposite template pyrimidines by human pol iota, we carried out kinetic analyses of incorporation of modified purine nucleoside triphosphates including 7-deazapurines, inosine, 2-aminopurine, 2,6-diaminopurine, and 6-chloropurine, which affect H-bonding in base-pair formation opposite template pyrimidines. Carbon substitution at the N7 atom of purine nucleoside triphosphates, which disrupts Hoogsteen base pairing, only slightly inhibited DNA synthesis opposite template pyrimidines by pol iota, which was not substantially different from human pols eta and kappa. Opposite template T, only the relative wobble stabilities (inferred from the potential numbers of H-bonding, steric, and electrostatic interactions but not measured) of base pairs were positively correlated to the relative efficiencies of nucleotide incorporation by pol iota but not the relative W-C or Hoogsteen stabilities, unlike pols eta and kappa. In contrast, opposite C, only the relative W-C stabilities of base pairs were positively correlated to the relative efficiencies of nucleotide incorporation by pol iota, as with pols eta and kappa. These results suggest that pol iota might not indispensably require Hoogsteen base pairing for DNA synthesis opposite pyrimidines but rather might prefer wobble base pairing in the selection of nucleotides opposite T and W-C base pairing opposite C.

Project description:Human DNA polymerase ? (pol?) has been suggested to play a role in cisplatin resistance, especially in pol?-overexpressing cancer cells. Pol? has been shown to accurately albeit slowly bypass the cisplatin-1,2-d(GpG) (Pt-GG) intramolecular cross-link in vitro. Currently, the structural basis for the inefficient Pt-GG bypass mechanism of pol? is unknown. To gain structural insights into the mechanism, we determined two ternary structures of pol? incorporating dCTP opposite the templating Pt-GG lesion in the presence of the active site Mg(2+) or Mn(2+). The Mg(2+)-bound structure shows that the bulky Pt-GG adduct is accommodated in the pol? active site without any steric hindrance. In addition, both guanines of the Pt-GG lesion form Watson-Crick base pairing with the primer terminus dC and the incoming dCTP, providing the structural basis for the accurate bypass of the Pt-GG adduct by pol?. The Mn(2+)-bound structure shows that pol? adopts a catalytically suboptimal semiclosed conformation during the insertion of dCTP opposite the templating Pt-GG, explaining the inefficient replication across the Pt-GG lesion by pol?. Overall, our studies provide the first structural insights into the mechanism of the potential pol?-mediated cisplatin resistance.

Project description:O(6)-methylguanine (O(6)-methylG) is highly mutagenic and is commonly found in DNA exposed to methylating agents, even physiological ones (e.g. S-adenosylmethionine). The efficiency of a truncated, catalytic DNA polymerase ? core enzyme was determined for nucleoside triphosphate incorporation opposite O(6)-methylG, using steady-state kinetic analyses. The results presented here corroborate previous work from this laboratory using full-length pol ?, which showed that dTTP incorporation occurs with high efficiency opposite O(6)-methylG. Misincorporation of dTTP opposite O(6)-methylG occurred with ?6-fold higher efficiency than incorporation of dCTP. Crystal structures of the truncated form of pol ? with O(6)-methylG as the template base and incoming dCTP or dTTP were solved and showed that O(6)-methylG is rotated into the syn conformation in the pol ? active site and that dTTP misincorporation by pol ? is the result of Hoogsteen base pairing with the adduct. Both dCTP and dTTP base paired with the Hoogsteen edge of O(6)-methylG. A single, short hydrogen bond formed between the N3 atom of dTTP and the N7 atom of O(6)-methylG. Protonation of the N3 atom of dCTP and bifurcation of the N3 hydrogen between the N7 and O(6) atoms of O(6)-methylG allow base pairing of the lesion with dCTP. We conclude that differences in the Hoogsteen hydrogen bonding between nucleotides is the main factor in the preferential selectivity of dTTP opposite O(6)-methylG by human pol ?, in contrast to the mispairing modes observed previously for O(6)-methylG in the structures of the model DNA polymerases Sulfolobus solfataricus Dpo4 and Bacillus stearothermophilus DNA polymerase I.

Project description:The ability of DNA polymerases to maintain the integrity of the genome even after it has been structurally altered is vital. There is considerable interest in determining the structural properties of the DNA template that polymerases recognize when determining which nucleotide to add to a nascent strand. Mechanistic, synthetic, and structural chemistries have been used to study how DNA polymerase activity is affected by size, shape, pi-stacking, and hydrogen bonds of the template molecules. Herein, we probe the structural aspects of abasic lesions that result in their distinct coding potential in Escherichia coli despite lacking a Watson-Crick base. In particular, we investigate why bypass of 2-deoxyribonolactone (L) results in significant amounts of dG incorporation opposite the lesion, whereas other abasic lesions (e.g., AP) adhere to the "A-rule". Experiments using synthetic analogues reveal that DNA polymerase V bypasses L and increased levels of dG incorporation result from a hydrogen bonding interaction between the carbonyl oxygen and dG. These results show that a DNA polymerase utilizes hydrogen bonding as one structural parameter when decoding an abasic lesion.