Translesion synthesis past platinum DNA adducts by human DNA polymerase mu

DNA polymerase mu (pol mu) is a member of the pol X family of DNA polymerases, and it shares a number of characteristics of both DNA polymerase beta (pol beta) and terminal deoxynucleotidyl transferase (TdT). Because pol beta has been shown to perform translesion DNA synthesis past cisplatin (CP)- and oxaliplatin (OX)-GG adducts, we determined the ability of pol mu to bypass these lesions. Pol mu bypassed CP and OX adducts with an efficiency of 14-35% compared to chain elongation on undamaged DNA, which is second only to pol eta in terms of bypass efficiency. The relative ability of pol mu to bypass CP and OX adducts was dependent on both template structure and sequence context. Since pol mu has been shown to be more efficient on gapped DNA templates than on primed single-stranded DNA templates, we determined the ability of pol mu to bypass Pt-DNA adducts on both primed single-stranded and gapped templates. The bypass of Pt-DNA adducts by pol mu was highly error-prone on all templates, resulting in 2, 3, and 4 nt deletions. We postulate that bypass of Pt-DNA adducts by pol mu may involve looping out the Pt-GG adduct to allow chain elongation downstream of the adduct. This reaction appears to be facilitated by the presence of a downstream "acceptor" and a gap large enough to provide undamaged template DNA for elongation past the adduct, although gapped DNA is clearly not required for bypass.     

Efficient translesion replication past oxaliplatin and cisplatin GpG adducts by human DNA polymerase eta

Platinum anticancer agents form bulky DNA adducts which are thought to exert their cytotoxic effect by blocking DNA replication. Translesion synthesis, one of the pathways of postreplication repair, is thought to account for some resistance to DNA damage and much of the mutagenicity of bulky DNA adducts in dividing cells. Oxaliplatin has been shown to be effective in cisplatin-resistant cell lines and less mutagenic than cisplatin in the Ames assay. We have shown that the eukaryotic DNA polymerases yeast pol zeta, human pol beta, and human pol gamma bypass oxaliplatin-GG adducts more efficiently than cisplatin-GG adducts. Human pol eta, a product of the XPV gene, has been shown to catalyze efficient translesion synthesis past cis, syn-cyclobutane pyrimidine dimers. In the present study we compared translesion synthesis past different Pt-GG adducts by human pol eta. Our data show that, similar to other eukaryotic DNA polymerases, pol eta bypasses oxaliplatin-GG adducts more efficiently than cisplatin-GG adducts. However, pol eta-catalyzed translesion replication past Pt-DNA adducts was more efficient and less accurate than that seen for previously tested polymerases. We show that the efficiency and fidelity of translesion replication past Pt-DNA adducts appear to be determined by both the structure of the adduct and the DNA polymerase active site.     

The efficiency and fidelity of translesion synthesis past cisplatin and oxaliplatin GpG adducts by human DNA polymerase beta

DNA polymerase beta (pol beta) is the only mammalian DNA polymerase identified to date that can catalyze extensive bypass of platinum-DNA adducts in vitro. Previous studies suggest that DNA synthesis by pol beta is distributive on primed single-stranded DNA and processive on gapped DNA. The data presented in this paper provide an analysis of translesion synthesis past cisplatin- and oxaliplatin-DNA adducts by pol beta functioning in both distributive and processive modes using primer extension and steady-state kinetic experiments. Translesion synthesis past Pt-DNA adducts was greater with gapped DNA templates than with single-stranded DNA templates. In the processive mode pol beta did not discriminate between cisplatin and oxaliplatin adducts, while in the distributive mode it displayed about 2-fold increased ability for translesion synthesis past oxaliplatin compared with cisplatin adducts. The differentiation between cisplatin and oxaliplatin adducts resulted from a K(m)-mediated increase in the efficiency of dCTP incorporation across from the 3'-G of oxaliplatin-GG adducts. Rates of misincorporation across platinated guanines determined by the steady-state kinetic assay were higher in reactions with primed single-stranded templates than with gapped DNA and a slight increase in the misincorporation of dTTP across from the 3'-G was found for oxaliplatin compared with cisplatin adducts.     

Specificity of platinum-DNA adduct repair

Cell lines with resistance to cisplatin and carboplatin often retain sensitivity to platinum complexes with different carrier ligands (e.g., oxaliplatin and JM216). HeLa cell extracts were shown to excise cisplatin, oxaliplatin, and JM216 adducts with equal efficiency, suggesting that nucleotide excision repair does not contribute to the carrier-ligand specificity of platinum resistance. We have shown previously that the extent of replicative bypass in vivo is influenced by the carrier ligand of the platinum adducts. The specificity of replicative bypass may be determined by the DNA polymerase complexes that catalyze translesion synthesis past Pt-DNA adducts, by the mismatch-repair system that removes newly synthesized DNA opposite Pt-DNA adducts, and/or by DNA damage-recognition proteins that bind to the Pt-DNA adducts and block translesion synthesis. Primer extension on DNA templates containing site-specifically placed cisplatin, oxaliplatin, or JM216 Pt-GG adducts revealed that the eukaryotic DNA polymerases beta, zeta, gamma and HIV-1 RT had a similar specificity for translesion synthesis past Pt-DNA adducts (oxaliplatin > or = cisplatin > JM216). In addition, defects in the mismatch-repair proteins hMSH6 and hMLH1 led to increased replicative bypass of cisplatin adducts, but not of oxaliplatin adducts. Finally, primer extension assays performed in the presence of HMG1, which is known to recognize cisplatin-damaged DNA, revealed that inhibition of translesion synthesis by HMG1 also depended on the carrier ligand of the Pt-DNA adduct (cisplatin > oxaliplatin = JM216). These studies show that DNA polymerases, the mismatch-repair system and damage-recognition proteins can all impart specificity to replicative bypass of Pt-DNA adducts. Replicative bypass, in turn, may influence the carrier-ligand specificity of resistance.     

Frameshifts and deletions during in vitro translesion synthesis past Pt-DNA adducts by DNA polymerases beta and eta

DNA polymerases beta (pol beta ) and eta (pol eta ) are the only two eukaryotic polymerases known to efficiently bypass cisplatin and oxaliplatin adducts in vitro. Frameshift errors are an important aspect of mutagenesis. We have compared the types of frameshifts that occur during translesion synthesis past cisplatin and oxaliplatin adducts in vitro by pol beta and pol eta on a template containing multiple runs of nucleotides flanking a single platinum-GG adduct. Translesion synthesis past platinum adducts by pol beta resulted in approximately 50% replication products containing single-base deletions. For both adducts the majority of -1 frameshifts occurred in a TTT sequence 3-5 bp upstream of the DNA lesion. For pol eta, all of the bypass products for both cisplatin and oxaliplatin adducts contained -1 frameshifts in the upstream TTT sequence and most of the products of replication on oxaliplatin-damaged templates had multiple replication errors, both frameshifts and misinsertions. In addition, on platinated templates both polymerases generated replication products 4-8 bp shorter than the full-length products. The majority of short cisplatin-induced products contained an internal deletion which included the adduct. In contrast, the majority of oxaliplatin-induced short products contained a 3' terminal deletion. The implications of these in vitro results for in vivo mutagenesis are discussed.     

Flanking bases influence the nature of DNA distortion by platinum 1,2-intrastrand (GG) cross-links

The differences in efficacy and molecular mechanisms of platinum anti-cancer drugs cisplatin (CP) and oxaliplatin (OX) are thought to be partially due to the differences in the DNA conformations of the CP and OX adducts that form on adjacent guanines on DNA, which in turn influence the binding of damage-recognition proteins that control downstream effects of the adducts. Here we report a comprehensive comparison of the structural distortion of DNA caused by CP and OX adducts in the TGGT sequence context using nuclear magnetic resonance (NMR) spectroscopy and molecular dynamics (MD) simulations. When compared to our previous studies in other sequence contexts, these structural studies help us understand the effect of the sequence context on the conformation of Pt-GG DNA adducts. We find that both the sequence context and the type of Pt-GG DNA adduct (CP vs. OX) play an important role in the conformation and the conformational dynamics of Pt-DNA adducts, possibly explaining their influence on the ability of many damage-recognition proteins to bind to Pt-DNA adducts.     

Evading the proofreading machinery of a replicative DNA polymerase: induction of a mutation by an environmental carcinogen

DNA replication fidelity is dictated by DNA polymerase enzymes and associated proteins. When the template DNA is damaged by a carcinogen, the fidelity of DNA replication is sometimes compromized, allowing mispaired bases to persist and be incorporated into the DNA, resulting in a mutation. A key question in chemical carcinogenesis by metabolically activated polycyclic aromatic hydrocarbons (PAHs) is the nature of the interactions between the carcinogen-damaged DNA and the replicating polymerase protein that permits the mutagenic misincorporation to occur. PAHs are environmental carcinogens that, upon metabolic activation, can react with DNA to form bulky covalently linked combination molecules known as carcinogen-DNA adducts. Benzo[a]pyrene (BP) is a common PAH found in a wide range of material ingested by humans, including cigarette smoke, car exhaust, broiled meats and fish, and as a contaminant in other foods. BP is metabolically activated into several highly reactive intermediates, including the highly tumorigenic (+)-anti-benzo[a]pyrene diol epoxide (BPDE). The primary product of the reaction of (+)-anti-BPDE with DNA, the (+)-trans-anti-benzo[a]pyrene diol epoxide-N(2)-dG ((+)-ta-[BP]G) adduct, is the most mutagenic BP adduct in mammalian systems and primarily causes G-to-T transversion mutations, resulting from the mismatch of adenine with BP-damaged guanine during replication. In order to elucidate the structural characteristics and interactions between the DNA polymerase and carcinogen-damaged DNA that allow a misincorporation opposite a DNA lesion, we have modeled a (+)-ta-[BP]G adduct at a primer-template junction within the replicative phage T7 DNA polymerase containing an incoming dATP, the nucleotide most commonly mismatched with the (+)-ta-[BP]G adduct during replication. A one nanosecond molecular dynamics simulation, using AMBER 5.0, has been carried out, and the resultant trajectory analyzed. The modeling and simulation have revealed that a (+)-ta-[BP]G:A mismatch can be accommodated stably in the active site so that the fidelity mechanisms of the polymerase are evaded and the polymerase accepts the incoming mutagenic base. In this structure, the modified guanine base is in the syn conformation, with the BP moiety positioned in the major groove, without interfering with the normal protein-DNA interactions required for faithful polymerase function. This structure is stabilized by a hydrogen bond between the modified guanine base and dATP partner, hydrophobic interactions between the BP moiety and the polymerase, a hydrogen bond between the modified guanine base and the polymerase, and several hydrogen bonds between the BP moiety and polymerase side-chains. Moreover, the G:A mismatch in this system closely resembles the size and shape of a normal Watson-Crick pair. These features reveal how the polymerase proofreading machinery may be evaded in the presence of a mutagenic carcinogen-damaged DNA, so that a mismatch can be accommodated readily, allowing bypass of the adduct by the replicative T7 DNA polymerase.     

Efficiency and accuracy of SOS-induced DNA polymerases replicating benzo[a]pyrene-7,8-diol 9,10-epoxide A and G adducts.

Nucleotide incorporation fidelity, mismatch extension, and translesion DNA synthesis efficiencies were determined using SOS-induced Escherichia coli DNA polymerases (pol) II, IV, and V to copy 10R and 10S isomers of trans-opened benzo[a]pyrene-7,8-diol 9,10-epoxide (BaP DE) A and G adducts. A-BaP DE adducts were bypassed by pol V with moderate accuracy and considerably higher efficiency than by pol II or IV. Error-prone pol V copied G-BaP DE-adducted DNA poorly, forming A*G-BaP DE-S and -R mismatches over C*G-BaP DE-S and -R correct matches by factors of approximately 350- and 130-fold, respectively, even favoring G*G-BaP DE mismatches over correct matches by factors of 2-4-fold. In contrast, pol IV bypassed G-BaP DE adducts with the highest efficiency and fidelity, making misincorporations with a frequency of 10(-2) to 10(-4) depending on sequence context. G-BaP DE-S-adducted M13 DNA yielded 4-fold fewer plaques when transfected into SOS-induced DeltadinB (pol IV-deficient) mutant cells compared with the isogenic wild-type E. coli strain, consistent with the in vitro data showing that pol IV was most effective by far at copying the G-BaP DE-S adduct. SOS polymerases are adept at copying a variety of lesions, but the relative contribution of each SOS polymerase to copying damaged DNA appears to be determined by the lesion's identity.     

A single highly mutable catalytic site amino acid is critical for DNA polymerase fidelity

DNA polymerases contain active sites that are structurally superimposable and conserved in amino acid sequence. To probe the biochemical and structure-function relationship of DNA polymerases, a large library (200,000 members) of mutant Thermus aquaticus DNA polymerase I (Taq pol I) was created containing random substitutions within a portion of the dNTP binding site (Motif A; amino acids 605-617), and a fraction of all selected active Taq pol I (291 out of 8000) was tested for base pairing fidelity; seven unique mutants that efficiently misincorporate bases and/or extend mismatched bases were identified and sequenced. These mutants all contain substitutions of one specific amino acid, Ile-614, which forms part of the hydrophobic pocket that binds the base and ribose portions of the incoming nucleotide. Mutant Taq pol Is containing hydrophilic substitution I614K exhibit 10-fold lower base misincorporation fidelity, as well as a high propensity to extend mispairs. In addition, these low fidelity mutants containing hydrophilic substitution for Ile-614 can bypass damaged templates that include an abasic site and vinyl chloride adduct ethenoA. During polymerase chain reaction, Taq pol I mutant I614K exhibits an error rate that is >20-fold higher relative to the wild-type enzyme and efficiently catalyzes both transition and transversion errors. These studies have generated polymerase chain reaction-proficient mutant polymerases containing substitutions within the active site that confers low base pairing fidelity and a high error rate. Considering the structural and sequence conservation of Motif A, it is likely that a similar substitution will yield active low fidelity DNA polymerases that are mutagenic.     

Fidelity and processivity of Saccharomyces cerevisiae DNA polymerase eta

The yeast RAD30 gene functions in error-free replication of UV-damaged DNA, and RAD30 encodes a DNA polymerase, pol eta, that has the ability to efficiently and correctly replicate past a cis-syn-thymine-thymine dimer in template DNA. To better understand the role of pol eta in damage bypass, we examined its fidelity and processivity on nondamaged DNA templates. Steady-state kinetic analyses of deoxynucleotide incorporation indicate that pol eta has a low fidelity, misincorporating deoxynucleotides with a frequency of about 10(-2) to 10(-3). Also pol eta has a low processivity, incorporating only a few nucleotides before dissociating. We suggest that pol eta's low fidelity reflects a flexibility in its active site rendering it more tolerant of DNA damage, while its low processivity limits its activity to reduce errors.     

trans-Lesion synthesis past bulky benzo[a]pyrene diol epoxide N2-dG and N6-dA lesions catalyzed by DNA bypass polymerases

The effectiveness of in vitro primer elongation reactions catalyzed by human bypass DNA polymerases kappa (hDinB1), pol eta (hRad30A), pol iota (hRad30B), and yeast pol zeta (Rev3 and Rev7) in site-specifically modified template oligonucleotide strands were studied in vitro. The templates contained single bulky lesions derived from the trans-addition of the mutagenic (+)- or (-)-enantiomers of r7,t8-dihydroxy-t9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene (a metabolite of the environmental carcinogen benzo[a]pyrene), to the exocyclic amino groups of guanine or adenine in oligonucleotide templates 33, or more, bases long. In "running start" primer extension reactions, pol kappa effectively bypassed both the stereoisomeric (+)- and (-)-trans-guanine adducts but not the analogous adenine adducts. In sharp contrast, pol eta, which exhibits considerable sequence homology with pol kappa (both belong to the group of Y family polymerases), is partially blocked by the guanine adducts and the (-)-trans-adenine adduct, although the stereoisomeric (+)-trans-adenine adduct is more successfully bypassed. Neither pol iota nor pol zeta, either alone or in combination, were effective in trans-lesion synthesis past the same adducts. In all cases, the fidelity of insertion is dependent on adduct stereochemistry and structure. Generally, error-free nucleotide insertion opposite the lesions tends to depend more on adduct stereochemistry than error-prone insertion. None of the polymerases tested are a universal bypass polymerase for the stereoisomeric bulky polycyclic aromatic hydrocarbon-DNA adducts derived from anti-BPDE.     

Structural basis of accurate replication beyond a bulky major benzo[a]pyrene adduct by human DNA polymerase kappa

Human Y-family DNA polymerase kappa (polκ) is specialized to bypass bulky lesions in DNA in an error-free way, thus protecting cells from carcinogenic bulky DNA adducts. Benzo[a]pyrene (BP) is one of the most ubiquitous polycyclic aromatic hydrocarbons and an environmental carcinogen. BP covalently modifies DNA and generates mutagenic, bulky adducts. The major BP adduct formed in cells is 10S (+)-trans-anti-BP-N²-dG adduct (BP-dG), which is associated with cancer. The molecular mechanism of how polκ replicates BP-dG accurately is not clear. Here we report the structure of polκ captured at the lesion-extension stage: the enzyme is extending the primer strand after the base pair containing the BP-dG adduct in the template strand at the −1 position. Polκ accommodates the BP adduct in the nascent DNA’s minor groove and keeps the adducted DNA helix in a B-form. Two water molecules cover the edge of the minor groove of the replicating base pair (0 position), which is secured by the BP ring in the −1 position in a 5′ orientation. The 5′ oriented BP adduct keeps correct Watson-Crick base pairing in the active site and promotes high fidelity replication. Our structural and biochemical data reveal a unique molecular basis for accurate DNA replication right after the bulky lesion BP-dG.     

Biochemical Analysis of DNA Polymerase η Fidelity in the Presence of Replication Protein A

DNA polymerase η (pol η) synthesizes across from damaged DNA templates in order to prevent deleterious consequences like replication fork collapse and double-strand breaks. This process, termed translesion synthesis (TLS), is an overall positive for the cell, as cells deficient in pol η display higher mutation rates. This outcome occurs despite the fact that the in vitro fidelity of bypass by pol η alone is moderate to low, depending on the lesion being copied. One possible means of increasing the fidelity of pol η is interaction with replication accessory proteins present at the replication fork. We have previously utilized a bacteriophage based screening system to measure the fidelity of bypass using purified proteins. Here we report on the fidelity effects of a single stranded binding protein, replication protein A (RPA), when copying the oxidative lesion 7,8-dihydro-8-oxo-guanine(8-oxoG) and the UV-induced cis-syn thymine-thymine cyclobutane pyrimidine dimer (T-T CPD). We observed no change in fidelity dependent on RPA when copying these damaged templates. This result is consistent in multiple position contexts. We previously identified single amino acid substitution mutants of pol η that have specific effects on fidelity when copying both damaged and undamaged templates. In order to confirm our results, we examined the Q38A and Y52E mutants in the same full-length construct. We again observed no difference when RPA was added to the bypass reaction, with the mutant forms of pol η displaying similar fidelity regardless of RPA status. We do, however, observe some slight effects when copying undamaged DNA, similar to those we have described previously. Our results indicate that RPA by itself does not affect pol η dependent lesion bypass fidelity when copying either 8-oxoG or T-T CPD lesions.     

Effects of accessory proteins on the bypass of a cis-syn thymine-thymine dimer by Saccharomyces cerevisiae DNA polymerase eta

Among several hypotheses to explain how translesion synthesis (TLS) by DNA polymerase eta (pol eta) suppresses ultraviolet light-induced mutagenesis in vivo despite the fact that pol eta copies DNA with low fidelity, here we test whether replication accessory proteins enhance the fidelity of TLS by pol eta. We first show that the single-stranded DNA binding protein RPA, the sliding clamp PCNA, and the clamp loader RFC slightly increase the processivity of yeast pol eta and its ability to recycle to new template primers. However, these increases are small, and they are similar when copying an undamaged template and a template containing a cis-syn TT dimer. Consequently, the accessory proteins do not strongly stimulate the already robust TT dimer bypass efficiency of pol eta. We then perform a comprehensive analysis of yeast pol eta fidelity. We show that it is much less accurate than other yeast DNA polymerases and that the accessory proteins have little effect on fidelity when copying undamaged templates or when bypassing a TT dimer. Thus, although accessory proteins clearly participate in pol eta functions in vivo, they do not appear to help suppress UV mutagenesis by improving pol eta bypass fidelity per se.     

Extending the understanding of mutagenicity: structural insights into primer-extension past a benzo[a]pyrene diol epoxide-DNA adduct

DNA polymerase enzymes employ a number of innate fidelity mechanisms to ensure the faithful replication of the genome. However, when confronted with DNA damage, their fidelity mechanisms can be evaded, resulting in a mutation that may contribute to the carcinogenic process. The environmental carcinogen benzo[a]pyrene is metabolically activated to reactive intermediates, including the tumorigenic (+)-anti-benzo[a]pyrene diol epoxide, which can attack DNA at the exocyclic amino group of guanine to form the major (+)-trans-anti-[BP]-N(2)-dG adduct. Bulky adducts such as (+)-trans-anti-[BP]-N(2)-dG primarily block DNA replication, but are occasionally bypassed and cause mutations if paired with an incorrect base. In vitro standing-start primer-extension assays show that the preferential insertion of A opposite (+)-trans-anti-[BP]-N(2)-dG is independent of the sequence context, but the primer is extended preferentially when dT is positioned opposite the damaged base in a 5'-CG*T-3' sequence context. Regardless of the base positioned opposite (+)-trans-anti-[BP]-N(2)-dG, extension of the primer past the lesion site poses the greatest block to polymerase progression. In order to gain insight into primer-extension of each base opposite (+)-trans-anti-[BP]-N(2)-dG, we carried out molecular modeling and 1.25 ns unrestrained molecular dynamics simulations of the adduct in the +1 position of the template within the replicative pol I family T7 DNA polymerase. Each of the four bases was modeled at the 3' terminus of the primer, incorporated opposite the adduct, and the next-to-be replicated base was in the active site with its Watson-Crick partner as the incoming nucleotide. As in our studies of nucleotide incorporation, (+)-trans-anti-[BP]-N(2)-dG was modeled in the syn conformation in the +1 position, with the BP moiety on the open major groove side of the primer-template duplex region, leaving critical protein-DNA interactions intact. The present work revealed that the efficiency of primer-extension past this bulky adduct opposite each of the four bases in the 5'-CG*T-3' sequence can be rationalized by the stability of interactions between the polymerase protein, primer-template DNA and incoming nucleotide. However, the relative stabilization of each nucleotide opposite (+)-trans-anti-[BP]-N(2)-dG in the +1 position (T > G > A > or = C) differed from that when the adduct and partner were the nascent base-pair (A > T > or = G > C). In addition, extension past (+)-trans-anti-[BP]-N(2)-dG may pose a greater block to a high fidelity DNA polymerase than does nucleotide incorporation opposite the adduct because the presence of the modified base-pair in the +1 position is more disruptive to the polymerase-DNA interactions than it is within the active site itself. The dN:(+)-trans-anti-[BP]-N(2)-dG base-pair is strained to shield the bulky aromatic BP moiety from contact with the solvent in the +1 position, causing disruption of protein-DNA interactions that would likely result in decreased extension of the base-pair. These studies reveal in molecular detail the kinds of specific structural interactions that determine the function of a processive DNA polymerase when challenged by a bulky DNA adduct.     

Structure of a high fidelity DNA polymerase bound to a benzo[a]pyrene adduct that blocks replication

Of the carcinogens to which humans are most frequently exposed, the polycyclic aromatic hydrocarbon benzo[a]pyrene (BP) is one of the most ubiquitous. BP is a byproduct of grilled foods and tobacco and fuel combustion and has long been linked to various human cancers, particularly lung and skin. BP is metabolized to diol epoxides that covalently modify DNA bases to form bulky adducts that block DNA synthesis by replicative or high fidelity DNA polymerases. Here we present the structure of a high fidelity polymerase from a thermostable strain of Bacillus stearothermophilus (Bacillus fragment) bound to the most common BP-derived N2-guanine adduct base-paired with cytosine. The BP adduct adopts a conformation that places the polycyclic BP moiety in the nascent DNA minor groove and is the first structure of a minor groove adduct bound to a polymerase. Orientation of the BP moiety into the nascent DNA minor groove results in extensive disruption to the interactions between the adducted DNA duplex and the polymerase. The disruptions revealed by the structure of Bacillus fragment bound to a BP adduct provide a molecular basis for rationalizing the potent blocking effect on replication exerted by BP adducts.     

Effects of benzo[a]pyrene adduct stereochemistry on downstream DNA replication in vitro: evidence for different adduct conformations within the active site of DNA polymerase I (Klenow fragment)

The presence of bulky adducts in DNA is known to interfere with DNA replication not only at the site of the lesion but also at positions up to 5 nucleotides past the adduct location. Kinetic studies of primer extension by exonuclease-deficient E. coli DNA polymerase I (Klenow fragment) (KF) when (+)-trans- or (+)-cis-B[a]P-N(2)-dG adducts were positioned in the double-stranded region of the primer-templates showed that both stereoisomers significantly block downstream replication. However the (+)-cis adduct, which causes a stronger inhibition of the nucleotides insertion across from and immediately past the lesion, affected the downstream replication to a much smaller extent than did the (+)-trans adduct, especially when the B[a]P-modified dG was properly paired with a dC. The effects of mismatches across from the adduct and the sequence context surrounding the adduct were also dependent on the stereochemistry of the B[a]P adduct. Thus, the identity of the nucleotide across from the adduct that provided the best downstream replication was different for the (+)-cis and (+)-trans adducts, a factor that might differentially contribute to the mutagenic bypass of these lesions. These findings provide strong direct evidence that the conformations of the (+)-cis and (+)-trans adducts within the active site of KF are significantly different and probably differentially affect the interactions of the polymerase with the minor groove, thereby leading to different replication trends. The stereochemistry of the adduct was also found to differentially affect the sequence-mediated primer-template misalignments, resulting in different consequences during the bypass of the lesion.     

Translesion synthesis past equine estrogen-derived 2'-deoxyadenosine DNA adducts by human DNA polymerases eta and kappa

Hormone replacement therapy (HRT) increases the risk of developing breast, ovarian, and endometrial cancers. Equilin and equilenin are the major components of the widely prescribed drug used for HRT. 4-Hydroxyequilenin (4-OHEN), a major metabolite of equilin and equilenin, promotes 4-OHEN-modified dC, dA, and dG DNA adducts. These DNA adducts were detected in breast tumor and adjacent normal tissues of several patients receiving HRT. We have recently found that the 4-OHEN-dC DNA adduct is a highly miscoding lesion generating C --> T transitions and C --> G transversions. To explore the mutagenic potential of another major 4-OHEN-dA adduct, site-specifically modified oligodeoxynucleotides containing a single diastereoisomer of 4-OHEN-dA (Pk-1, Pk-2, and Pk-3) were prepared by a postsynthetic method and used as DNA templates for primer extension reactions catalyzed by human DNA polymerase (pol) eta and kappa that are highly expressed in the reproductive organs. Primer extension catalyzed by pol eta or pol kappa occurred rapidly on the unmodified template to form fully extended products. With the major 4-OHEN-dA-modified templates (Pk-2 and Pk-3), primer extension was retarded prior to the lesion and opposite the lesion; a fraction of the primers was extended past the lesion. Steady-state kinetic studies with pol eta and pol kappa indicated that dTMP, the correct base, was preferentially incorporated opposite the 4-OHEN-dA lesion. In addition, pol eta and pol kappa bypassed the lesion by incorporating dAMP and dCMP, respectively, opposite the lesion and extended past the lesion. The relative bypass frequency past the 4-OHEN-dA lesion with pol eta was at least 2 orders of magnitude higher than that observed with pol kappa. The bypass frequency past Pk-2 was more efficient than that past Pk-3. Thus, 4-OHEN-dA is a miscoding lesion generating A --> T transversions and A --> G transitions. The miscoding frequency and specificity of 4-OHEN-dA varied depending on the stereoisomer of the 4-OHEN-dA adduct and DNA polymerase used.     

Inefficient proofreading and biased error rates during inaccurate DNA synthesis by a mutant derivative of Saccharomyces cerevisiae DNA polymerase delta

DNA polymerase delta (pol delta) is a high fidelity eukaryotic enzyme that participates in DNA repair and is essential for DNA replication. Toward the goal of dissecting its multiple biological functions, here we describe the biochemical properties of Saccharomyces cerevisiae pol delta with a methionine replacing conserved leucine 612 at the polymerase active site. Compared with wild type pol delta, L612M pol delta has normal processivity and slightly higher polymerase specific activity. L612M pol delta also has normal 3' exonuclease activity, yet it is impaired in partitioning mismatches to the exonuclease active site, thereby reducing DNA synthesis fidelity. Error rates in vitro for L612M pol delta are elevated for both base substitutions and single base deletions but in a highly biased manner. For each of the six possible pairs of reciprocal mismatches that could arise during replication of complementary DNA strands to account for any particular base substitution in vivo (e.g. T-dGMP or A-dCMP for T to C transitions), L612M pol delta error rates are substantially higher for one mismatch than the other. These results provide a biochemical explanation for our observation, which confirms earlier genetic studies, that a haploid pol3-L612M S. cerevisiae strain has an elevated spontaneous mutation rate that is likely due to reduced replication fidelity in vivo.