Base sequence dependence of in vitro translesional DNA replication past a bulky lesion catalyzed by the exo- Klenow fragment of Pol I

Translesion synthesis past guanine(C8)-thymine(N3) intrastrand cross-links catalyzed by selected A- and Y-family polymerases

Oxidatively generated guanine radicals in DNA can undergo various nucleophilic reactions including the formation of C8-guanine cross-links with adjacent or nearby N3-thymines in DNA in the presence of O2. These G[8-3]T lesions have been identified in the DNA of human cells exposed to oxidative stress, and are most likely genotoxic if not removed by cellular defence mechanisms. The abilities of several representative polymerases to bypass the G[8-3]T lesions in two different sequence contexts, G*T* and G*CT*, were assessed in vitro. The polymerase BF (bacillus fragment) from Bacillus stearothermophilus, the Y-family archaeal polymerases Dpo4 from Sulfolobus sulfataricus P2, and human DNA pol κ and pol η were selected for the study. The A-family polymerase BF was strongly blocked, while relatively weak translesion synthesis was observed in the case of Y-family polymerases Dpo4 and pol κ. Primer extension catalyzed by pol η was also partially stalled at various positions at or near the G[8-3]T cross-linked bases, but a significant and distributive primer extension was observed beyond the sites of the lesions with the efficiency being consistently greater in the case of G*CT* than in the case of G*T* lesions. The results obtained with pol η are compared with translesion synthesis past other intrastrand cross-linked lesions with previously published results of others that include the isomeric G[8-5m]T lesions generated by ionizing radiation, the cis-syn cyclobutane pyrimidine dimer and the 6-4 photoproduct generated by UV irradiation, and the Pt-G*G* lesions derived from the reactions of the chemotherapeutic agent cisplatin with DNA.

Visualizing sequence-governed nucleotide selectivities and mutagenic consequences through a replicative cycle: processing of a bulky carcinogen N2-dG lesion in a Y-family DNA polymerase

Understanding how DNA polymerases process lesions remains fundamental to determining the molecular origins of mutagenic translesion bypass. We have investigated how a benzo[a]pyrene-derived N(2)-dG adduct, 10S-(+)-trans-anti-[BP]-N(2)-dG ([BP]G*), is processed in Dpo4, the well-characterized Y-family bypass DNA polymerase. This polymerase has a slippage-prone spacious active site region. Experimental results in a 5'-C[BP]G*G-3' sequence context reveal significant selectivity for dGTP insertion that predominantly yields -1 deletion extension products. A less pronounced error-prone nonslippage pathway that leads to full extension products with insertion of A > C > G opposite the lesion is also observed. Molecular modeling and dynamics simulations follow the bypass of [BP]G* through an entire replication cycle for the first time in Dpo4, providing structural interpretations for the experimental observations. The preference for dGTP insertion is explained by a 5'-slippage pattern in which the unmodified G rather than G* is skipped, the incoming dGTP pairs with the C on the 5'-side of G*, and the -1 deletion is produced upon further primer extension which is more facile than nucleotide insertion. In addition, the simulations suggest that the [BP]G* may undergo an anti/syn conformational rearrangement during the stages of the replication cycle. In the minor nonslippage pathway, the nucleotide insertion preferences opposite the lesion are explained by relative distortions to the active site region. These structural insights, provided by the modeling and dynamics studies, augment kinetic and limited available crystallographic investigations with bulky lesions, by providing molecular explanations for lesion bypass activities over an entire replication cycle.

Lesion processing: high-fidelity versus lesion-bypass DNA polymerases

When a high-fidelity DNA polymerase encounters certain DNA-damage sites, its progress can be stalled and one or more lesion-bypass polymerases are recruited to transit the lesion. Here, we consider two representative types of lesions: (i) 7,8-dihydro-8-oxoguanine (8-oxoG), a small, highly prevalent lesion caused by oxidative damage; and (ii) bulky lesions derived from the environmental pre-carcinogen benzo[a]pyrene, in the high-fidelity DNA polymerase Bacillus fragment (BF) from Bacillus stearothermophilus and in the lesion-bypass DNA polymerase IV (Dpo4) from Sulfolobus solfataricus. The tight fit of the BF polymerase around the nascent base pair contrasts with the more spacious, solvent-exposed active site of Dpo4, and these differences in architecture result in distinctions in their respective functions: one-step versus stepwise polymerase translocation, mutagenic versus accurate bypass of 8-oxoG, and polymerase stalling versus mutagenic bypass at bulky benzo[a]pyrene-derived lesions.

Nucleotide selectivity opposite a benzo[a]pyrene-derived N2-dG adduct in a Y-family DNA polymerase: a 5'-slippage mechanism

The Y-family DNA polymerase Dpo4, from the archaeon bacterium Sulfolobus solfataricus, is a member of the DinB family, which also contains human Pol kappa. It has a spacious active site that can accommodate two templating bases simultaneously, with one of them skipped by the incoming dNTP. Assays of single dNTP insertion opposite a benzo[ a]pyrene-derived N (2)-dG adduct, 10 S(+)- trans- anti-[BP]- N (2)-dG ([BP]G*), reveal that an incoming dATP is significantly preferred over the other three dNTPs in the TG 1*G 2 sequence context. Molecular modeling and dynamics simulations were carried out to interpret this experimental observation on a molecular level. Modeling studies suggest that the significant preference for dATP insertion observed experimentally can result from two possible dATP incorporation modes. The dATP can be inserted opposite the T on the 5' side of the adduct G 1*, using an unusual 5'-slippage pattern, in which the unadducted G 2, rather than G 1*, is skipped, to produce a -1 deletion. In addition, the dATP can be misincorporated opposite the adduct. The 5'-slippage pattern may be generally facilitated in cases where the base 3' to the lesion is the same as the adducted base.

Single-stranded DNA-binding protein in vitro eliminates the orientation-dependent impediment to polymerase passage on CAG/CTG repeats

Small insertions and deletions of trinucleotide repeats (TNRs) can occur by polymerase slippage and hairpin formation on either template or newly synthesized strands during replication. Although not predicted by a slippage model, deletions occur preferentially when 5'-CTG is in the lagging strand template and are highly favored over insertion events in rapidly replicating cells. The mechanism for the deletion bias and the orientation dependence of TNR instability is poorly understood. We report here that there is an orientation-dependent impediment to polymerase progression on 5'-CAG and 5'-CTG repeats that can be relieved by the binding of single-stranded DNA-binding protein. The block depends on the primary sequence of the TNR but does not correlate with the thermodynamic stability of hairpins. The orientation-dependent block of polymerase passage is the strongest when 5'-CAG is the template. We propose a "template-push" model in which the slow speed of DNA polymerase across the 5'-CAG leading strand template creates a threat to helicase-polymerase coupling. To prevent uncoupling, the TNR template is pushed out and by-passed. Hairpins do not cause the block, but appear to occur as a consequence of polymerase pass-over.

Following an environmental carcinogen N2-dG adduct through replication: elucidating blockage and bypass in a high-fidelity DNA polymerase

We have investigated how a benzo[a]pyrene-derived N²-dG adduct, 10S(+)-trans-anti-[BP]-N²-dG ([BP]G*), is processed in a well-characterized Pol I family model replicative DNA polymerase, Bacillus fragment (BF). Experimental results are presented that reveal relatively facile nucleotide incorporation opposite the lesion, but very inefficient further extension. Computational studies follow the possible bypass of [BP]G* through the pre-insertion, insertion and post-insertion sites as BF alternates between open and closed conformations. With dG* in the normal B-DNA anti conformation, BP seriously disturbs the polymerase structure, positioning itself either deeply in the pre-insertion site or on the crowded evolving minor groove side of the modified template, consistent with a polymerase-blocking conformation. With dG* in the less prevalent syn conformation, BP causes less distortion: it is either out of the pre-insertion site or in the major groove open pocket of the polymerase. Thus, the syn conformation can account for the observed relatively easy incorporation of nucleotides, with mutagenic purines favored, opposite the [BP]G* adduct. However, with the lesion in the BF post-insertion site, more serious distortions caused by the adduct even in the syn conformation explain the very inefficient extension observed experimentally. In vivo, a switch to a potentially error-prone bypass polymerase likely dominates translesion bypass.

Increased flexibility enhances misincorporation: temperature effects on nucleotide incorporation opposite a bulky carcinogen-DNA adduct by a Y-family DNA polymerase

The Y-family DNA polymerase Dpo4, from the thermophilic crenarchaeon Sulfolobus solfataricus P2, offers a valuable opportunity to investigate the effect of conformational flexibility on the bypass of bulky lesions because of its ability to function efficiently at a wide range of temperatures. Combined molecular modeling and experimental kinetic studies have been carried out for 10S-(+)-trans-anti-[BP]-N2-dG ((+)-ta-[BP]G), a lesion derived from the covalent reaction of a benzo[a]pyrene metabolite with guanine in DNA, at 55 degrees C and results compared with an earlier study at 37 degrees C (Perlow-Poehnelt, R. A., Likhterov, I., Scicchitano, D. A., Geacintov, N. E., and Broyde, S. (2004) J. Biol. Chem. 279, 36951-36961). The experimental results show that there is more overall nucleotide insertion opposite (+)-ta-[BP]G due to particularly enhanced mismatch incorporation at 55 degrees C compared with 37 degrees C. The molecular dynamics simulations suggest that mismatched nucleotide insertion opposite (+)-ta-[BP]G is increased at 55 degrees C compared with 37 degrees C because the higher temperature shifts the preference of the damaged base from the anti to the syn conformation, with the carcinogen on the more open major groove side. The mismatched dNTP structures are less distorted when the damaged base is syn than when it is anti, at the higher temperature. However, with the normal partner dCTP, the anti conformation with close to Watson-Crick alignment remains more favorable. The molecular dynamics simulations are consistent with the kcat values for nucleotide incorporation opposite the lesion studied, providing structural interpretation of the experimental observations. The observed temperature effect suggests that conformational flexibility plays a role in nucleotide incorporation and bypass fidelity opposite (+)-ta-[BP]G by Dpo4.

Flow cytometric detection of tandem repeat mutations induced by various chemical classes

To facilitate detection of genotoxicity from environmental mutagen exposure, we generated an in vitro enhanced green fluorescence protein (EGFP) reactivation assay that quickly and effectively detects frameshift mutations in tandem repeat sequences (TRS). Two murine cell lines, C3H10T1/2 and mismatch repair deficient MC2a, were stably transfected with EGFP reporter plasmids in which the EGFP constructs contain TRS that put the EGFP sequence out of frame. These included several 2, 3, 4, 5 and 6 bp repeat sequences, a control non-repetitive sequence and a human gene sequence containing a 4 bp repeat motif. Transfected cultures were exposed to five model mutagens and carcinogens: hydrogen peroxide (H(2)O(2)), 12-O-tetradecanoyl-phorbol-13-acetate (TPA), benzo-a-pyrene-diol-epoxide (BPDE), ethyl nitrosourea (ENU), 9-aminoacridine (9AA) and two controls: acetone and ethanol. Frameshift mutations resulted in green fluorescent revertants, as determined by flow cytometry, and were confirmed, for 9AA treatments, by sequencing. All five treatments with model agents induced statistically significant sequence- and exposure-dependent responses in MC2a cells and a negative response with the two negative control treatments, acetone and ethanol. Similar responses were seen in a smaller panel of treatments and plasmids in C3H10T1/2 cells. The mutation frequencies were higher in cells transfected with the plasmids containing TRS than those harbouring the control construct lacking repeats. The highest mutation frequencies were observed with H(2)O(2) and 9AA treatments, yielding up to a 50-fold difference between vehicle and highest concentration treatment. ENU, BPDE, and to a lesser extent TPA treatments, also showed a statistically significant exposure response. Results from these experiments reveal that the assay responds robustly to various classes of mutagenic substances, as well as to rodent carcinogens that are inactive in conventional mutation assays, and that responses are not linked to cytotoxicity. This assay is a promising approach for detecting chemically induced frameshifts within certain DNA sequences of interest, but further characterization and validation are required prior to general use in genotoxicity screening.

Accommodation of a 1S-(-)-benzo[c]phenanthrenyl-N6-dA adduct in the Y-family Dpo4 DNA polymerase active site: structural insights through molecular dynamics simulations

Molecular modeling and molecular dynamics simulations have been performed to elucidate feasible structures in the Y-family Dpo4 DNA polymerase for the 1S-(-)-trans-anti-B[c]Ph-N6-dA adduct, derived from the fjord region polycyclic aromatic hydrocarbon (PAH) benzo[c]phenanthrene. Three types of models were delineated as follows: an intercalation model, a model with the aromatic ring system in the polymerase major groove open pocket, and a -1 deletion major groove model. All four 2'-deoxyribonucleoside 5'-triphosphates (dNTPs) were considered in the first two cases, and a normal Watson-Crick partner positioned to have skipped the modified template was employed as the incoming dNTP in the -1 deletion case. The trajectories derived from the dynamics simulations were analyzed in detail to evaluate the extents of distortion for each system. Overall, our results suggest that the major groove model is the least distorted, followed by the -1 deletion model, while the intercalation model is perturbed the most. The syn-dGTP and syn-dATP mismatches opposite the lesion are well-accommodated in the major groove model, as is the normal Watson-Crick partner dTTP. The intercalation model appears most likely to impede the polymerase. More broadly, these models look reasonable for other PAH metabolite-derived adducts to adenine with similar 1S stereochemistry. Furthermore, these models suggest how error-prone translesion synthesis by Y-family polymerases might produce mutations that may play a role in the initiation of cancer.

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.

Kinetics of nucleotide incorporation opposite DNA bulky guanine N2 adducts by processive bacteriophage T7 DNA polymerase (exonuclease-) and HIV-1 reverse transcriptase

Six oligonucleotides with carcinogen derivatives bound at the N2 atom of deoxyguanosine were prepared, including adducts derived from butadiene, acrolein, crotonaldehyde, and styrene, and examined for effects on the replicative enzymes bacteriophage DNA polymerase T7- (T7-) and HIV-1 reverse transcriptase for comparison with previous work on smaller DNA adducts. All of these adducts strongly blocked dCTP incorporation opposite the adducts. dATP was preferentially incorporated opposite the acrolein and crotonaldehyde adducts, and dTTP incorporation was preferred at the butadiene- and styrene-derived adducts. Steady-state kinetic analysis indicated that the reduced catalytic efficiency with adducted DNA involved both an increased Km and attenuated kcat. Fluorescence estimates of Kd and pre-steady-state kinetic measurements of koff showed no significantly decreased affinity of T7- with the adducted oligonucleotides or the dNTP. Pre-steady-state kinetics showed no burst phase kinetics for dNTP incorporation with any of the modified oligonucleotides. These results indicate that phosphodiester bond formation or a conformational change of the enzyme.DNA complex is rate-limiting instead of the step involving release of the oligonucleotide. Thio elemental effects for dNTP incorporation were generally relatively small but variable, indicating that the presence of adducts may sometimes make phosphodiester bond formation rate-limiting but not always.

The spacious active site of a Y-family DNA polymerase facilitates promiscuous nucleotide incorporation opposite a bulky carcinogen-DNA adduct: elucidating the structure-function relationship through experimental and computational approaches

Y-family DNA polymerases lack some of the mechanisms that replicative DNA polymerases employ to ensure fidelity, resulting in higher error rates during replication of undamaged DNA templates and the ability to bypass certain aberrant bases, such as those produced by exposure to carcinogens, including benzo[a]pyrene (BP). A tumorigenic metabolite of BP, (+)-anti-benzo-[a]pyrene diol epoxide, attacks DNA to form the major 10S (+)-trans-anti-[BP]-N(2)-dG adduct, which has been shown to be mutagenic in a number of prokaryotic and eukaryotic systems. The 10S (+)-trans-anti-[BP]-N(2)-dG adduct can cause all three base substitution mutations, and the SOS response in Escherichia coli increases bypass of bulky adducts, suggesting that Y-family DNA polymerases are involved in the bypass of such lesions. Dpo4 belongs to the DinB branch of the Y-family, which also includes E. coli pol IV and eukaryotic pol kappa. We carried out primer extension assays in conjunction with molecular modeling and molecular dynamics studies in order to elucidate the structure-function relationship involved in nucleotide incorporation opposite the bulky 10S (+)-trans-anti-[BP]-N(2)-dG adduct by Dpo4. Dpo4 is able to bypass the 10S (+)-trans-anti-[BP]-N(2)-dG adduct, albeit to a lesser extent than unmodified guanine, and the V(max) values for insertion of all four nucleotides opposite the adduct by Dpo4 are similar. Computational studies suggest that 10S (+)-trans-anti-[BP]-N(2)-dG can be accommodated in the active site of Dpo4 in either the anti or syn conformation due to the limited protein-DNA contacts and the open nature of both the minor and major groove sides of the nascent base pair, which can contribute to the promiscuous nucleotide incorporation opposite this lesion.

Dynamic conformational heterogeneities of carcinogen-DNA adducts and their mutagenic relevance

Arylamines and polycyclic aromatic hydrocarbons (PAHs), which are known as "bulky" carcinogens, have been studied extensively and upon activation in vivo, react with cellular DNA to form DNA-adducts. The available structure data accumulated thus far has revealed that conformational heterogeneity is a common theme among duplex DNA modified with these carcinogens. Several conformationally diverse structures have been elucidated and found to be in equilibrium in certain cases. The dynamics of the heterogeneity appear to be modulated by the nature of the adduct structure and the base sequences neighboring the lesion site. These can be termed as "adduct- and sequence-induced conformational heterogeneities," respectively. Due to the small energy differences, the population levels of these conformers could readily be altered within the active sites of repair or replicate enzymes. Thus, the complex role of "enzyme-induced conformational heterogeneity" must also be taken into consideration for the establishment of a functional structure-mutation relationship. Ultimately, a major challenge in mutation structural biology is to carry out adduct- and site-specific experiments in a conformationally specific manner within biologically relevant environments. Results from such experiments should provide an accurate account of how a single chemically homogenous adduct gives rise to complex multiple mutations, the earliest step in the induction of cancer.

The thermodynamics of template-directed DNA synthesis: base insertion and extension enthalpies

We used stopped-flow calorimetry to measure the overall enthalpy change associated with template-directed nucleotide insertion and DNA extension. Specifically, we used families of hairpin self-priming templates in conjunction with an exonuclease-free DNA polymerase to study primer extension by one or more dA or dT residues. Our results reveal exothermic heats between -9.8 and -16.0 kcal/bp for template-directed enzymatic polymerization. These extension enthalpies depend on the identity of the inserting base, the primer terminus, and/or the preceding base. Despite the complexity of the overall process, the sign, magnitude, and sequence dependence of these insertion and extension enthalpies are consistent with nearest-neighbor data derived from DNA melting studies. We recognize that the overall process studied here involves contributions from a multitude of events, including dNTP to dNMP hydrolysis, phosphodiester bond formation, and enzyme conformational changes. It is therefore noteworthy that the overall enthalpic driving force per base pair is of a magnitude similar to that expected for addition of one base pair or base stack per insertion event, rather than that associated with the rupture and/or formation of covalent bonds, as occurs during this catalytic process. Our data suggest a constant sequence-independent background of compensating enthalpic contributions to the overall process of DNA synthesis, with discrimination expressed by differences in noncovalent interactions at the template-primer level. Such enthalpic discrimination underscores a model in which complex biological events are regulated by relatively modest energy balances involving weak interactions, thereby allowing subtle mechanisms of regulation.

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.

Two-step error-prone bypass of the (+)- and (-)-trans-anti-BPDE-N2-dG adducts by human DNA polymerases eta and kappa

Benzo[a]pyrene is a polycyclic aromatic hydrocarbon (PAH) associated with potent carcinogenic activity. Mutagenesis induced by benzo[a]pyrene DNA adducts is believed to involve error-prone translesion synthesis opposite the lesion. However, the DNA polymerase involved in this process has not been clearly defined in eukaryotes. Here, we provide biochemical evidence suggesting a role for DNA polymerase eta (Poleta) in mutagenesis induced by benzo[a]pyrene DNA adducts in cells. Purified human Poleta predominantly inserted an A opposite a template (+)- and (-)-trans-anti-BPDE-N2-dG, two important DNA adducts of benzo[a]pyrene. Both lesions also dramatically elevated G and T mis-insertion error rates of human Poleta. Error-prone nucleotide insertion by human Poleta was more efficient opposite the (+)-trans-anti-BPDE-N2-dG adduct than opposite the (-)-trans-anti-BPDE-N2-dG. However, translesion synthesis by human Poleta largely stopped opposite the lesion and at one nucleotide downstream of the lesion (+1 extension). The limited extension synthesis of human Poleta from opposite the lesion was strongly affected by the stereochemistry of the trans-anti-BPDE-N2-dG adducts, the nucleotide opposite the lesion, and the sequence context 5' to the lesion. By combining the nucleotide insertion activity of human Poleta and the extension synthesis activity of human Polkappa, effective error-prone lesion bypass was achieved in vitro in response to the (+)- and (-)-trans-anti-BPDE-N2-dG DNA adducts.

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.

DNA adducts from a tumorigenic metabolite of benzo[a]pyrene block human RNA polymerase II elongation in a sequence- and stereochemistry-dependent manner

Many carcinogens exert their cancer-causing effects by reacting with DNA either directly or following metabolic activation, resulting in covalently linked combination molecules known as carcinogen-DNA adducts. The presence of such lesions in the genome increases the error frequency of the replication machinery, causing mutations that contribute to the initiation and progression of cancer. Cellular DNA repair pathways remove carcinogen adducts from DNA, thus averting the mutagenic potential of many DNA lesions by reducing their presence in the genome. Bulky DNA adducts, like those derived from a number of activated environmental carcinogens such as polycyclic aromatic hydrocarbons (PAHs), are primarily repaired by the nucleotide excision repair (NER) pathway. Transcription-coupled NER (TC-NER) preferentially removes lesions from the transcribed strand of actively expressed genes, and RNA polymerase II stalled at the lesion quite possibly initiates the pathway. Among the bulky DNA adducts that are subject to TC-NER are those resulting from the reaction of the metabolically activated PAH benzo[a]pyrene (BP) with DNA. The P450 mixed-function oxygenases convert BP into a number of reactive intermediates, including tumorigenic (+)- and non-tumorigenic (-)-anti-benzo[a]pyrene diol epoxide (BPDE) that react with DNA via trans epoxide opening to form (+)-trans-anti-[BP]-N(2)-dG ((+)-ta[BP]G) and (-)-trans-anti-[BP]-N(2)-dG ((-)-ta[BP]G), respectively. To test the effect of these lesions on RNA synthesis, in vitro transcription assays using human nuclear extracts were performed with DNA templates containing an RNAPII promoter and a stereochemically pure (+)- or (-)-ta[BP]G adduct on the transcribed or non-transcribed strand. Transcription past (+)- or (-)-ta[BP]G adducts was investigated in the same sequence context to examine stereochemical effects. The (+)-ta[BP]G adduct was investigated in two different local sequence contexts to determine if the surrounding bases influence the adduct's ability to block transcription. These experiments revealed that (+)- and (-)-ta[BP]G adducts on the transcribed strand of the DNA template block RNAPII in a sequence and stereochemistry-dependent manner; however, adducts on the non-transcribed strand do not block elongation significantly but may increase pausing at innate pause sites. In order to elucidate biologically influential differences between the (+)- and (-)-ta[BP]G structures, the DUPLEX program was used to carry out potential energy minimization searches at model transcription junctions. The lowest-energy minimum for the (+)-ta[BP]G adduct gives a structure in which the benzo[a]pyrenyl ring system resides in the minor groove of the heteroduplex region. In contrast, the lowest-energy minimum for a (-)-ta[BP]G adduct shows an orientation in which the benzo[a]pyrenyl group adopts a carcinogen/base-stacked conformation. These conformational preferences may contribute to the differential treatment of (+)- and (-)-ta[BP]G adducts by human RNAPII. In addition, while previous experiments showed that BPDE adducts cause T7RNAP to produce a ladder of truncated transcripts, RNAPII is blocked entirely at only one or two positions by the (+)- and (-)-ta[BP]G adducts, depending on sequence context. It is likely that these differences between the behaviors of T7RNAP and human RNAPII are a result of the structural characteristics of the enzymes' active sites, a hypothesis that is explored in light of their known crystal structures.