Mammalian translesion DNA synthesis across an acrolein-derived deoxyguanosine adduct. Participation of DNA polymerase eta in error-prone synthesis in human cells

alpha-OH-PdG, an acrolein-derived deoxyguanosine adduct, inhibits DNA synthesis and miscodes significantly in human cells. To probe the cellular mechanism underlying the error-free and error-prone translesion DNA syntheses, in vitro primer extension experiments using purified DNA polymerases and site-specific alpha-OH-PdG were conducted. The results suggest the involvement of pol eta in the cellular error-prone translesion synthesis. Experiments with xeroderma pigmentosum variant cells, which lack pol eta, confirmed this hypothesis. The in vitro results also suggested the involvement of pol iota and/or REV1 in inserting correct dCMP opposite alpha-OH-PdG during error-free synthesis. However, none of translesion-specialized DNA polymerases catalyzed significant extension from a dC terminus when paired opposite alpha-OH-PdG. Thus, our results indicate the following. (i) Multiple DNA polymerases are involved in the bypass of alpha-OH-PdG in human cells. (ii) The accurate and inaccurate syntheses are catalyzed by different polymerases. (iii) A modification of the current eukaryotic bypass model is necessary to account for the accurate bypass synthesis in human cells.     

Responses to the major acrolein-derived deoxyguanosine adduct in Escherichia coli

Acrolein, a reactive alpha,beta-unsaturated aldehyde found ubiquitously in the environment and formed endogenously in mammalian cells, reacts with DNA to form an exocyclic DNA adduct, 3H-8-hydroxy-3-(beta-D-2'-deoxyribofuranosyl)-5,6,7,8-tetrahydropyrido[3,2-a]purine-9-one (gamma-OH-PdG). The cellular processing and mutagenic potential of gamma-OH-PdG have been examined, using a site-specific approach in which a single adduct is embedded in double-strand plasmid DNA. Analysis of progeny plasmid reveals that this adduct is excised by nucleotide excision repair. The apparent level of inhibition of DNA synthesis is approximately 70% in Escherichia coli DeltarecA, uvrA. The block to DNA synthesis can be overcome partially by recA-dependent recombination repair. Targeted G --> T transversions were observed at a frequency of 7 x 10(-4)/translesion synthesis. Inactivation of polB, dinB, and umuD,C genes coding for "SOS" DNA polymerases did not affect significantly the efficiency or fidelity of translesion synthesis. In vitro primer extension experiments revealed that the Klenow fragment of polymerase I catalyzes error-prone synthesis, preferentially incorporating dAMP and dGMP opposite gamma-OH-PdG. We conclude from this study that DNA polymerase III catalyzes translesion synthesis across gamma-OH-PdG in an error-free manner. Nucleotide excision repair, recombination repair, and highly accurate translesion synthesis combine to protect E. coli from the potential genotoxicity of this DNA adduct.     

Activities of human DNA polymerase kappa in response to the major benzo[a]pyrene DNA adduct: error-free lesion bypass and extension synthesis from opposite the lesion

In cells, the major benzo[a]pyrene DNA adduct is the highly mutagenic (+)-trans-anti-BPDE-N(2)-dG. In eukaryotes, little is known about lesion bypass of this DNA adduct during replication. Here, we show that purified human Polkappa can effectively bypass a template (+)-trans-anti-BPDE-N(2)-dG adduct in an error-free manner. Kinetic parameters indicate that Polkappa bypass of the (-)-trans-anti-BPDE-N(2)-dG adduct was approximately 41-fold more efficient compared to the (+)-trans-anti-BPDE-N(2)-dG adduct. Furthermore, we have found another activity of human Polkappa in response to the (+)- and (-)-trans-anti-BPDE-N(2)-dG adducts: extension synthesis from mispaired primer 3' ends opposite the lesion. In contrast, the two adducts strongly blocked DNA synthesis by the purified human Polbeta and the purified catalytic subunits of yeast Polalpha, Poldelta, and Pol epsilon right before the lesion. Extension by human Polkappa from the primer 3' G opposite the (+)- and (-)-trans-anti-BPDE-N(2)-dG adducts was mediated by a -1 deletion mechanism, probably resulting from re-aligning the primer G to pair with the next template C by Polkappa prior to DNA synthesis. Thus, sequence contexts 5' to the lesion strongly affect the fidelity and mechanism of the Polkappa-catalyzed extension synthesis. These results support a dual-function model of human Polkappa in bypass of BPDE DNA adducts: it may function both as an error-free bypass polymerase alone and an extension synthesis polymerase in combination with another polymerase.     

Protein-template-directed synthesis across an acrolein-derived DNA adduct by yeast Rev1 DNA polymerase

Acrolein is generated as the end product of lipid peroxidation and is also a ubiquitous environmental pollutant. Its reaction with the N2 of guanine leads to a cyclic gamma-HOPdG adduct that presents a block to normal replication. We show here that yeast Rev1 incorporates the correct nucleotide C opposite a permanently ring-closed form of gamma-HOPdG (PdG) with nearly the same efficiency as opposite an undamaged G. The structural basis of this action lies in the eviction of the PdG adduct from the Rev1 active site, and the pairing of incoming dCTP with a "surrogate" arginine residue. We also show that yeast Polzeta can carry out the subsequent extension reaction. Together, our studies reveal how the exocyclic PdG adduct is accommodated in a DNA polymerase active site, and they show that the combined action of Rev1 and Polzeta provides for accurate and efficient synthesis through this potentially carcinogenic DNA lesion.     

Translesion synthesis by human DNA polymerase kappa on a DNA template containing a single stereoisomer of dG-(+)- or dG-(-)-anti-N(2)-BPDE (7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene)

Several recently discovered human DNA polymerases are associated with translesion synthesis past DNA adducts. These include human DNA polymerase kappa (pol kappa), a homologue of Escherichia coli pol IV, which enhances the frequency of spontaneous mutation. Using a truncated form of pol kappa (pol kappa Delta C), translesion synthesis past dG-(+)- or dG-(-)-anti-N(2)-BPDE (7,8-dihydroxy-anti-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene) adducts was explored. Site-specifically-modified oligodeoxynucleotides containing a single stereoisomeric dG-N(2)-BPDE lesion were used as DNA templates for primer extension reactions catalyzed by pol kappa Delta C. Primer extension was retarded one base prior to the dG-N(2)-BPDE lesion; when incubated for longer times or with higher concentration of enzyme, full primer extension was observed. Quantitative analysis of fully extended products showed preferential incorporation of dCMP, the correct base, opposite all four stereoisomeric dG-N(2)-BPDE lesions. (+)-trans-dG-N(2)-BPDE, a major BPDE-DNA adduct, promoted small amounts of dTMP, dAMP, and dGMP misincorporation opposite the lesion (total 2.7% of the starting primers) and deletions (1.1%). Although (+)-cis-dG-N(2)-BPDE was most effective in blocking translesion synthesis, its miscoding properties were similar to other dG-N(2)-BPDE isomers. Steady-state kinetic data indicate that dCMP is efficiently inserted opposite all dG-N(2)-BPDE adducts and extended past these lesions. The relative frequency of translesion synthesis (F(ins) x F(ext)) of dC.dG-N(2)-BPDE pairs was 2-6 orders of magnitude higher than that of other mismatched pairs. Pol kappa may play an important role in translesion synthesis by incorporating preferentially the correct base opposite dG-N(2)-BPDE. Its relatively low contribution to mutagenicity suggests that other newly discovered DNA polymerase(s) may be involved in mutagenic events attributed to dG-N(2)-BPDE adducts in human cells.     

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.     

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.     

Miscoding potential of the N2-ethyl-2'-deoxyguanosine DNA adduct by the exonuclease-free Klenow fragment of Escherichia coli DNA polymerase I

Acetaldehyde, a major metabolite of ethanol, reacts with dG residues in DNA, resulting in the formation of the N(2)-ethyl-2'-deoxyguanosine (N(2)-Et-dG) adduct. This adduct has been detected in lymphocyte DNA of alcohol abusers. To explore the miscoding property of the N(2)-Et-dG DNA adduct, phosphoramidite chemical synthesis was used to prepare site-specifically modified oligodeoxynucleotides containing a single N(2)-Et-dG. These N(2)-Et-dG-modified oligodeoxynucleotides were used as templates for primer extension reactions catalyzed by the 3' --> 5' exonuclease-free (exo(-)) Klenow fragment of Escherichia coli DNA polymerase I. The primer extension was retarded one base prior to the N(2)-Et-dG lesion and opposite the lesion; however, when the enzyme was incubated for a longer time or with increased amounts of this enzyme, full extension occurred. Quantitative analysis of the fully extended products showed the preferential incorporation of dGMP and dCMP opposite the N(2)-Et-dG lesion, accompanied by a small amounts of dAMP and dTMP incorporation and one- and two-base deletions. Steady-state kinetic studies were also performed to determine the frequency of nucleotide insertion opposite the N(2)-Et-dG lesion and chain extension from the 3' terminus from the dN.N(2)-Et-dG (N is C, A, G, or T) pairs. These results indicate that the N(2)-Et-dG DNA adduct may generate G --> C transversions in living cells. Such a mutational spectrum has not been detected with other methylated dG adducts, including 8-methyl-2'-deoxyguanosine, O(6)-methyl-2'-deoxyguanosine, and N(2)-methyl-2'-deoxyguanosine. In addition, N(2)-ethyl-2'-deoxyguanosine triphosphate (N(2)-Et-dGTP) was efficiently incorporated opposite a template dC during DNA synthesis catalyzed by the exo(-) Klenow fragment. The utilization of N(2)-Et-dGTP was also determined by steady-state kinetic studies. N(2)-Et-dG DNA adducts are also formed by the incorporation of N(2)-Et-dGTP into DNA and may cause mutations, leading to the development of alcohol- and acetaldehyde-induced human cancers.     

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.     

Translesion synthesis of acetylaminofluorene-dG adducts by DNA polymerase zeta is stimulated by yeast Rev1 protein

Translesion synthesis is an important mechanism in response to unrepaired DNA lesions during replication. The DNA polymerase ζ (Polζ) mutagenesis pathway is a major error-prone translesion synthesis mechanism requiring Polζ and Rev1. In addition to its dCMP transferase, a non-catalytic function of Rev1 is suspected in cellular response to certain types of DNA lesions. However, it is not well understood about the non-catalytic function of Rev1 in translesion synthesis. We have analyzed the role of Rev1 in translesion synthesis of an acetylaminofluorene (AAF)-dG DNA adduct. Purified yeast Rev1 was essentially unresponsive to a template AAF-dG DNA adduct, in contrast to its efficient C insertion opposite a template 1,N⁶-ethenoadenine adduct. Purified yeast Polζ was very inefficient in the bypass of the AAF-dG adduct. Combining Rev1 and Polζ, however, led to a synergistic effect on translesion synthesis. Rev1 protein enhanced Polζ-catalyzed nucleotide insertion opposite the AAF-dG adduct and strongly stimulated Polζ-catalyzed extension from opposite the lesion. Rev1 also stimulated the deficient synthesis by Polζ at the very end of undamaged DNA templates. Deleting the C-terminal 205 aa of Rev1 did not affect its dCMP transferase activity, but abolished its stimulatory activity on Polζ-catalyzed extension from opposite the AAF-dG adduct. These results suggest that translesion synthesis of AAF-dG adducts by Polζ is stimulated by Rev1 protein in yeast. Consistent with the in vitro results, both Polζ and Rev1 were found to be equally important for error-prone translesion synthesis across from AAF-dG DNA adducts in yeast cells.     

Replication past a trans-4-hydroxynonenal minor-groove adduct by the sequential action of human DNA polymerases iota and kappa

The X-ray crystal structure of human DNA polymerase iota (Poliota) has shown that it differs from all known Pols in its dependence upon Hoogsteen base pairing for synthesizing DNA. Hoogsteen base pairing provides an elegant mechanism for synthesizing DNA opposite minor-groove adducts that present a severe block to synthesis by replicative DNA polymerases. Germane to this problem, a variety of DNA adducts form at the N2 minor-groove position of guanine. Previously, we have shown that proficient and error-free replication through the gamma-HOPdG (gamma-hydroxy-1,N2-propano-2'-deoxyguanosine) adduct, which is formed from the reaction of acrolein with the N2 of guanine, is mediated by the sequential action of human Poliota and Polkappa, in which Poliota incorporates the nucleotide opposite the lesion site and Polkappa carries out the subsequent extension reaction. To test the general applicability of these observations to other adducts formed at the N2 position of guanine, here we examine the proficiency of human Poliota and Polkappa to synthesize past stereoisomers of trans-4-hydroxy-2-nonenal-deoxyguanosine (HNE-dG). Even though HNE- and acrolein-modified dGs share common structural features, due to their increased size and other structural differences, HNE adducts are potentially more blocking for replication than gamma-HOPdG. We show here that the sequential action of Poliota and Polkappa promotes efficient and error-free synthesis through the HNE-dG adducts, in which Poliota incorporates the nucleotide opposite the lesion site and Polkappa performs the extension reaction.     

In vitro replication by prokaryotic and eukaryotic polymerases on DNA templates containing site-specific and stereospecific benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide adducts.

DNA adducts of the environmental carcinogen benzo[a]pyrene-7,8-dihydrodiol-9,10-epoxide (BPDE) interact stereospecifically with prokaryotic and eukaryotic polymerases in vitro. Toward understanding the capacity to replicate past different diastereomers of BPDE at specific sites in DNA, six deoxyoligonucleotides, each 33 bases long, were constructed with stereochemically defined BPDE adducts on adenine N6 at position two of the human N-ras codon 61. Four polymerases that were studied under single encounters with the template-primer complex terminated synthesis one base 3' to the lesion with all the adducted templates. When multiple encounters between polymerase and substrate were permitted, each of the polymerases analyzed revealed a unique pattern for a given adducted template. The general replication pattern was encompassed under two categories, reflecting the significance of the R and S configurations of C10 of the pyrenyl ring attached to the single-stranded DNA template. Furthermore, within each of these categories, every polymerase demonstrated distinct quantitative differences in product accumulation at a given site, for the various adducted templates. Among the polymerases utilized in this study, exonuclease-deficient Klenow fragment of polymerase I (exo- KF) exhibited the most efficient translesion synthesis resulting in approximately 16% full-length products with the modified templates bearing adducts with C10-S configuration. In contrast, chain elongation with bacteriophage T4 DNA polymerase bearing an active 3'-->5' exonucleolytic activity was most strongly inhibited by all six BPDE-adducted templates. Misincorporation of A opposite the adduct occurred in all the templates when polymerized with Sequenase, whereas exo- KF preferentially incorporated C opposite the C10-R BPDE adducts and A opposite the C10-S BPDE adducts.     

Miscoding events during DNA synthesis past the nitration-damaged base 8-nitroguanine

8-Nitro-2'-deoxyguanosine (8-NO(2)-dG) DNA adducts are induced by the reactive nitrogen species and may be associated with the development of cancer in inflammatory tissues. To explore the miscoding potential of 8-NO(2)-dG adduct, an oligodeoxynucleotide containing a single 8-NO(2)-dG adduct was prepared by photochemical synthesis and used as a template in primer extension reactions catalyzed by mammalian DNA polymerases (pol). Primer extension reactions catalyzed by pol alpha or beta were strongly retarded at the 8-NO(2)-dG lesion; a fraction of primers was extended past the lesion by incorporating preferentially dCMP, the correct base, opposite the lesion, accompanied by lesser amounts of dAMP and dGMP incorporation. In contrast, primer extension reactions catalyzed by pol eta or a truncated form of pol kappa (pol kappaDeltaC) readily extended past the 8-NO(2)-dG lesion. Pol eta and kappaDeltaC showed more broad miscoding spectra; direct incorporations of dCMP and dAMP were observed, along with lesser amounts of dGMP and dTMP incorporations and deletions. The miscoding frequencies induced by pol eta and kappaDeltaC were at least 8 times higher than that of pol alpha or beta. Miscoding frequency and specificity of 8-NO(2)-dG varied depending on the DNA polymerases used. These observations were supported by steady-state kinetic studies. 8-NO(2)-dG adduct may play an important role in initiating inflammation driven carcinogenesis.     

Insertion of dNTPs opposite the 1,N2-propanodeoxyguanosine adduct by Sulfolobus solfataricus P2 DNA polymerase IV

1, N (2)-Propanodeoxyguanosine (PdG) is a stable structural analogue for the 3-(2'-deoxy-beta- d- erythro-pentofuranosyl)pyrimido[1,2-alpha]purin-10(3 H)-one (M 1dG) adduct derived from exposure of DNA to base propenals and to malondialdehyde. The structures of ternary polymerase-DNA-dNTP complexes for three template-primer DNA sequences were determined, with the Y-family Sulfolobus solfataricus DNA polymerase IV (Dpo4), at resolutions between 2.4 and 2.7 A. Three template 18-mer-primer 13-mer sequences, 5'-d(TCACXAAATCCTTCCCCC)-3'.5'-d(GGGGGAAGGATTT)-3' (template I), 5'-d(TCACXGAATCCTTCCCCC)-3'.5'-d(GGGGGAAGGATTC)-3' (template II), and 5'-d(TCATXGAATCCTTCCCCC)-3'.5'-d(GGGGGAAGGATTC)-3' (template III), where X is PdG, were analyzed. With templates I and II, diffracting ternary complexes including dGTP were obtained. The dGTP did not pair with PdG, but instead with the 5'-neighboring template dC, utilizing Watson-Crick geometry. Replication bypass experiments with the template-primer 5'-TCACXAAATCCTTACGAGCATCGCCCCC-3'.5'-GGGGGCGATGCTCGTAAGGATTT-3', where X is PdG, which includes PdG in the 5'-CXA-3' template sequence as in template I, showed that the Dpo4 polymerase inserted dGTP and dATP when challenged by the PdG adduct. For template III, in which the template sequence was 5'-TXG-3', a diffracting ternary complex including dATP was obtained. The dATP did not pair with PdG, but instead with the 5'-neighboring T, utilizing Watson-Crick geometry. Thus, all three ternary complexes were of the "type II" structure described for ternary complexes with native DNA [Ling, H., Boudsocq, F., Woodgate, R., and Yang, W. (2001) Cell 107, 91-102]. The PdG adduct remained in the anti conformation about the glycosyl bond in each of these threee ternary complexes. These results provide insight into how -1 frameshift mutations might be generated for the PdG adduct, a structural model for the exocylic M 1dG adduct formed by malondialdehyde.     

Repair kinetics of trans-4-hydroxynonenal-induced cyclic 1,N2-propanodeoxyguanine DNA adducts by human cell nuclear extracts

trans-4-Hydroxynonenal (HNE) is a major peroxidation product of omega-6 polyunsaturated fatty acids. The reaction of HNE with DNA produces four diastereomeric 1,N(2)-gamma-hydroxypropano adducts of deoxyguanosine (HNE-dG); background levels of these adducts have been detected in tissues of animals and humans. There is evidence to suggest that these adducts are mutagenic and involved in liver carcinogenesis in patients with Wilson's disease and in other human cancers. Here, we present biochemical evidence that in human cell nuclear extracts the HNE-dG adducts are repaired by the nucleotide excision repair (NER) pathway. To investigate the recognition and repair of HNE-dG adducts in human cell extracts, we prepared plasmid DNA substrates modified by HNE. [(32)P]-Postlabeling/HPLC determined that the HNE-dG adduct levels were approximately 1200/10(6) dG of plasmid DNA substrate. We used this substrate in an in vitro repair-synthesis assay to study the complete repair of HNE-induced DNA adducts in cell-free extracts. We observed that nuclear extracts from HeLa cells incorporated a significant amount of alpha[(32)P]dCTP in DNA that contained HNE-dG adducts by comparison with UV-irradiated DNA as the positive control. Such repair synthesis for UV damage or HNE-dG adducts did not occur in XPA cell nuclear extracts that lack the capacity for NER. However, XPA cells complemented with XPA protein restored repair synthesis for both of these adducts. To verify that HNE-dG adducts in DNA were indeed repaired, we measured HNE-dG adducts in the post-repaired DNA substrates by the [(32)P]-postlabeling/HPLC method, showing that 50-60% of HNE-dG adducts were removed from the HeLa cell nuclear extracts after 3 h at 30 degrees C. The repair kinetics indicated that the excision rate is faster than the rate of gap-filling/DNA synthesis. Furthermore, the HNE-dG adduct isomers 2 and 4 appeared to be repaired more efficiently at early time points than isomers 1 and 3.     

Mutation spectra induced by alpha-acetoxytamoxifen-DNA adducts in human DNA repair proficient and deficient (xeroderma pigmentosum complementation group A) cells

Tamoxifen, a breast cancer drug, has recently been approved for the chemoprevention of this disease. However, tamoxifen causes hepatic carcinomas in rats through a genotoxic mechanism and increases the risk of endometrial tumors in women. DNA adducts have been detected at low levels in human endometrium, and there is much interest in determining whether DNA damage plays a role in tamoxifen-induced endometrial carcinogenesis. This study investigates the mutagenicity of tamoxifen DNA adducts formed by alpha-acetoxytamoxifen, a reactive ester producing the major DNA adduct formed in livers of tamoxifen-treated rats. pSP189 plasmid DNA containing the supF gene was treated with alpha-acetoxytamoxifen and adduct levels (0.5-8.0 adducts per plasmid) determined by (32)P-postlabeling. Adducted plasmids were transfected into nucleotide excision repair proficient (GM00637) or deficient (GM04429, XPA) human fibroblasts. After replication, plasmids were recovered and screened in indicator bacteria. Relative mutation frequencies increased with the adduct level, with 1.3-3.6-fold higher numbers of mutations in the XP cells compared to the GM00637 cells, indicating that NER plays a significant role in the removal of these particular tamoxifen DNA adducts. The majority of sequence alterations (91-96%) occurred at GC base pairs, as did mutation hotspots, although the type and position of mutations was cell-specific. In both cell lines, as the adduct level increased, the proportion of GC --> AT transitions decreased and GC --> TA transversions, mutations known to arise from the major tamoxifen adducts, increased. Given the high mutagenicity of dG-N(2)-tamoxifen adducts, if not excised, they may potentially contribute to the initiation of endometrial cancer in women.     

The p-benzoquinone DNA adducts derived from benzene are highly mutagenic

Benzene is a human leukemia carcinogen, resulting from its cellular metabolism. A major benzene metabolite is p-benzoquinone (pBQ), which can damage DNA by forming the exocyclic base adducts pBQ-dC, pBQ-dA, and pBQ-dG in vitro. To gain insights into the role of pBQ in benzene genotoxicity, we examined in vitro translesion synthesis and in vivo mutagenesis of these pBQ adducts. Purified REV1 and Polkappa were essentially incapable of translesion synthesis in response to the pBQ adducts. Opposite pBQ-dA and pBQ-dC, purified human Poliota was capable of error-prone nucleotide insertion, but was unable to perform extension synthesis. Error-prone translesion synthesis was observed with Poleta. However, DNA synthesis largely stopped opposite the lesion. Consistent with in vitro results, replication of site-specifically damaged plasmids was strongly inhibited by pBQ adducts in yeast cells, which depended on both Polzeta and Poleta. In wild-type cells, the majority of translesion products were deletions at the site of damage, accounting for 91%, 90%, and 76% for pBQ-dA, pBQ-dG, and pBQ-dC, respectively. These results show that the pBQ-dC, pBQ-dA, and pBQ-dG adducts are strong blocking lesions, and are highly mutagenic by predominantly inducing deletion mutations. These results are consistent with the lesion structures predicted by molecular dynamics simulation. Our results led to the following model. Translesion synthesis normally occurs by directly copying the lesion site through base insertion and extension synthesis. When the lesion becomes incompatible in accommodating a base opposite the lesion in DNA, translesion synthesis occurs by a less efficient lesion loop-out mechanism, resulting in avoiding copying the damaged base and leading to deletion.     

Mutagenic properties of 3-(deoxyguanosin-N2-yl)-2-acetylaminofluorene, a persistent acetylaminofluorene-derived DNA adduct in mammalian cells

The carcinogen 2-acetylaminofluorene is metabolically activated in cells and reacts with DNA to form N-(deoxyguanosin-8-yl)-2-acetylaminofluorene (dG-C8-AAF), N-(deoxyguanosin-8-yl)-2-aminofluorene (dG-C8-AF), and 3-(deoxyguanosin-N(2)()-yl)-2-acetylaminofluorene (dG-N(2)-AAF) DNA adducts. The dG-N(2)-AAF adduct is the least abundant of the three isomers, but it persists in the tissues of animals treated with this carcinogen. The miscoding and mutagenic properties of dG-C8-AAF and dG-C8-AF have been established; these adducts are readily excised by DNA repair enzymes engaged in nucleotide excision repair. In the present study, oligodeoxynucleotides modified site-specifically with dG-N(2)-AAF were used as DNA templates in primer extension reactions catalyzed by mammalian DNA polymerases. Reactions catalyzed by pol alpha were strongly blocked at a position one base before dG-N(2)-AAF and also opposite this lesion. In contrast, during translesion synthesis catalyzed by pol eta or pol kappa nucleotides were incorporated opposite the lesion. Both pol eta and pol kappa incorporated dCMP, the correct base, opposite dG-N(2)-AAF. In reactions catalyzed by pol eta, small amounts of dAMP misincorporation and one-base deletions were detected at the lesion site. With pol kappa, significant dTMP misincorporation was observed opposite the lesion. Steady-state kinetic analysis confirmed the results obtained from primer extension studies. Single-stranded shuttle vectors containing (5)(')TCCTCCTCXCCTCTC (X = dG-N(2)-AAF, dG-C8-AAF, or dG) were used to establish the frequency and specificity of dG-N(2)-AAF-induced mutations in simian kidney (COS-7) cells. Both lesions promote G --> T transversions overall, with dG-N(2)-AAF being less mutagenic than dG-C8-AAF (3.4% vs 12.5%). We conclude from this study that dG-N(2)-AAF, by virtue of its persistence in tissues, contributes significantly to the mutational spectra observed in AAF-induced mutagenesis and that pol eta, but not pol kappa, may play a role in this process.     

Miscoding properties of 1,N6-ethanoadenine, a DNA adduct derived from reaction with the antitumor agent 1,3-bis(2-chloroethyl)-1-nitrosourea

1,N(6)-Ethanoadenine (EA) is an exocyclic adduct formed from DNA reaction with the antitumor agent, 1,3-bis(2-chloroethyl)-1-nitrosourea (BCNU). To understand the role of this adduct in the mechanism of mutagenicity or carcinogenicity by BCNU, an oligonucleotide with a site-specific EA was synthesized using phosphoramidite chemistry. We now report the in vitro miscoding properties of EA in translesion DNA synthesis catalyzed by mammalian DNA polymerases (pols) alpha, beta, eta and iota. These data were also compared with those obtained for the structurally related exocyclic adduct, 1,N(6)-ethenoadenine (epsilonA). Using a primer extension assay, both pols alpha and beta were primarily blocked by EA or epsilonA with very minor extension. Pol eta, a member of the Y family of polymerases, was capable of catalyzing a significant amount of bypass across both adducts. Pol eta incorporated all four nucleotides opposite EA and epsilonA, but with differential preferences and mainly in an error-prone manner. Human pol iota, a paralog of human pol eta, was blocked by both adducts with a very small amount of synthesis past epsilonA. It incorporated C and, to a much lesser extent, T, opposite either adduct. In addition, the presence of an A adduct, e.g. epsilonA, could affect the specificity of pol iota toward the template T immediately 3' to the adduct. In conclusion, the four polymerases assayed on templates containing an EA or epsilonA showed differential bypass capacity and nucleotide incorporation specificity, with the two adducts not completely identical in influencing these properties. Although there was a measurable extent of error-free nucleotide incorporation, all these polymerases primarily misincorporated opposite EA, indicating that the adduct, similar to epsilonA, is a miscoding lesion.