The proofreading 3'-->5' exonuclease activity of DNA polymerases: a kinetic barrier to translesion DNA synthesis

The 3'-->5' exonuclease activity intrinsic to several DNA polymerases plays a primary role in genetic stability; it acts as a first line of defense in correcting DNA polymerase errors. A mismatched basepair at the primer terminus is the preferred substrate for the exonuclease activity over a correct basepair. The efficiency of the exonuclease as a proofreading activity for mispairs containing a DNA lesion varies, however, being dependent upon both the DNA polymerase/exonuclease and the type of DNA lesion. The exonuclease activities intrinsic to the T4 polymerase (family B) and DNA polymerase gamma (family A) proofread DNA mispairs opposite endogenous DNA lesions, including alkylation, oxidation, and abasic adducts. However, the exonuclease of the Klenow polymerase cannot discriminate between correct and incorrect bases opposite alkylation and oxidative lesions. DNA damage alters the dynamics of the intramolecular partitioning of DNA substrates between the 3'-->5' exonuclease and polymerase activities. Enzymatic idling at lesions occurs when an exonuclease activity efficiently removes the same base that is preferentially incorporated by the DNA polymerase activity. Thus, the exonuclease activity can also act as a kinetic barrier to translesion synthesis (TLS) by preventing the stable incorporation of bases opposite DNA lesions. Understanding the downstream consequences of exonuclease activity at DNA lesions is necessary for elucidating the mechanisms of translesion synthesis and damage-induced cytotoxicity.     

DNA polymerase mutagenic bypass and proofreading of endogenous DNA lesions

DNA polymerases differentiate between correct and incorrect substrates during synthesis on undamaged DNA templates through the biochemical steps of base incorporation, primer-template extension and proofreading excision. Recent research examining DNA polymerase processing of abasic, alkylation and oxidative lesions is reviewed in light of these discrimination mechanisms. Inhibition of DNA synthesis results from correct polymerase discrimination against utilization of geometrically incorrect template bases or 3' terminal basepairs. The efficiency of translesion synthesis is thus related to the physical structure of the lesion containing DNA. However, variations in enzyme structure and kinetics result in translesion synthesis efficiencies that are also dependent upon the DNA polymerase. With a low probability, polymerase misinsertion events create a 3' lesion terminus which is geometrically favored over the correct lesion basepair, resulting in mutagenic translesion synthesis. For example, both polymerase alpha and polymerase beta appear to require the formation of a stable 3' primer-template structure for efficient abasic site translesion synthesis. However, the enzymes differ as to the precise molecular make-up of the stable DNA structure, resulting in different mutational specificities. Similar mechanisms may be applicable to oxidative damage, where mutational specificities dependent upon the DNA polymerase also have been observed. In vitro reaction conditions also influence DNA polymerase processing of lesions. Using an in vitro herpes simplex virus thymidine kinase (HSV-tk) gene forward mutation assay, we demonstrate that high dNTP substrate concentrations affect the mutagenic specificity of translesion synthesis using alkylated templates. The exonuclease-deficient Klenow polymerase error frequency for G-->A transition mutations using templates modified by N-ethyl-N-nitrosourea (ENU) was four-fold higher at 1000 microM [dNTP], relative to 50 microM [dNTP], consistent with an increased efficiency of extension of the etO6G.T mispair. Moreover, the frequency of other ENU-induced polymerase errors was suppressed when polymerase reactions contained 50 microM dNTP, relative to 1000 microM dNTP. The efficiency of proofreading as a polymerase error discrimination mechanism reflects a balance between the competing processes of 3'-->5' exonuclease removal of mispairs and polymerization of the next correct nucleotide. Polymerases that are devoid of a proofreading exonuclease generally display enhanced abasic site translesion synthesis relative to proofreading-proficient enzymes. In addition, the proofreading exonucleases of Escherichia coli Pol I and T4 DNA polymerases have been found to remove mispairs caused by abasic sites and oxidative lesions, respectively, resulting in lowered polymerase error rates. However, the magnitude of the exonuclease effect is small (less than 10-fold), and highly dependent upon the DNA polymerase-exonuclease. We have studied proofreading exonuclease removal of alkylation damage in the HSV-tk forward assay. We observed no significant reduction in the magnitude of the mutant frequency vs. dose-response curves when N-methyl-N-nitrosourea or ENU-treated templates were used in exonuclease-proficient Klenow polymerase reactions, as compared to the exonuclease-deficient polymerase reactions. Thus, available data suggest that proofreading excision of endogenous lesion mispairs does occur, but the efficiency is dependent upon the lesion and the DNA polymerase-exonuclease studied.     

Replication of DNA templates containing 5-formyluracil, a major oxidative lesion of thymine in DNA.

5-Formyluracil (5-foU) is a major lesion of thymine produced in DNA by ionizing radiation and various chemical oxidants. To assess its biochemical effects on DNA replication, 22mer oligonucleotide templates containing an internal 5-foU at defined sites were synthesized by the phosphoramidite method and examined for ability to serve as a template for various DNA polymerases in vitro . Klenow fragments with and without 3'-->5'exonuclease of DNA polymerase I, Thermus thermophilus DNA polymerase (exonuclease-deficient) and Pyrococcus furiosus DNA polymerase (exonuclease-proficient) read through the site of 5-foU in the template. Primer extension assays revealed that the 5-foU directed not only incorporation of dAMP but also dCMP opposite the lesion during DNA synthesis. Misincorporation opposite 5-foU was unaffected by 3'-->5' exonuclease activity. DNA polymerases had different dissociation rates from a dCMP/T mispair and from a dCMP/5-foU mispair. The incorporation of an 'incorrect' nucleotide was dependent on the sequence context and DNA polymerase used. These results suggest that 5-foU produced in DNA has mutagenic potential leading to T-->G transversions during DNA synthesis.     

The proofreading 3′→5′ exonuclease activity of DNA polymerases: a kinetic barrier to translesion DNA synthesis

The 3′→5′ exonuclease activity intrinsic to several DNA polymerases plays a primary role in genetic stability; it acts as a first line of defense in correcting DNA polymerase errors. A mismatched basepair at the primer terminus is the preferred substrate for the exonuclease activity over a correct basepair. The efficiency of the exonuclease as a proofreading activity for mispairs containing a DNA lesion varies, however, being dependent upon both the DNA polymerase/exonuclease and the type of DNA lesion. The exonuclease activities intrinsic to the T4 polymerase (family B) and DNA polymerase γ (family A) proofread DNA mispairs opposite endogenous DNA lesions, including alkylation, oxidation, and abasic adducts. However, the exonuclease of the Klenow polymerase cannot discriminate between correct and incorrect bases opposite alkylation and oxidative lesions. DNA damage alters the dynamics of the intramolecular partitioning of DNA substrates between the 3′→5′ exonuclease and polymerase activities. Enzymatic idling at lesions occurs when an exonuclease activity efficiently removes the same base that is preferentially incorporated by the DNA polymerase activity. Thus, the exonuclease activity can also act as a kinetic barrier to translesion synthesis (TLS) by preventing the stable incorporation of bases opposite DNA lesions. Understanding the downstream consequences of exonuclease activity at DNA lesions is necessary for elucidating the mechanisms of translesion synthesis and damage-induced cytotoxicity.     

Specificity of proofreading by the 3'----5' exonuclease of the DNA polymerase-primase of Drosophila melanogaster

The DNA polymerase-primase from Drosophila melanogaster contains a cryptic 3'----5' exonuclease that can be detected after separation of the 182-kDa polymerase subunit from the four-subunit enzyme. To determine the specificity of excision of mispaired nucleotides by the exonuclease, we have utilized primed phi X174am3 single-stranded DNA containing a noncomplementary nucleotide at the 3'-primer terminus, opposite deoxyadenosine at position 587 in the amber3 codon of the template strand. In the absence of polymerization, the preference for excision of the mispaired nucleotide from the primer is C greater than A much greater than G. Excision under these conditions is inhibited by the addition of deoxyguanosine monophosphate. Under conditions of concomitant DNA synthesis, the preference for excision at this site becomes A = G much greater than C, and excision is insensitive to deoxyguanosine monophosphate. The high fidelity of DNA synthesis exhibited by the isolated 182-kDa polymerase subunit is not reduced by concentrations of deoxyguanosine monophosphate or adenosine monophosphate that inhibit proofreading by prokaryotic DNA polymerases. Thus, the 3'----5' exonuclease of the Drosophila DNA polymerase-primase participates in exonucleolytic proofreading by excising noncomplementary nucleotides prior to extension of the primer by polymerase action. The deoxynucleoside triphosphate analogs N2-(p-butylphenyl)deoxyguanosine triphosphate and N2-(p-butylphenyl)deoxyadenosine triphosphate are potent inhibitors of DNA polymerase alpha. Like calf thymus DNA polymerase delta, recently determined to have proofreading capability, DNA synthesis by the isolated Drosophila 182-kDa polymerase subunit was not inhibited by the two analogs. In contrast, DNA synthesis by the intact Drosophila polymerase-primase complex was inhibited greater than 95% by these analogs.     

Properties of the 3' to 5' exonuclease associated with porcine liver DNA polymerase gamma. Substrate specificity, product analysis, inhibition, and kinetics of terminal excision.

Porcine liver DNA polymerase gamma was shown previously to copurify with an associated 3' to 5' exonuclease activity (Kunkel, T. A., and Mosbaugh, D. W. (1989) Biochemistry 28, 988-995). The 3' to 5' exonuclease has now been characterized, and like the DNA polymerase activity, it has an absolute requirement for a divalent metal cation (Mg2+ or Mn2+), a relatively high NaCl and KCl optimum (150-200 mM), and an alkaline pH optimum between 7 and 10. The exonuclease has a 7.5-fold preference for single-stranded over double-stranded DNA, but it cannot excise 3'-terminal dideoxy-NMP residues from either substrate. Excision of 3'-terminally mismatched nucleotides was preferred approximately 5-fold over matched 3' termini, and the hydrolysis product from both was a deoxyribonucleoside 5'-monophosphate. The kinetics of 3'-terminal excision were measured at a single site on M13mp2 DNA for each of the 16 possible matched and mismatched primer.template combinations. As defined by the substrate specificity constant (Vmax/Km), each of the 12 mismatched substrates was preferred over the four matched substrates (A.T, T.A, C.G, G.C). Furthermore, the exonuclease could efficiently excise internally mismatched nucleotides up to 4 residues from the 3' end. DNA polymerase gamma was not found to possess detectable DNA primase, endonuclease, 5' to 3' exonuclease, RNase, or RNase H activities. The DNA polymerase and exonuclease activities exhibited dissimilar rates of heat inactivation and sensitivity to N-ethylmaleimide. After nondenaturing activity gel electrophoresis, the DNA polymerase and 3' to 5' exonuclease activities were partially resolved and detected in situ as separate species. A similar analysis on a denaturing activity gel identified catalytic polypeptides with molecular weights of 127,000, 60,000, and 32,000 which possessed only DNA polymerase gamma activity. Collectively, these results suggest that the polymerase and exonuclease activities reside in separate polypeptides, which could be derived from separate gene products or from proteolysis of a single gene product.     

Accessory proteins assist exonuclease-deficient bacteriophage T4 DNA polymerase in replicating past an abasic site

Replicative DNA polymerases, such as T4 polymerase, possess both elongation and 3'-5' exonuclease proofreading catalytic activities. They arrest at the base preceding DNA damage on the coding DNA strand and specialized DNA polymerases have evolved to replicate across the lesion by a process known as TLS (translesion DNA synthesis). TLS is considered to take place in two steps that often require different enzymes, insertion of a nucleotide opposite the damaged template base followed by extension from the inserted nucleotide. We and others have observed that inactivation of the 3'-5' exonuclease function of T4 polymerase enables TLS across a single site-specific abasic [AP (apurinic/apyrimidinic)] lesion. In the present study we report a role for auxiliary replicative factors in this reaction. When replication is performed with a large excess of DNA template over DNA polymerase in the absence of auxiliary factors, the exo- polymerase (T4 DNA polymerase deficient in the 3'-5' exonuclease activity) inserts one nucleotide opposite the AP site but does not extend past the lesion. Addition of the clamp processivity factor and the clamp loader complex restores primer extension across an AP lesion on a circular AP-containing DNA substrate by the exo- polymerase, but has no effect on the wild-type enzyme. Hence T4 DNA polymerase exhibits a variety of responses to DNA damage. It can behave as a replicative polymerase or (in the absence of proofreading activity) as a specialized DNA polymerase and carry out TLS. As a specialized polymerase it can function either as an inserter or (with the help of accessory proteins) as an extender. The capacity to separate these distinct functions in a single DNA polymerase provides insight into the biochemical requirements for translesion DNA synthesis.     

Role of DNA polymerase zeta in the bypass of a (6-4) TT photoproduct

UV light-induced DNA lesions block the normal replication machinery. Eukaryotic cells possess DNA polymerase eta (Poleta), which has the ability to replicate past a cis-syn thymine-thymine (TT) dimer efficiently and accurately, and mutations in human Poleta result in the cancer-prone syndrome, the variant form of xeroderma pigmentosum. Here, we test Poleta for its ability to bypass a (6-4) TT lesion which distorts the DNA helix to a much greater extent than a cis-syn TT dimer. Opposite the 3' T of a (6-4) TT photoproduct, both yeast and human Poleta preferentially insert a G residue, but they are unable to extend from the inserted nucleotide. DNA Polzeta, essential for UV induced mutagenesis, efficiently extends from the G residue inserted opposite the 3' T of the (6-4) TT lesion by Poleta, and Polzeta inserts the correct nucleotide A opposite the 5' T of the lesion. Thus, the efficient bypass of the (6-4) TT photoproduct is achieved by the combined action of Poleta and Polzeta, wherein Poleta inserts a nucleotide opposite the 3' T of the lesion and Polzeta extends from it. These biochemical observations are in concert with genetic studies in yeast indicating that mutations occur predominantly at the 3' T of the (6-4) TT photoproduct and that these mutations frequently exhibit a 3' T-->C change that would result from the insertion of a G opposite the 3' T of the (6-4) TT lesion.     

A new proofreading mechanism for lesion bypass by DNA polymerase-λ

Replicative DNA polymerases (DNA pols) increase their fidelity by removing misincorporated nucleotides with their 3' → 5' exonuclease activity. Exonuclease activity reduces translesion synthesis (TLS) efficiency and TLS DNA pols lack 3' → 5' exonuclease activity. Here we show that physiological concentrations of pyrophosphate (PP(i)) activate the pyrophosphorolytic activity by DNA pol-λ, allowing the preferential excision of the incorrectly incorporated A opposite a 7,8-dihydro-8-oxoguanine lesion, or T opposite a 6-methyl-guanine, with respect to the correct C. This is the first example of an alternative proofreading mechanism used during TLS.     

Oxygen free radical damage to DNA. Translesion synthesis by human DNA polymerase eta and resistance to exonuclease action at cyclopurine deoxynucleoside residues.

Cyclopurine deoxynucleosides are common DNA lesions generated by exposure to reactive oxygen species under hypoxic conditions. The S and R diastereoisomers of cyclodeoxyadenosine on DNA were investigated separately for their ability to block 3' to 5' exonucleases. The mammalian DNA-editing enzyme DNase III (TREX1) was blocked by both diastereoisomers, whereas only the S diastereoisomer was highly efficient in preventing digestion by the exonuclease function of T4 DNA polymerase. Digestion in both cases was frequently blocked one residue before the modified base. Oligodeoxyribonucleotides containing a cyclodeoxyadenosine residue were further employed as templates for synthesis by human DNA polymerase eta (pol eta). pol eta could catalyze translesion synthesis on the R diastereoisomer of cyclodeoxyadenosine. On the S diastereoisomer, pol eta could catalyze the incorporation of one nucleotide opposite the lesion but could not continue elongation. Although pol eta preferentially incorporated dAMP opposite the R diastereoisomer, elongation continued only when dTMP was incorporated, suggesting bypass of this lesion by pol eta with reasonable fidelity. With the S diastereoisomer, pol eta mainly incorporated dAMP or dTMP opposite the lesion but could not elongate even after incorporating a correct nucleotide. These data suggest that the S diastereoisomer may be a more cytotoxic DNA lesion than the R diastereoisomer.     

Replication past O(6)-methylguanine by yeast and human DNA polymerase eta

O(6)-Methylguanine (m6G) is formed by the action of alkylating agents such as N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) on DNA. m6G is a highly mutagenic and carcinogenic lesion, and it presents a block to synthesis by DNA polymerases. Here, we provide genetic and biochemical evidence for the involvement of yeast and human DNA polymerase eta (Poleta) in the replicative bypass of m6G lesions in DNA. The formation of MNNG-induced mutations is almost abolished in the rad30Delta pol32Delta double mutant of yeast, which lacks the RAD30 gene that encodes Poleta and the Pol32 subunit of DNA polymerase delta (Poldelta). Although Poldelta can function in the mutagenic bypass of m6G lesions, our biochemical studies indicate that Poleta is much more efficient in replicating through m6G than Poldelta. Both Poleta and Poldelta insert a C or a T residue opposite from m6G; Poleta, however, is more accurate, as it inserts a C about twice as frequently as Poldelta. Alkylating agents are used in the treatment of malignant tumors, including lymphomas, brain tumors, melanomas, and gastrointestinal carcinomas, and the clinical effectiveness of these agents derives at least in part from their ability to form m6G in DNA. Inactivation of Poleta could afford a useful strategy for enhancing the effectiveness of these agents in cancer chemotherapy.     

Loss of DNA minor groove interactions by exonuclease-deficient Klenow polymerase inhibits O6-methylguanine and abasic site translesion synthesis

The importance of DNA polymerase-DNA minor groove interactions on translesion synthesis (TLS) was examined in vitro using variants of exonuclease-deficient Klenow polymerase and site-specifically modified DNA oligonucleotides. Polymerase variant R668A lacks primer strand interactions, while variant Q849A lacks template strand interactions. O(6)-Methylguanine (m6G) and abasic site TLS was examined in three stages: dNTP insertion opposite the lesion, extension from a terminal lesion-containing base pair, and the dissociation equilibrium of the polymerase from the lesion-containing template. Less than 5% TLS was observed at the insertion step for either variant on the lesion-containing templates. While extensive TLS was observed for WT polymerase on the m6G template, only incorporation opposite the lesion was observed for the R668A variant. Loss of the template strand interaction, Q849A, resulted in the inability to insert dNTPs opposite either the m6G or abasic lesion. For both variants, extension of purine-containing m6G primer-templates was increased relative to WT polymerase. We observed similar extension efficiencies for all variants, relative to WT, using abasic template-primers. Polymerase dissociation/reassociation was studied through the use of a competitor primer/template complex. Dissociation for WT polymerase increased 2-fold and 3-fold, respectively, for m6G and abasic lesion-containing templates, relative to the natural template. Variants lacking DNA minor groove interactions displayed increased dissociation from DNA templates, relative to WT polymerase, but do not display an increased level of lesion-induced polymerase dissociation. Our results indicate that the primer and template strand interactions of the Klenow polymerase with the DNA minor groove are critical for maintaining the DNA-polymerase complex during translesion synthesis.     

In vitro selection of sequence contexts which enhance bypass of abasic sites and tetrahydrofuran by T4 DNA polymerase holoenzyme

The influence of sequence context on the ability of DNA polymerase to bypass sites of base loss was addressed using an in vitro selection system. Oligonucleotides containing either an aldehydic abasic site or tetrahydrofuran surrounded by four randomized bases on both the 5' and 3' sides were used as templates for synthesis by phage T4 DNA polymerase holoenzyme proficient or deficient in the 3'-->5' proofreading exonuclease activity. Successful bypass products were purified, subcloned and the sequences of approximately 100 subclones were determined for each of the four polymerase/lesion combinations tested. Between 7 and 19 % of the bypass products contained deletions of one to three nucleotides in the randomized region. In bypass products not containing deletions, biases for and against certain nucleotides were readily noticeable across the entire randomized region. Template strands from successful bypass products of abasic sites had a high frequency of T in most of the randomized positions, while those from bypass products of tetrahydrofuran had a high frequency of G at the positions immediately to the 3' and 5' side of the lesion. Consensus sequences were shared by successful bypass products of the same lesion but not between bypass products of the two lesions. The consensus sequence for efficient bypass of tetrahydrofuran was over-represented in several frames relative to the lesion. T4 DNA polymerase inserted A opposite abasic sites 63 % of the time in the presence of proofreading and 79 % of the time in its absence, followed by G>T>C, while the insertion of A opposite tetrahydrofuran ranged between 93 % and 100 % in the presence and absence of proofreading, respectively. Finally, sequence context influenced the choice of nucleotide inserted opposite abasic sites and consensus sequences which favored the incorporation of nucleotides other than A were defined.     

Chlamydial DNA polymerase I can bypass lesions in vitro

We found that DNA polymerase I from Chlamydiophila pneumoniae AR39 (CpDNApolI) presents DNA-dependent DNA polymerase activity, but has no detectable 3' exonuclease activity. CpDNApolI-dependent DNA synthesis was performed using DNA templates carrying different lesions. DNAs containing 2'-deoxyuridine (dU), 2'-deoxyinosine (dI) or 2'-deoxy-8-oxo-guanosine (8-oxo-dG) served as templates as effectively as unmodified DNAs for CpDNApolI. Furthermore, the CpDNApolI could bypass natural apurinic/apyrimidinic sites (AP sites), deoxyribose (dR), and synthetic AP site tetrahydrofuran (THF). CpDNApolI could incorporate any dNMPs opposite both of dR and THF with the preference to dAMP-residue. CpDNApolI preferentially extended primer with 3'-dAMP opposite dR during DNA synthesis, however all four primers with various 3'-end nucleosides (dA, dT, dC, and dG) opposite THF could be extended by CpDNApolI. Efficiently bypassing of AP sites by CpDNApolI was hypothetically attributed to lack of 3' exonuclease activity.     

Blockage of polymerase-catalyzed DNA chain elongation by chemically modified cytosine residues in templates and the release of blockage for readthrough.

The Klenow fragment-mediated in vitro DNA elongation was inhibited by the presence of a class of modified cytosines in the template DNA, i.e., the N4-amino(and -methoxy)-5,6-dihydrocytosine-6-sulfonate residues. We have studied the mechanism of the blockage, using as templates bisulfite-hydrazine (and -methoxyamine)- modified single strand phage-M13mp2 DNA and synthetic oligonucleotides. Both N4-amino-5,6-dihydrocytosine-6-sulfonate and N4-methoxy-5,6-dihydrocytosine-6-sulfonate residues blocked the elongation at one nucleotide before these sites. In this blockage, the idling of polymerase at the lesion site due to its 3'-5' exonuclease action appears not to play a major role, because Sequenase that lacks the 3'-5' exonuclease activity still could not readthrough these sites. It seems possible that conformational distortion of the template near these sites is responsible for the blockage, because on conversion of this 5,6-dihydropyrimidine-6-sulfonate structure into a planar pyrimidine, a complete restoration of polymerase-readthrough resulted. In the presence of RecA and SSB proteins, the Klenow fragment was able to partially readthrough these sites. Since there was no decrease in the 3'-5' exonuclease activity during this readthrough, it seems that the binding of these proteins relaxes the distortion in the modified template to allow the polymerase to readthrough the lesion site. These sites on phage DNA can be lethal but also are capable of inducing C-to-T transitions. This observation suggests that these sites can be read by E. coli DNA polymerases in vivo with accompanying errors.     

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.     

Preferential incorporation of G opposite template T by the low-fidelity human DNA polymerase iota

DNA polymerase activity is essential for replication, recombination, repair, and mutagenesis. All DNA polymerases studied so far from any biological source synthesize DNA by the Watson-Crick base-pairing rule, incorporating A, G, C, and T opposite the templates T, C, G, and A, respectively. Non-Watson-Crick base pairs would lead to mutations. In this report, we describe the ninth human DNA polymerase, Pol(iota), encoded by the RAD30B gene. We show that human Pol(iota) violates the Watson-Crick base-pairing rule opposite template T. During base selection, human Pol(iota) preferred T-G base pairing, leading to G incorporation opposite template T. The resulting T-G base pair was less efficiently extended by human Pol(iota) compared to the Watson-Crick base pairs. Consequently, DNA synthesis frequently aborted opposite template T, a property we designated the T stop. This T stop restricted human Pol(iota) to a very short stretch of DNA synthesis. Furthermore, kinetic analyses show that human Pol(iota) copies template C with extraordinarily low fidelity, misincorporating T, A, and C with unprecedented frequencies of 1/9, 1/10, and 1/11, respectively. Human Pol(iota) incorporated one nucleotide opposite a template abasic site more efficiently than opposite a template T, suggesting a role for human Pol(iota) in DNA lesion bypass. The unique features of preferential G incorporation opposite template T and T stop suggest that DNA Pol(iota) may additionally play a specialized function in human biology.     

In vitro effects of a C4'-oxidized abasic site on DNA polymerases

Oxidative damage to DNA produces abasic sites resulting from the formal hydrolysis of the nucleotides' glycosidic bonds, along with a variety of oxidized abasic sites. The C4'-oxidized abasic site (C4-AP) is produced by several DNA-damaging agents. This lesion accounts for approximately 40% of the DNA damage produced by bleomycin. The effect of a C4'-oxidized abasic site incorporated at a defined site in a template was examined on Klenow fragments with and without 3' --> 5' exonuclease activity. Both enzymes preferentially incorporated dA > dG > dC, T opposite C4-AP. Neither enzyme is able to extend the primer past the lesion. Experiments with regular AP sites in an otherwise identical template indicate that Klenow does not differentiate between these two disparate abasic sites. Extension of the primer by alternative polymerases pol II, pol II exo(-), pol IV, and pol V was examined. Pol II exo(-) was most efficient. Qualitative translesion synthesis experiments showed that pol II exo(-) preferentially incorporates T opposite C4-AP, followed in order by dG, dA, and dC. Thymidine incorporation opposite C4'-AP is distinct from the pol II exonuclease interaction with a regular AP site in an otherwise identical template. These in vitro experiments suggest that bypass polymerases may play a crucial role in survival of cells in which C4-AP is produced, and unlike a typical AP site, the C4-AP lesion may not follow the "A-rule". The interaction between bypass polymerases and a C4-AP lesion could explain the high levels of G:C --> T:A transversions in cells treated with bleomycin.