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

DNA Polymerase ν Rapidly Bypasses O6-Methyl-dG but Not O6-[4-(3-Pyridyl)-4-oxobutyl-dG and O2-Alkyl-dTs

4-(Methylnitrosamino)-1-(3-pyridyl)-1-butanone (NNK) is a potent tobacco carcinogen that forms mutagenic DNA adducts including O6-methyl-2'-deoxyguanosine (O6-Me-dG), O6-[4-(3-pyridyl)-4-oxobut-1-yl]-dG (O6-POB-dG), O2-methylthymidine (O2-Me-dT), and O2-POB-dT. We evaluated the ability of human DNA polymerase ν to bypass this damage to evaluate the structural constraints on substrates for pol ν and to evaluate if there is kinetic evidence suggesting the in vivo activity of pol ν on tobacco-induced DNA damage. Presteady-state kinetic analysis has indicated that O6-Me-dG is a good substrate for pol ν, while O6-POB-dG and the O2-alkyl-dT adducts are poor substrates for pol ν. The reactivity with O6-Me-dG is high with a preference for dCTP > dGTP > dATP > dTTP. The catalytic activity of pol ν toward O6-Me-dG is high and can potentially be involved in its bypass in vivo. In contrast, pol ν is unlikely to bypass O6-POB-dG or the O2-alkyl-dTs in vivo.

Replication, repair, and translesion polymerase bypass of N⁶-oxopropenyl-2'-deoxyadenosine

The oxidative stress products malondialdehyde and base propenal react with DNA bases forming the adduction products 3-(2'-deoxy-β-D-erythro-pentofuranosyl)pyrimido[1,2-a]purin-10(3H)-one (M1dG) and N(6)-(oxypropenyl)-2'-deoxyadenosine (OPdA). M1dG is mutagenic in vivo and miscodes in vitro, but little work has been done on OPdA. To improve our understanding of the effect of OPdA on polymerase activity and mutagenicity, we evaluated the ability of the translesion DNA polymerases hPols η, κ, and ι to bypass OPdA in vitro. hPols η and κ inserted dNTPs opposite the lesion and extended the OPdA-modified primer to the terminus. hPol ι inserted dNTPs opposite OPdA but failed to fully extend the primer. Steady-state kinetic analysis indicated that these polymerases preferentially insert dTTP opposite OPdA, although less efficiently than opposite dA. Minimal incorrect base insertion was observed for all polymerases, and dCTP was the primary mis-insertion event. Examining replicative and repair polymerases revealed little effect of OPdA on the Sulfolobus solfataricus polymerase Dpo1 or the Klenow fragment of Escherichia coli DNA polymerase I. Bacteriophage T7 DNA polymerase displayed a reduced level of OPdA bypass compared to unmodified DNA, and OPdA nearly completely blocked the activity of base excision repair polymerase hPol β. This work demonstrates that bypass of OPdA is generally error-free, modestly decreases the catalytic activity of most polymerases, and blocks hPol β polymerase activity. Although mis-insertion opposite OPdA is relatively weak, the efficiency of bypass may introduce A → G transitions observed in vivo.

Replication past the butadiene diepoxide-derived DNA adduct S-[4-(N(6)-deoxyadenosinyl)-2,3-dihydroxybutyl]glutathione by DNA polymerases

1,2,3,4-Diepoxybutane (DEB), a metabolite of the carcinogen butadiene, has been shown to cause glutathione (GSH)-dependent base substitution mutations, especially A:T to G:C mutations in Salmonella typhimurium TA1535 [Cho, S. H., et al. (2010) Chem. Res. Toxicol. 23, 1544] and Escherichia coli TRG8 cells [Cho, S. H., and Guengerich, F. P. (2012) Chem. Res. Toxicol. 25, 1522]. We previously identified S-[4-(N(6)-deoxyadenosinyl)-2,3-dihydroxybutyl]GSH [N(6)dA-(OH)2butyl-GSH] as a major adduct in the reaction of S-(2-hydroxy-3,4-epoxybutyl)glutathione (DEB-GSH conjugate) with nucleosides and calf thymus DNA and in vivo in livers of mice and rats treated with DEB [Cho, S. H., and Guengerich, F. P. (2012) Chem. Res. Toxicol. 25, 706]. For investigation of the miscoding potential of the major DEB-GSH conjugate-derived DNA adduct [N(6)dA-(OH)2butyl-GSH] and the effect of GSH conjugation on replication of DEB, extension studies were performed in duplex DNA substrates containing the site-specifically incorporated N(6)dA-(OH)2butyl-GSH adduct, N(6)-(2,3,4-trihydroxybutyl)deoxyadenosine adduct (N(6)dA-butanetriol), or unmodified deoxyadenosine (dA) by human DNA polymerases (Pol) η, ι, and κ, bacteriophage polymerase T7, and Sulfolobus solfataricus polymerase Dpo4. Although dTTP incorporation was the most preferred addition opposite the N(6)dA-(OH)2butyl-GSH adduct, N(6)dA-butanetriol adduct, or unmodified dA for all polymerases, the dCTP misincorporation frequency opposite N(6)dA-(OH)2butyl-GSH was significantly higher than that opposite the N(6)dA-butanetriol adduct or unmodified dA with Pol κ or Pol T7. LC-MS/MS analysis of full-length primer extension products confirmed that Pol κ or Pol T7 incorporated the incorrect base C opposite the N(6)dA-(OH)2butyl-GSH lesion. These results indicate the relevance of GSH-containing adducts for the A:T to G:C mutations produced by DEB.

Translesion synthesis past acrolein-derived DNA adducts by human mitochondrial DNA polymerase γ

Acrolein, a mutagenic aldehyde, is produced endogenously by lipid peroxidation and exogenously by combustion of organic materials, including tobacco products. Acrolein reacts with DNA bases forming exocyclic DNA adducts, such as γ-hydroxy-1,N(2)-propano-2'-deoxyguanosine (γ-HOPdG) and γ-hydroxy-1,N(6)-propano-2'-deoxyadenosine (γ-HOPdA). The bulky γ-HOPdG adduct blocks DNA synthesis by replicative polymerases but can be bypassed by translesion synthesis polymerases in the nucleus. Although acrolein-induced adducts are likely to be formed and persist in mitochondrial DNA, animal cell mitochondria lack specialized translesion DNA synthesis polymerases to tolerate these lesions. Thus, it is important to understand how pol γ, the sole mitochondrial DNA polymerase in human cells, acts on acrolein-adducted DNA. To address this question, we investigated the ability of pol γ to bypass the minor groove γ-HOPdG and major groove γ-HOPdA adducts using single nucleotide incorporation and primer extension analyses. The efficiency of pol γ-catalyzed bypass of γ-HOPdG was low, and surprisingly, pol γ preferred to incorporate purine nucleotides opposite the adduct. Pol γ also exhibited ∼2-fold lower rates of excision of the misincorporated purine nucleotides opposite γ-HOPdG compared with the corresponding nucleotides opposite dG. Extension of primers from the termini opposite γ-HOPdG was accomplished only following error-prone purine nucleotide incorporation. However, pol γ preferentially incorporated dT opposite the γ-HOPdA adduct and efficiently extended primers from the correctly paired terminus, indicating that γ-HOPdA is probably nonmutagenic. In summary, our data suggest that acrolein-induced exocyclic DNA lesions can be bypassed by mitochondrial DNA polymerase but, in the case of the minor groove γ-HOPdG adduct, at the cost of unprecedented high mutation rates.

1,3-Butadiene: II. Genotoxicity profile

1,3-Butadiene’s (BD’s) major electrophilic metabolites 1,2-epoxy-3-butene (EB), 1,2-dihydroxy-3,4-epoxybutane (EBD), and 1,2,3,4-diepoxybutane (DEB) are responsible for both its mutagenicity and carcinogenicity. EB, EBD, and DEB are DNA reactive, forming a variety of adducts. All three metabolites are genotoxic in vitro and in vivo, with relative mutagenic potencies of DEB >> EB > EBD. DEB also effectively produces gene deletions and chromosome aberrations. BD’s greater mutagenicity and carcinogenicity in mice over rats as well as its failure to induce chromosome-level mutations in vivo in rats appear to be due to greater production of DEB in mice. Concentrations of EB and DEB in vivo in humans are even lower than in rats. Although most studies of BD-exposed humans have failed to find increases in gene mutations, one group has reported positive findings. Reasons for these discordant results are examined. BD-related chromosome aberrations have never been demonstrated in humans except for the possible production of micronuclei in lymphocytes of workers exposed to extremely high levels of BD in the workplace. The relative potencies of the BD metabolites, their relative abundance in the different species, and the kinds of mutations they can induce are major considerations in BD’s overall genotoxicity profile.

Postsynthetic guanine arylation of DNA by Suzuki-Miyaura cross-coupling

Direct radical addition reactions at the C(8)-site of 2'-deoxyguanosine (dG) can afford C(8)-Ar-dG adducts that are produced by carcinogenic arylhydrazines, polycyclic aromatic hydrocarbons, and certain phenolic toxins. Such modified nucleobases are also highly fluorescent for sensing applications and possess useful electron transfer properties. The site-specific synthesis of oligonucleotides containing the C(8)-Ar-G adduct can be problematic. These lesions are sensitive to acids and oxidants that are commonly used in solid-phase DNA synthesis and are too bulky to be accepted as substrates for enzymatic synthesis by DNA polymerases. Using the Suzuki-Miyaura cross-coupling reaction, we have synthesized a number of C(8)-Ar-G-modified oligonucleotides (dimers, trimers, decamers, and a 15-mer) using a range of arylboronic acids. Good to excellent yields were obtained, and the reaction is insensitive to the nature of the bases flanking the convertible 8-Br-G nucleobase, as both pyrimidines and purines are tolerated. The impact of the C(8)-Ar-G lesion was also characterized by electrospray ionization tandem mass spectrometry, UV melting temperature analysis, circular dichroism, and fluorescence spectroscopy. The C(8)-Ar-G-modified oligonucleotides are expected to be useful substrates for diagnostic applications and understanding the biological impact of the C(8)-Ar-G lesion.

Steric and electrostatic effects at the C2 atom substituent influence replication and miscoding of the DNA deamination product deoxyxanthosine and analogs by DNA polymerases

Deoxyinosine (dI) and deoxyxanthosine (dX) are both formed in DNA at appreciable levels in vivo by deamination of deoxyadenosine (dA) and deoxyguanosine (dG), respectively, and can miscode. Structure-activity relationships for dA pairing have been examined extensively using analogs but relatively few studies have probed the roles of the individual hydrogen-bonding atoms of dG in DNA replication. The replicative bacteriophage T7 DNA polymerase/exonuclease and the translesion DNA polymerase Sulfolobus solfataricus pol IV were used as models to discern the mechanisms of miscoding by DNA polymerases. Removal of the 2-amino group from the template dG (i.e., dI) had little impact on the catalytic efficiency of either polymerase, as judged by either steady-state or pre-steady-state kinetic analysis, although the misincorporation frequency was increased by an order of magnitude. dX was highly miscoding with both polymerases, and incorporation of several bases was observed. The addition of an electronegative fluorine atom at the 2-position of dI lowered the oligonucleotide T(m) and strongly inhibited incorporation of dCTP. The addition of bromine or oxygen (dX) at C2 lowered the T(m) further, strongly inhibited both polymerases, and increased the frequency of misincorporation. Linear activity models show the effects of oxygen (dX) and the halogens at C2 on both DNA polymerases as mainly due to a combination of both steric and electrostatic factors, producing a clash with the paired cytosine O2 atom, as opposed to either bulk or perturbation of purine ring electron density alone.

Versatility of Y-family Sulfolobus solfataricus DNA polymerase Dpo4 in translesion synthesis past bulky N2-alkylguanine adducts

In contrast to replicative DNA polymerases, Sulfolobus solfataricus Dpo4 showed a limited decrease in catalytic efficiency (k(cat)/Km) for insertion of dCTP opposite a series of N2-alkylguanine templates of increasing size from (methyl (Me) to (9-anthracenyl)-Me (Anth)). Fidelity was maintained with increasing size up to (2-naphthyl)-Me (Naph). The catalytic efficiency increased slightly going from the N2-NaphG to the N2-AnthG substrate, at the cost of fidelity. Pre-steady-state kinetic bursts were observed for dCTP incorporation throughout the series (N2-MeG to N2-AnthG), with a decrease in the burst amplitude and k(pol), the rate of single-turnover incorporation. The pre-steady-state kinetic courses with G and all of the six N2-alkyl G adducts could be fit to a general DNA polymerase scheme to which was added an inactive complex in equilibrium with the active ternary Dpo4.DNA.dNTP complex, and only the rates of equilibrium with the inactive complex and phosphodiester bond formation were altered. Two crystal structures of Dpo4 with a template N2-NaphG (in a post-insertion register opposite a 3'-terminal C in the primer) were solved. One showed N2-NaphG in a syn conformation, with the naphthyl group located between the template and the Dpo4 "little finger" domain. The Hoogsteen face was within hydrogen bonding distance of the N4 atoms of the cytosine opposite N2-NaphG and the cytosine at the -2 position. The second structure showed N2-Naph G in an anti conformation with the primer terminus largely disordered. Collectively these results explain the versatility of Dpo4 in bypassing bulky G lesions.

Biological properties of single chemical-DNA adducts: a twenty year perspective

The genome and its nucleotide precursor pool are under sustained attack by radiation, reactive oxygen and nitrogen species, chemical carcinogens, hydrolytic reactions, and certain drugs. As a result, a large and heterogeneous population of damaged nucleotides forms in all cells. Some of the lesions are repaired, but for those that remain, there can be serious biological consequences. For example, lesions that form in DNA can lead to altered gene expression, mutation, and death. This perspective examines systems developed over the past 20 years to study the biological properties of single DNA lesions.

Translesion synthesis across bulky N2-alkyl guanine DNA adducts by human DNA polymerase kappa

DNA polymerase (pol) kappa is one of the so-called translesion polymerases involved in replication past DNA lesions. Bypass events have been studied with a number of chemical modifications with human pol kappa, and the conclusion has been presented, based on limited quantitative data, that the enzyme is ineffective at incorporating opposite DNA damage but proficient at extending beyond bases paired with the damage. Purified recombinant full-length human pol kappa was studied with a series of eight N(2)-guanyl adducts (in oligonucleotides) ranging in size from methyl- to -CH(2)(6-benzo[a]pyrenyl) (BP). Steady-state kinetic parameters (catalytic specificity, k(cat)/K(m)) were similar for insertion of dCTP opposite the lesions and for extension beyond the N(2)-adduct G:C pairs. Mispairing of dGTP and dTTP was similar and occurred with k(cat)/K(m) values approximately 10(-3) less than for dCTP with all adducts; a similar differential was found for extension beyond a paired adduct. Pre-steady-state kinetic analysis showed moderately rapid burst kinetics for dCTP incorporations, even opposite the bulky methyl(9-anthracenyl)- and BPG adducts (k(p) 5.9-10.3 s(-1)). The rapid bursts were abolished opposite BPG when alpha-thio-dCTP was used instead of dCTP, implying rate-limiting phosphodiester bond formation. Comparisons are made with similar studies done with human pols eta and iota; pol kappa is the most resistant to N(2)-bulk and the most quantitatively efficient of these in catalyzing dCTP incorporation opposite bulky guanine N(2)-adducts, particularly the largest (N(2)-BPG).

Kinetic evidence for inefficient and error-prone bypass across bulky N2-guanine DNA adducts by human DNA polymerase iota

DNA polymerase (pol) iota has been proposed to be involved in translesion synthesis past minor groove DNA adducts via Hoogsteen base pairing. The N2 position of G, located in minor groove side of duplex DNA, is a major site for DNA modification by various carcinogens. Oligonucleotides with varying adduct size at G N2 were analyzed for bypass ability and fidelity with human pol iota. Pol iota effectively bypassed N2-methyl (Me)G and N2-ethyl(Et)G, partially bypassed N2-isobutyl(Ib)G and N2-benzylG, and was blocked at N2-CH2(2-naphthyl)G (N2-NaphG), N2-CH2(9-anthracenyl)G (N2-AnthG), and N2-CH2(6-benzo[a]pyrenyl)G. Steady-state kinetic analysis showed decreases of kcat/Km for dCTP insertion opposite N2-G adducts according to size, with a maximal decrease opposite N2-AnthG (61-fold). dTTP misinsertion frequency opposite template G was increased 3-11-fold opposite adducts (highest with N2-NaphG), indicating the additive effect of bulk (or possibly hydrophobicity) on T misincorporation. N2-IbG, N2-NaphG, and N2-AnthG also decreased the pre-steady-state kinetic burst rate compared with unmodified G. High kinetic thio effects (S(p)-2'-deoxycytidine 5'-O-(1-thiotriphosphate)) opposite N2-EtG and N2-AnthG (but not G) suggest that the chemistry step is largely interfered with by adducts. Severe inhibition of polymerization opposite N2,N2-diMeG compared with N2-EtG by pol eta but not by pol iota is consistent with Hoogsteen base pairing by pol iota. Thus, polymerization by pol iota is severely inhibited by a bulky group at G N2 despite an advantageous mode of Hoogsteen base pairing; pol iota may play a limited role in translesion synthesis on bulky N2-G adducts in cells.

Site specific synthesis and polymerase bypass of oligonucleotides containing a 6-hydroxy-3,5,6,7-tetrahydro-9H-imidazo[1,2-a]purin-9-one base, an intermediate in the formation of 1,N2-etheno-2'-deoxyguanosine

The reaction of DNA with certain bis-electrophiles such as chlorooxirane and chloroacetaldehyde produces etheno adducts. These lesions are highly miscoding, and some of the chemical agents that produce them have been shown to be carcinogenic in laboratory animals and in humans. An intermediate in the formation of 1,N2-ethenoguanine is 6-hydroxy-3,5,6,7-tetrahydro-9H-imidazo[1,2-a]purin-9-one (6-hydroxyethanoguanine), which undergoes conversion to the etheno adduct. The chemical properties and miscoding potential of the hydroxyethano adduct have not been previously studied. A synthesis of the hydroxyethano-adducted nucleoside was developed, and it was site specifically incorporated into oligonucleotides. This adduct had a half-life of between 24 and 48 h at neutral pH and 25 degrees C at the nucleoside and oligonucleotide levels. The miscoding potential of the hydroxyethano adduct was examined by primer extension reactions with the DNA polymerases Dpo4 and pol T7-, and the results were compared to the corresponding etheno-adducted oligonucleotide. Dpo4 preferentially incorporated dATP opposite the hydroxyethano adduct and dGTP opposite the etheno adduct; pol T7- preferentially incorporated dATP opposite the etheno adduct while dGTP and dATP were incorporated opposite the hydroxyethano adduct with nearly equal catalytic efficiencies. Collectively, these results indicate that the hydroxyethano adduct has a sufficient lifetime and miscoding properties to contribute to the mutagenic spectrum of chlorooxirane and related genotoxic species.

Efficient and high fidelity incorporation of dCTP opposite 7,8-dihydro-8-oxodeoxyguanosine by Sulfolobus solfataricus DNA polymerase Dpo4

DNA polymerases insert dATP opposite the oxidative damage product 7,8-dihydro-8-oxodeoxyguanosine (8-oxoG) instead of dCTP, to the extent of >90% with some polymerases. Steady-state kinetics with the Y-family Sulfolobus solfataricus DNA polymerase IV (Dpo4) showed 90-fold higher incorporation efficiency of dCTP > dATP opposite 8-oxoG and 4-fold higher efficiency of extension beyond an 8-oxoG:C pair than an 8-oxoG:A pair. The catalytic efficiency for these events (with dCTP or C) was similar for G and 8-oxoG templates. Mass spectral analysis of extended DNA primers showed >/=95% incorporation of dCTP > dATP opposite 8-oxoG. Pre-steady-state kinetics showed faster rates of dCTP incorporation opposite 8-oxoG than G. The measured K(d)(,dCTP) was 15-fold lower for an oligonucleotide containing 8-oxoG than with G. Extension beyond an 8-oxoG:C pair was similar to G:C and faster than for an 8-oxoG:A pair, in contrast to other polymerases. The E(a) for dCTP insertion opposite 8-oxoG was lower than for opposite G. Crystal structures of Dpo4 complexes with oligonucleotides were solved with C, A, and G nucleoside triphosphates placed opposite 8-oxoG. With ddCTP, dCTP, and dATP the phosphodiester bonds were formed even in the presence of Ca(2+). The 8-oxoG:C pair showed classic Watson-Crick geometry; the 8-oxoG:A pair was in the syn:anti configuration, with the A hybridized in a Hoogsteen pair with 8-oxoG. With dGTP placed opposite 8-oxoG, pairing was not to the 8-oxoG but to the 5' C (and in classic Watson-Crick geometry), consistent with the low frequency of this frameshift event observed in the catalytic assays.

Adduct size limits efficient and error-free bypass across bulky N2-guanine DNA lesions by human DNA polymerase eta

The N2 position of guanine (G) is one of the major sites for DNA modification by various carcinogens. Eight oligonucleotides with varying adduct bulk at guanine N2 were analyzed for catalytic efficiency and fidelity with human DNA polymerase (pol) eta, which is involved in translesion synthesis (TLS). Pol eta effectively bypassed N2-methyl(Me)G, N2-ethyl(Et)G, N2-isobutyl(Ib)G, N2-benzyl(Bz)G, and N2-CH2(2-naphthyl)G but was severely blocked at N2-CH2(9-anthracenyl)G (N2-AnthG) and N2-CH2(6-benzo[a]pyrenyl)G (N2-BPG). Steady-state kinetic analysis showed proportional decreases of kcat/Km in dCTP insertion opposite N2-AnthG and N2-BPG (73 and 320-fold) and also kcat/Km in next-base extension from a C paired with each adduct (15 and 51-fold relative to G). Frequencies of dATP misinsertion and extension beyond mispairs were also proportionally increased (70 and 450-fold; 12 and 44-fold) with N2-AnthG and N2-BPG, indicating the effect of adduct bulk on blocking and misincorporation in TLS by pol eta. N2-AnthG and N2-BPG also greatly decreased the pre-steady-state kinetic burst rate (25 and 125-fold) compared to unmodified G. N2-AnthG decreased dCTP binding affinity (2.6-fold) and increased DNA substrate binding affinity. These results and the small kinetic thio effects (S(p)-dCTPalphaS) suggest that the early steps, possibly conformational change, are interfered with by the bulky adducts. In contrast, human pol delta bypassed adducts effectively up to N2-EtG but was strongly blocked by N2-IbG and larger adducts. We conclude that TLS DNA polymerases may be required for the efficient bypass of pol delta-blocking N2-G adducts bulkier than N2-EtG in human cells, and the bulk size can be a major factor for efficient and error-free bypass at these adducts by TLS DNA polymerases.

Kinetic analysis of steps in the repair of damaged DNA by human O6-alkylguanine-DNA alkyltransferase

Rates of individual steps in the removal of alkyl groups from O6-methyl (Me) and -benzyl (Bz) guanine in oligonucleotides by human O6-alkylguanine DNA alkyltransferase (AGT) were estimated using rapid reaction kinetic methods. The overall reaction yields hyperbolic plots of rate versus AGT concentration for O6-MeG but linear plots for the O6-BzG reaction, which is approximately 100-fold faster. The binding of AGT and DNA (double-stranded 30-mer/36-mer complex) appears to be diffusion-limited. The rate of dissociation of the complex is approximately 25-fold slower (approximately 1 s(-1)) for DNA containing O6-MeG or O6-BzG than unmodified DNA. The fluorescent dC-analog 6-methylpyrrolo[2,3-d]pyrimidine-2(3H) one deoxyribonucleoside (pyrrolo dC), which pairs with G, was positioned opposite G, O6-MeG, or O6-BzG and used as a probe of the rate of base flipping. A rapid increase of fluorescence (k approximately 200 s(-1)) was observed with O6-MeG and O6-BzG and AGT but not with a Gly mutation at Arg128, which has been implicated in base flipping with crystal structures. Only weak and slower fluorescence changes were observed with G:pyrrolo dC or T:2-aminopurine pairs. These rate estimates were used in a kinetic model in which AGT binds and scans DNA rapidly, flips O6-alkylG residues, transfers the alkyl group in a chemical step that is rate-limiting in the case of O6-MeG but not O6-BzG, and releases the dealkylated DNA. The results explain the overall patterns of rates of alkyl group removal versus AGT concentration and the effects of the mutations, as well as the greater affinity of AGT for DNA with O6-alkylG lesions.

DNA adduct bypass polymerization by Sulfolobus solfataricus DNA polymerase Dpo4: analysis and crystal structures of multiple base pair substitution and frameshift products with the adduct 1,N2-ethenoguanine

1,N(2)-Etheno(epsilon)guanine is a mutagenic DNA lesion derived from lipid oxidation products and also from some chemical carcinogens. Gel electrophoretic analysis of the products of primer extension by Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) indicated preferential incorporation of A opposite 3'-(1,N(2)-epsilon-G)TACT-5', among the four dNTPs tested individually. With the template 3'-(1,N(2)-epsilon-G)CACT-5', both G and A were incorporated. When primer extension was done in the presence of a mixture of all four dNTPs, high pressure liquid chromatography-mass spectrometry analysis of the products indicated that (opposite 3'-(1,N(2)-epsilon-G)CACT-5') the major product was 5'-GTGA-3' and the minor product was 5'-AGTGA-3'. With the template 3'-(1,N(2)-epsilon-G)TACT-5', the following four products were identified by high pressure liquid chromatography-mass spectrometry: 5'-AATGA-3', 5'-ATTGA-3', 5'-ATGA-3', and 5'-TGA-3'. An x-ray crystal structure of Dpo4 was solved (2.1 A) with a primer-template and A placed in the primer to be opposite the 1,N(2)-epsilon-G in the template 3'-(1,N(2)-epsilon-G)TACT 5'. The added A in the primer was paired across the template T with classic Watson-Crick geometry. Similar structures were observed in a ternary Dpo4-DNA-dATP complex and a ternary Dpo4-DNA-ddATP complex, with d(d)ATP opposite the template T. A similar structure was observed with a ddGTP adjacent to the primer and opposite the C next to 1,N(2)-epsilon-G in 3'-(1,N(2)-epsilon-G)CACT-5'. We concluded that Dpo4 uses several mechanisms, including A incorporation opposite 1,N(2)-epsilon-G and also a variation of dNTP-stabilized misalignment, to generate both base pair and frameshift mutations.

Interaction of the Ty3 reverse transcriptase thumb subdomain with template-primer

Amino acid sequence alignment was used to identify the putative thumb subdomain of reverse transcriptase (RT) from the Saccharomyces cerevisiae long terminal repeat-containing retrotransposon Ty3. The counterpart to helix alphaH of human immunodeficiency virus type 1 (HIV-1) RT, which mediates important interactions with a duplex nucleic acid approximately 3-6 bp behind the DNA polymerase catalytic center, was identified between amino acids 290 and 298 of the Ty3 enzyme. The consequences of substituting Ty3 RT Gln290, Phe292, Gly294, Asn297, and Tyr298 (the counterparts of HIV-1 RT Gln258, Leu260, Gly262, Asn265, and Trp266, respectively) for both DNA polymerase and RNase H activities were examined. DNA-dependent DNA synthesis was evaluated on unmodified substrates and on duplexes containing targeted insertion of locked nucleic acid analogs and abasic lesions in either the template or primer. Based on this combined strategy, our data suggest an interaction of Ty3 RT Tyr298 with primer nucleotide -3, Gly294 with primer nucleotide -4, and Asn297 with template nucleotide -6. Substitution of Ala for Gln290 was well tolerated, despite the high degree of conservation at this position. Mutations in the thumb subdomain of Ty3 also affected RNase H activity, suggesting a closer spatial relationship between its N- and C-terminal catalytic centers compared with HIV-1 RT.

Stereo-selectivity of HIV-1 reverse transcriptase toward isomers of thymidine-5'-O-1-thiotriphosphate

The first pre-steady-state kinetic analysis of the stereo-selective incorporation of Rp- and Sp-isomers of thymidine-5'-O-1-thiotriphosphate (TTPalphaS) by HIV-1 reverse transcriptase (RT) is reported. Rates of polymerization (k(pol)), apparent dissociation constants (K(d)), and substrate specificities (k(pol)/K(d)) were measured for TTP, Rp-TTPalphaS, and Sp-TTPalphaS in the presence of Mg(2+), Mn(2+), and Co(2+). HIV-1 RT exhibits a strong preference to incorporate Sp-TTPalphaS over Rp-TTPalphaS in the presence of Mg(2+); however, this stereo-selective preference was decreased when Mg(2+) was replaced with Mn(2+) and Co(2+). Furthermore, HIV-1 RT exhibited no phosphorothioate elemental effects for the incorporation of Sp-TTPalphaS, but large elemental effects were calculated for Rp-TTPalphaS for each of the metals tested. These results are discussed in relation to our current understanding of the RT active-site structure and the mechanism of DNA synthesis.