Substrate and mispairing properties of 5-formyl-2'-deoxyuridine 5'-triphosphate assessed by in vitro DNA polymerase reactions.

5-Formyluracil (fU) is one of the thymine lesions produced by reactive oxygen radicals in DNA and its constituents. In this work, 5-formyl-2'-deoxyuridine 5'-triphosphate (fdUTP) was chemically synthesized and extensively purified by HPLC. The electron withdrawing 5-formyl group facilitated ionization of fU. Thus, p K a of the base unit of fdUTP was 8.6, significantly lower than that of parent thymine (p K a = 10.0 as dTMP). fdUTP efficiently replaced dTTP during DNA replication catalyzed by Escherichia coli DNA polymerase I (Klenow fragment), T7 DNA polymerase (3'-5'exonuclease free) and Taq DNA polymerase. fU-specific cleavage of the replication products by piperidine revealed that when incorporated as T, incorporation of fU was virtually uniform, suggesting minor sequence context effects on the incorporation frequency of fdUTP. fdUTP also replaced dCTP, but with much lower efficiency than that for dTTP. The substitution efficiency for dCTP increased with increasing pH from 7.2 to 9.0. The parallel correlation between ionization of the base unit of fdUTP (p K a = 8.6) and the substitution efficiency for dCTP strongly suggests that the base-ionized form of fdUTP is involved in mispairing with template G. These data indicate that fU can be specifically introduced into DNA as unique lesions by in vitro DNA polymerase reactions. In addition, fU is potentially mutagenic since this lesion is much more prone to form mispairing with G than parent thymine.     

Structural basis for proficient incorporation of dTTP opposite O6-methylguanine by human DNA polymerase iota

O(6)-methylguanine (O(6)-methylG) is highly mutagenic and is commonly found in DNA exposed to methylating agents, even physiological ones (e.g. S-adenosylmethionine). The efficiency of a truncated, catalytic DNA polymerase ι core enzyme was determined for nucleoside triphosphate incorporation opposite O(6)-methylG, using steady-state kinetic analyses. The results presented here corroborate previous work from this laboratory using full-length pol ι, which showed that dTTP incorporation occurs with high efficiency opposite O(6)-methylG. Misincorporation of dTTP opposite O(6)-methylG occurred with ～6-fold higher efficiency than incorporation of dCTP. Crystal structures of the truncated form of pol ι with O(6)-methylG as the template base and incoming dCTP or dTTP were solved and showed that O(6)-methylG is rotated into the syn conformation in the pol ι active site and that dTTP misincorporation by pol ι is the result of Hoogsteen base pairing with the adduct. Both dCTP and dTTP base paired with the Hoogsteen edge of O(6)-methylG. A single, short hydrogen bond formed between the N3 atom of dTTP and the N7 atom of O(6)-methylG. Protonation of the N3 atom of dCTP and bifurcation of the N3 hydrogen between the N7 and O(6) atoms of O(6)-methylG allow base pairing of the lesion with dCTP. We conclude that differences in the Hoogsteen hydrogen bonding between nucleotides is the main factor in the preferential selectivity of dTTP opposite O(6)-methylG by human pol ι, in contrast to the mispairing modes observed previously for O(6)-methylG in the structures of the model DNA polymerases Sulfolobus solfataricus Dpo4 and Bacillus stearothermophilus DNA polymerase I.     

Chemical synthesis of novel base pairs and their enzymatic incorporation into DNA.

A novel base pair, 2-amino-6-(N,N-dimethylamino)purine (denoted x) and the counter part, pyridin-2-one (denoted y) were designed. The bulky 6-dimethylamino group of x is expected to eliminate base pairing with all natural bases. The phosphoramidite of x for DNA templates and the 2'-deoxyribonucleoside triphosphate of y (dyTP) for a substrate were synthesized, and the selectivity of the enzymatic incorporation of dyTP opposite x in the templates was examined. dyTP was preferentially incorporated opposite x than canonical dNTPs by Klenow fragment of Escherichia coli DNA polymerase I. While dyTP was also incorporated opposite A and G, the misincorporation was suppressed in the presence of dTTP and dCTP, respectively.     

Inhibition of DNA polymerase reactions by pyrimidine nucleotide analogues lacking the 2-keto group.

To investigate the influence of the pyrimidine 2-keto group on selection of nucleotides for incorporation into DNA by polymerases, we have prepared two C nucleoside triphosphates that are analogues of dCTP and dTTP, namely 2-amino-5-(2'-deoxy-beta-d-ribofuranosyl)pyridine-5'-triphosphate (d*CTP) and 5-(2'-deoxy- beta-d-ribofuranosyl)-3-methyl-2-pyridone-5'-triphosphate (d*TTP) respectively. Both proved strongly inhibitory to PCR catalysed by Taq polymerase; d*TTP rather more so than d*CTP. In primer extension experiments conducted with either Taq polymerase or the Klenow fragment of Escherichia coli DNA polymerase I, both nucleotides failed to substitute for their natural pyrimidine counterparts. Neither derivative was incorporated as a chain terminator. Their capacity to inhibit DNA polymerase activity may well result from incompatibility with the correctly folded form of the polymerase enzyme needed to stabilize the transition state and catalyse phosphodiester bond formation.     

Major oxidative products of cytosine, 5-hydroxycytosine and 5-hydroxyuracil, exhibit sequence context-dependent mispairing in vitro.

Two major stable oxidation products of 2'-deoxycytidine are 2'-deoxy-5-hydroxycytidine (5-OHdC) and 2'-deoxy-5-hydroxyuridine (5-OHdU). In order to study the in vitro incorporation of 5-OHdC and 5-OHdU into DNA by DNA polymerase, and to check the base pairing specificity of these modified bases, 5-OHdCTP and 5-OHdUTP were synthesized. Incorporation studies showed that 5-OHdCTP can replace dCTP, and to a much lesser extent dTTP, as a substrate for Escherichia coli DNA polymerase I Klenow fragment (exonuclease free). However, 5-OHdUTP can only be incorporated into DNA in place of dTTP. To study the specificity of nucleotide incorporation opposite 5-hydroxypyrimidines in template DNA, 18- and 45-member oligodeoxyribonucleotides, containing an internal 5-OHdC or 5-OHdU in two different sequence contexts, were used. Translesion synthesis past 5-OHdC and 5-OHdU in both oligonucleotides occurred, but pauses both opposite, and one nucleotide prior to, the modified base in the template were observed. The specificity of nucleotide incorporation opposite 5-OHdC and 5-OHdU in the template was sequence context dependent. In one sequence context, dG was the predominant nucleotide incorporated opposite 5-OHdC with dA incorporation also observed; in this sequence context, dA was the principal nucleotide incorporated opposite 5-OHdU. However in a second sequence context, dC was the predominant base incorporated opposite 5-OHdC. In that same sequence context, dC was also the predominant nucleotide incorporated opposite 5-OHdU. These data suggest that the 5-hydroxypyrimidines have the potential to be premutagenic lesions leading to C-->T transitions and C-->G transversions.     

Quantitation of cellular deoxynucleoside triphosphates

Eukaryotic cells contain a delicate balance of minute amounts of the four deoxyribonucleoside triphosphates (dNTPs), sufficient only for a few minutes of DNA replication. Both a deficiency and a surplus of a single dNTP may result in increased mutation rates, faulty DNA repair or mitochondrial DNA depletion. dNTPs are usually quantified by an enzymatic assay in which incorporation of radioactive dATP (or radioactive dTTP in the assay for dATP) into specific synthetic oligonucleotides by a DNA polymerase is proportional to the concentration of the unknown dNTP. We find that the commonly used Klenow DNA polymerase may substitute the corresponding ribonucleotide for the unknown dNTP leading in some instances to a large overestimation of dNTPs. We now describe assay conditions for each dNTP that avoid ribonucleotide incorporation. For the dTTP and dATP assays it suffices to minimize the concentrations of the Klenow enzyme and of labeled dATP (or dTTP); for dCTP and dGTP we had to replace the Klenow enzyme with either the Taq DNA polymerase or Thermo Sequenase. We suggest that in some earlier reports ribonucleotide incorporation may have caused too high values for dGTP and dCTP.     

Two DNA polymerases of Escherichia coli display distinct misinsertion specificities for 2-hydroxy-dATP during DNA synthesis

The insertion specificities of an oxidized dATP analogue, 2-hydroxydeoxyadenosine 5'-triphosphate (2-OH-dATP), were determined using the alpha (catalytic) subunit of Escherichia coli DNA polymerase III and the exonuclease-deficient Klenow fragment of DNA polymerase I. In contrast to our previous observation that mammalian DNA polymerase alpha incorporated the oxidized nucleotide opposite T and C, these two E. coli DNA polymerases incorporated 2-OH-dATP opposite T and G on the DNA template. Steady-state kinetic studies indicated that the alpha subunit incorporated 2-OH-dATP 10 times more frequently opposite T than opposite G. On the other hand, the incorporation of 2-OH-dATP opposite T by the exonuclease-deficient Klenow fragment was 2 orders of magnitude more efficient than that opposite G. These results indicate that the misinsertion specificity of 2-OH-dATP differs between replicative and repair-type DNA polymerases, and provide a biochemical basis for the mutations induced by 2-OH-dATP in E. coli.     

Mechanism and dynamics of translesion DNA synthesis catalyzed by the Escherichia coli Klenow fragment

Translesion DNA synthesis represents the ability of a DNA polymerase to incorporate and extend beyond damaged DNA. In this report, the mechanism and dynamics by which the Escherichia coli Klenow fragment performs translesion DNA synthesis during the misreplication of an abasic site were investigated using a series of natural and non-natural nucleotides. Like most other high-fidelity DNA polymerases, the Klenow fragment follows the "A-rule" of translesion DNA synthesis by preferentially incorporating dATP opposite the noninstructional lesion. However, several 5-substituted indolyl nucleotides lacking classical hydrogen-bonding groups are incorporated approximately 100-fold more efficiently than the natural nucleotide. In general, analogues that contain large substituent groups in conjunction with significant pi-electron density display the highest catalytic efficiencies ( k cat/ K m) for incorporation. While the measured K m values depend upon the size and pi-electron density of the incoming nucleotide, k cat values are surprisingly independent of both biophysical features. As expected, the efficiency by which these non-natural nucleotides are incorporated opposite templating nucleobases is significantly reduced. This reduction reflects minimal increases in K m values coupled with large decreases in k cat values. The kinetic data obtained with the Klenow fragment are compared to that of the high-fidelity bacteriophage T4 DNA polymerase and reveal distinct differences in the dynamics by which these non-natural nucleotides are incorporated opposite an abasic site. These biophysical differences argue against a unified mechanism of translesion DNA synthesis and suggest that polymerases employ different catalytic strategies during the misreplication of damaged DNA.     

Comparison of polymerase insertion and extension kinetics of a series of O2-alkyldeoxythymidine triphosphates and O4-methyldeoxythymidine triphosphate

The effect of alkyl group size on ability to act as deoxythymidine triphosphate (dTTP) has been studied for the carcinogen products O2-methyl-, O2-ethyl-, and O2-isopropyl-dTTP by using three types of nucleic acids as template and DNA polymerase I (Pol I) or Klenow fragment as the polymerizing enzymes. Apparent Km and relative Vmax values were determined in primer extension on M13 DNA at a single defined site, in poly[d(A-T)], and in nicked DNA. These data are the basis for calculation of the relative rate of insertion opposite A, relative to dTTP. The insertion rate for any O2-alkyl-dTTP is much higher than for a mismatch between unmodified dNTPs. Unexpectedly, O2-isopropyl-dTTP is more efficiently utilized than O2-methyl-dTTP or O2-ethyl-dTTP on each of the templates. O2-isopropyl-dTTP also substitutes for dTTP over extended times of DNA synthesis at a rate only slightly lower than that of dTTP. Parallel experiments using O4-methyl-dTTP under the same conditions show that it is incorporated opposite A more frequently than is O2-methyl-dTTP. Therefore, both the ring position and the size of the alkyl group influence polymerase recognition. Once formed, all O2-alkyl-T.A termini permit elongation, as does O4-methyl-T.A. In contrast to the relative difficulty of incorporating the O-alkyl-dTTPs, formation of the following normal base pair (C.G) occurs rapidly when dGTP is present. This indicates that a single O-alkyl-T.A pair does not confer significant structural distortion recognized by Pol I.     

Induction of mutation in mouse FM3A cells by N4-aminocytidine-mediated replicational errors.

To explore the potential use of a nucleoside analog, N4-aminocytidine, in studies of cellular biology, the mechanism of mutation induced by this compound in mouse FM3A cells in culture was studied. On treatment of cells in suspension with N4-aminocytidine, the mutation to ouabain resistance was induced. The major DNA-replicating enzyme in mammalian cells, DNA polymerase alpha, was used to investigate whether the possible cellular metabolite of N4-aminocytidine, N4-aminodeoxycytidine 5'-triphosphate (dCamTP), can be incorporated into the DNA during replication. Using [3H]dCamTP in an in vitro DNA-synthesizing system, we were able to show that this nucleotide analog can be incorporated into newly formed DNA and that it can serve as a substitute for either dCTP or dTTP. dCamTP in the absence of dCTP maintained the activated calf thymus DNA-directed polymerization of deoxynucleoside triphosphates as efficiently as in its presence. Even in the presence of dCTP, dCamTP was incorporated into the polynucleotide. When dCamTP was used as a single substrate in the poly(dA)-oligo(dT)-directed polymerase reaction, it was incorporated into the polynucleotide fraction. The extent of incorporation was 4% of that of dTTP incorporation when dTTP was used as a single substrate. Even in the presence of dTTP, dCamTP incorporation was observed. A copolymer containing N4-aminocytosine residues was shown to incorporate guanine residues opposite the N4-aminocytosines. However, we were unable to observe adenine incorporation opposite N4-aminocytosine in templates. These cell-free experiments show that an AT-to-GC transition can take place in the presence of dCamTP during DNA synthesis, strongly suggesting that the mutation induced in the FM3A cells by N4-aminocytidine is due to replicational errors.     

DNA polymerases β and λ as potential participants of TLS during genomic DNA replication on the lagging strand

The main strategy used by pro-and eukaryotic cells for replication of damaged DNA is translesion synthesis (TLS). Here, we investigate the TLS process catalyzed by DNA polymerases β and λ on DNA substrates using mono-or dinucleotide gaps opposite damage located in the template strand. An analog of a natural apurinic/apyrimidinic site, the 3-hydroxy-2-hydroxymetylthetrahydrofuran residue (THF), was used as damage. DNA was synthesized in the presence of either Mg²⁺ or Mn²⁺. DNA polymerases β and λ were able to catalyze DNA synthesis across THF only in the presence of Mn²⁺. Moreover, strand displacement synthesis was not observed. The primer was elongated by only one nucleotide. Another unusual aspect of the synthesis is that dTTP could not serve as a substrate in all cases. dATP was a preferential substrate for synthesis catalyzed by DNA polymerase β. As for DNA polymerase λ, dGMP was the only incorporated nucleotide out of four investigated. Modified on heterocyclic base photoreactive analogs of dCTP and dUTP showed substrate specificity for DNA polymerase β. In contrast, the dCTP analog modified on the exocyclic amino group was a substrate for DNA polymerase λ. We also observed that human replication protein A inhibited polymerase incorporation by both DNA polymerases β and λ on DNA templates containing damage.     

Role of hoogsteen edge hydrogen bonding at template purines in nucleotide incorporation by human DNA polymerase iota

Human DNA polymerase iota (Pol iota) differs from other DNA polymerases in that it exhibits a marked template specificity, being more efficient and accurate opposite template purines than opposite pyrimidines. The crystal structures of Pol iota with template A and incoming dTTP and with template G and incoming dCTP have revealed that in the Pol iota active site, the templating purine adopts a syn conformation and forms a Hoogsteen base pair with the incoming pyrimidine which remains in the anti conformation. By using 2-aminopurine and purine as the templating residues, which retain the normal N7 position but lack the N(6) of an A or the O(6) of a G, here we provide evidence that whereas hydrogen bonding at N(6) is dispensable for the proficient incorporation of a T opposite template A, hydrogen bonding at O(6) is a prerequisite for C incorporation opposite template G. To further analyze the contributions of O(6) and N7 hydrogen bonding to DNA synthesis by Pol iota, we have examined its proficiency for replicating through the (6)O-methyl guanine and 8-oxoguanine lesions, which affect the O(6) and N7 positions of template G, respectively. We conclude from these studies that for proficient T incorporation opposite template A, only the N7 hydrogen bonding is required, but for proficient C incorporation opposite template G, hydrogen bonding at both the N7 and O(6) is an imperative. The dispensability of N(6) hydrogen bonding for proficient T incorporation opposite template A has important biological implications, as that would endow Pol iota with the ability to replicate through lesions which impair the Watson-Crick hydrogen bonding potential at both the N1 and N(6) positions of templating A.     

The competitive miscoding of O6-methylguanine and O6-ethylguanine and the possible importance of cellular deoxynucleoside 5'-triphosphate pool sizes in mutagenesis and carcinogenesis

Using initiated poly(dG,O6-RdG) and poly(dA,O6-RdG) polynucleotides as templates for DNA polymerase I in vitro the promutagenic potential of O6-MeG and O6-EtG has been confirmed, together with the possibility of minor miscoding pathways for O6-RG. These lead to the incorporation of dAMP and dGMP, which could give rise to some of the limited number of transversions that have been observed arising from the action of alkylating agents. The results are compatible with the current knowledge of oncogenes, explaining the changes in base sequence that have been observed. The competition for the miscoding of O6-RG which leads to the incorporation of dCMP in addition to the expected dTMP is also shown. The relative amounts of these two nucleotides incorporated depend upon the concentrations of the dCTP and dTTP in the assay. The mutagenic efficiency of O6-MeG is constant at approx. 0.4 over a wide range of dTTP and dCTP concentrations and only increases when the dCTP in the assay ceases to saturate the polymerizing enzyme, indicating that the DNA polymerase I plays a role in determining the mutagenic efficiency of a modified base. Although the mutagenic efficiency of both O6-MeG and O6-EtG depends upon the relative concentrations. of dTTP and dCTP in the assay, a reduction in the concentration of dCTP can be more effective at increasing the mutagenic efficiency than a corresponding increase in the concentration of dTTP. These results indicate the importance of cellular dNTP pools in determining the cellular response to agents.     

Error-prone bypass of O6-methylguanine by DNA polymerase of Pseudomonas aeruginosa phage PaP1

O⁶-Methylguanine (O⁶-MeG) is highly mutagenic and is commonly found in DNA exposed to methylating agents, generally leads to G:C to A:T mutagenesis. To study DNA replication encountering O⁶-MeG by the DNA polymerase (gp90) of P. aeruginosa phage PaP1, we analyzed steady-state and pre-steady-state kinetics of nucleotide incorporation opposite O⁶-MeG by gp90 exo⁻. O⁶-MeG partially inhibited full-length extension by gp90 exo⁻. O⁶-MeG greatly reduces dNTP incorporation efficiency, resulting in 67-fold preferential error-prone incorporation of dTTP than dCTP. Gp90 exo⁻ extends beyond T:O⁶-MeG 2-fold more efficiently than C:O⁶-MeG. Incorporation of dCTP opposite G and incorporation of dCTP or dTTP opposite O⁶-MeG show fast burst phases. The pre-steady-state incorporation efficiency (k_pol/K_d,dNTP) is decreased in the order of dCTP:G > dTTP:O⁶-MeG > dCTP:O⁶-MeG. The presence of O⁶-MeG at template does not affect the binding affinity of polymerase to DNA but it weakened their binding in the presence of dCTP and Mg²⁺. Misincorporation of dTTP opposite O⁶-MeG further weakens the binding affinity of polymerase to DNA. The priority of dTTP incorporation opposite O⁶-MeG is originated from the fact that dTTP can induce a faster conformational change step and a faster chemical step than dCTP. This study reveals that gp90 bypasses O⁶-MeG in an error-prone manner and provides further understanding in DNA replication encountering mutagenic alkylation DNA damage for P. aeruginosa phage PaP1.     

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).     

Toward understanding the mutagenicity of an environmental carcinogen: structural insights into nucleotide incorporation preferences

Bulky carcinogen-DNA adducts, including (+)-trans-anti-[BP]-N(2)-dG derived from the reaction of (+)-anti-benzo[a]pyrene diol epoxide with guanine, often block the progression of DNA polymerases. However, when rare bypass of the lesions does occur, they may be misreplicated. Experimental results have shown that nucleotides are inserted opposite the (+)-trans-anti-[BP]-N(2)-dG adduct by bacteriophage T7 DNA polymerase with the order of preference A>T>or=G>C. To gain structural insights into the effects of the bulky adduct on nucleotide incorporation within the polymerase active site, molecular modeling and molecular dynamics simulations were carried out using T7 DNA polymerase to permit the relation of function to structure. We modeled the (+)-trans-anti-[BP]-N(2)-dG adduct opposite incoming dGTP, dTTP and dCTP nucleotides, as well as unmodified guanine opposite its normal partner dCTP as a control, to compare with our previous simulation with dATP opposite the adduct. The modeling required that the (+)-trans-anti-[BP]-N(2)-dG adduct adopt the syn conformation in each case to avoid deranging essential protein-DNA interactions. While the dATP: (+)-trans-anti-[BP]-N(2)-dG pair was well accommodated within the active site of T7 DNA polymerase, dCTP fit poorly opposite the adduct, adopting an orientation perpendicular to the plane of the syn modified guanine during the simulation. Rotation about the glycosidic bond of the dCTP residue to this abnormal position was allowed because only one hydrogen bond between dCTP and the (+)-trans-anti-[BP]-N(2)-dG residue evolved during the simulation, and this hydrogen bond was directly across from the dCTP glycosidic bond. The dTTP and dGTP nucleotides, incorporated with an intermediate preference opposite (+)-trans-anti-[BP]-N(2)-dG, were accommodated reasonably well, but not as stably as the dATP nucleotide, due to a skewed primer-template alignment and more exposed BP moiety, respectively. In addition, the extent of stabilizing interactions between the nascent base-pair in each simulation was correlated positively with the incorporation preference of that particular nucleotide. The dATP nucleotide is accommodated most stably opposite the adduct, with protein-DNA hydrogen bonding interactions and an active-site pocket size that do not deviate significantly from those of the control simulation. The simulations of dTTP and dGTP opposite (+)-trans-anti-[BP]-N(2)-dG exhibited more instability in interactions between the protein and the nascent base-pair than the dATP system. However, the active-site pocket size of the dTTP and dGTP simulations remained stable. The dCTP: (+)-trans-anti-[BP]-N(2)-dG system had the least number of stabilizing interactions, and the active-site pocket of this system increased in size significantly compared to the control and other dNTPs opposite the adduct. These simulations elucidated why A is inserted opposite (+)-trans-anti-[BP]-N(2)-dG most frequently, while T and G are inserted opposite the adduct to an extent intermediate between A and C, and C is most rarely incorporated. Structural rationalization of the incorporation preference opposite (+)-trans-anti-[BP]-N(2)-dG by T7 DNA polymerase contributes to providing a molecular explanation for mutations caused by this carcinogen-DNA adduct in a model system.