A structural model for sequence-specific proflavin-DNA interactions during in vitro frameshift mutagenesis.

Molecular models describing intermediates that may lead to proflavin-induced 1 bp deletions during in vitro polymerization by E. coli DNA polymerase I Klenow fragment are proposed. The models provide structural explanations for the fact that the induced frameshifts always occur opposite template bases that are adjacent to 5' pyrimidines and are based on the underlying hypothesis that the deletions arise because the polymerase passes by a template base without copying it. Because the most frequent mutations are opposite Pu in the template sequence 5' Py Pu 3', a single-strand loop-out model was constructed for this sequence and proflavin was added, using structures found in crystalline oligonucleotides and their complexes with proflavin. The model seeks to rationalize the roles of the 5' pyrimidine and proflavin in facilitating the bypass. Four potential roles for proflavin in mutagenesis are described: 1) stacking on the looped-out base; 2) stacking on the base pair immediately preceding the site of mutation; 3) hydrogen bonding with the 5' pyrimidine; 4) hydrogen bonding with the phosphate backbone. These models point to the possibility that a number of proflavin-DNA interactions may be involved. In contrast, modeling does not suggest a role for classically intercalated proflavin in frameshift mutagenesis arising during in vitro DNA polymerization.     

Effects of proflavin and photoactivated proflavin on the template function of single-stranded DNA

DNA context-specific effects of the association of proflavin, single-stranded DNA and DNA polymerase on DNA polymerization reactions were examined. Frameshift mutations induced by the presence of proflavin during in vitro DNA replication of a single-stranded DNA template by the Klenow fragment of Escherichia coli DNA polymerase I were sequenced. More than 80% of the frameshifts were one base-pair deletions opposite purine bases that were immediately 3' to pyrimidines. Purines (Pu) that were not adjacent to pyrimidines (Py) were not deletion sites. The remaining deletions were opposite template pyrimidines that were also immediately 3' to another pyrimidine. All pyrimidine site deletions occurred in the context 5' PyPyPu 3'. In additional experiments, the site-specific inhibition of processive DNA polymerization by proflavin was examined. A novel inhibition of polymerization was found opposite all pyrimidines in the template when proflavin-template complexes were exposed to ten seconds of white light. This inhibition of polymerization is reversible. Longer photoactivation led to an altered pattern of DNA sequence-specific inhibition that was not reversible. The role of DNA sequence-specific interactions of proflavin with DNA in proflavin mutagenesis is discussed.     

DNA Sequence Effects on Single Base Deletions Arising during DNA Polymerization in Vitro by Escherichia Coli Klenow Fragment Polymerase

Most single base deletions detected after DNA polymerization in vitro directed by either Escherichia coli DNA polymerase I or its Klenow fragment are opposite Pu in the template. The most frequent study, were previously found to be associated with the consensus template context 5'-PyTPu-3'. In this study, the predictive power of the consensus sequence on single base deletion frequencies was directly tested by parallel comparison of mutations arising in four related DNAs differing by a single base. G, a deletion hotspot within the template context 5'-TTGA-3', was substituted by each of the 3 other bases. Previous studies had shown that deletions opposite the G were frequent but that deletions opposite its neighboring A were never detected. Based on the predictions of the consensus, the substitution of T for G should produce frequent deletions opposite the neighboring A due to its new 5'-TTTA-3' template context. This prediction was fulfilled; no deletions of this A were detected in the other templates. The consensus further predicted that deletions opposite template C would be lower than those opposite either A or G at the same site and this prediction was also fulfilled. The C substitution also produced a new hotspot for 1 bp deletions 14 bp away. The new hotspot depends on quasi-palindromic misalignment of the newly synthesized DNA strand during polymerization; accurate, but ectopically templated synthesis is responsible for this mutagenesis. Mutations templated by quasi-palindromic misalignments have previously been recognized when they produced complex sequence changes; here we show that this mechanism can produce frequent single base deletions. The unique stimulation of misalignment mutagenesis by the C substitution in the template is consistent with the singular ability of C at that site to contribute to extended complementary pairing during the DNA misalignment that precedes mutagenesis.     

Structural basis of error‐prone replication and stalling at a thymine base by human DNA polymerase ι

Human DNA polymerase ι (polι) is a unique member of Y‐family polymerases, which preferentially misincorporates nucleotides opposite thymines (T) and halts replication at T bases. The structural basis of the high error rates remains elusive. We present three crystal structures of polι complexed with DNA containing a thymine base, paired with correct or incorrect incoming nucleotides. A narrowed active site supports a pyrimidine to pyrimidine mismatch and excludes Watson–Crick base pairing by polι. The template thymine remains in an anti conformation irrespective of incoming nucleotides. Incoming ddATP adopts a syn conformation with reduced base stacking, whereas incorrect dGTP and dTTP maintain anti conformations with normal base stacking. Further stabilization of dGTP by H‐bonding with Gln59 of the finger domain explains the preferential T to G mismatch. A template ‘U‐turn’ is stabilized by polι and the methyl group of the thymine template, revealing the structural basis of T stalling. Our structural and domain‐swapping experiments indicate that the finger domain is responsible for polι's high error rates on pyrimidines and determines the incorporation specificity.     

B family DNA polymerases asymmetrically recognize pyrimidines and purines

We utilized a series of pyrimidine analogues modified at O(2), N-3, and N(4)/O(4) to determine if two B family DNA polymerases, human DNA polymerase α and herpes simplex virus I DNA polymerase, choose whether to polymerize pyrimidine dNTPs using the same mechanisms they use for purine dNTPs. Removing O(2) of a pyrimidine dNTP vastly decreased the level of incorporation by these enzymes and also compromised fidelity in the case of C analogues, while removing O(2) from the templating base had more modest effects. Removing the Watson-Crick hydrogen bonding groups of N-3 and N(4)/O(4) greatly impaired polymerization, both of the resulting dNTP analogues and of natural dNTPs opposite these pyrimidine analogues when present in the template strand. Thus, the Watson-Crick hydrogen bonding groups of a pyrimidine clearly play an important role in enhancing correct dNTP polymerization but are not essential for preventing misincorporation. These studies also indicate that DNA polymerases recognize bases extremely asymmetrically, both in terms of whether they are a purine or pyrimidine and whether they are in the template or are the incoming dNTP. The mechanistic implications of these results with regard to how polymerases discriminate between right and wrong dNTPs are discussed.     

Configurational effects on conformational properties of cyclic nucleotides. I. Theoretical calculations of conformer preferences in α-nucleoside 3′,5′ cyclic monophosphates

A comparative study has been made of the configurational effects on the conformational properties of α- and β-anomers of purine and pyrimidine nucleoside 3′,5′,-cyclic monophosphates and their 2′-arabino epimers. Correlation between orientation of the base and the 2′-hydroxyl group have been studied theoretically using the PCILO (Perturbative Configuration Interaction using Localized Orbitals) method. The effect of change in ribose puckering on the base-hydroxyl interaction has also been studied. The result show that steric repulsions and stabilizing effects of intramolecular hydrogen bonding between the base and the 2′-hydroxyl (OH) group are of major importance in determining configurations of α-anomers and 2′-arabino-β-epimers. For example, hydrogen bonding between the 2′-hydroxyl group and polar centers on the base ring is clearly implicated as a determinant of syn-anti preferences of the purine (adenine) or pyrimidine (uracil) bases in α-nucleoside 3′,5′-cyclic monophosphates. Moreover, barrier heights for interconversion between conformers are sensitive to ribose pucker and 2′-OH orientations. The result clearly show that a change in ribose-ring pucker plays an essential role in relieving repulsive interaction between the base and the 2′-hydroxyl group. Thus a C2′-exo-C3′-endo (₂T³) pucker is favored for α-anomers in contrast with the C4′-exo-C3′-endo (₄T³) from found in β-compounds.     

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.     

Loop Stereochemistry and Dynamics in Transfer RNA

Abstract

The stereochemistry and the dynamics of two loops of yeast tRNA-asp, the thymine loop and the anticodon loop, are compared in the hope of a better understanding of the relationships between loop sequence and loop topology. Both loops are seven residues long and both present sharp turns after the second residue, U33 and ψ55, stabilized by hydrogen bonds between N3-H of the pyrimidine and the phosphates of C36 and A58 and stacking interactions of the pyrimidine ring with the phosphates of U35 and A57, respectively. In the thymine loop, the two purines following C56, A57 and A58, open up to leave space for the intercalation of the first invariant guanine residue of the D-loop, while the two pyrimidine bases, which follow A58, turn away from the stacking pattern of the thymine arm and stack instead with the last base pair of the dihydrouridine arm A15-U48. In the anticodon loop, however, the bases G34 to C38 form an helical stack in continuity with the anticodon stem on the 3′-end. At the same time C36 forms Watson-Crick hydrogen bonds with G34 of a twofold symmetrically related molecule. The anticodon-anticodon base pairing interactions between symmetrically-related molecules are stabilized by stacking with the modified base G37 on both sides of the triplet. Some comparisons are made with the structure of yeast tRNA-phe and some implications about the structure of mitochondrial tRNAs are discussed.     

Mechanisms of targeted frameshift mutations: Insertions arising during error-prone or SOS synthesis of DNA containing cis-syn cyclobutane thymine dimers

It is still unclear how frameshift mutations arise at cyclobutane pyrimidine dimers. The polymerase model is commonly used to explain the mechanisms of various mutations. An alternative polymerase-tautomer model was developed for UV-induced mutagenesis. A mechanism was proposed for targeted insertions caused by cis-syn cyclobutane thymine dimers. Targeted insertions are frameshift mutations due to addition of one or more nucleotides in a DNA sequence opposite to a lesion capable of stopping DNA synthesis. Among other factors, cyclobutane pyrimidine dimers can cause targeted insertions. UV irradiation can change the tautomeric form of DNA bases. Five rare tautomeric forms are possible for thymine, and they are stable when the thymine is a component of a cyclobutane dimer. A structural analysis showed that none of the canonical nucleotides can be added opposite to a specific rare thymine tautomer so that hydrogen bonds form between the two bases. A single nucleotide gap is consequently left in the corresponding site of the nascent strand when a specialized or modified DNA polymerase drives SOS or error-prone DNA synthesis on a template containing cis-syn cyclobutane thymine dimers with a base occurring in the rare tautomeric form. If the DNA composition is homogenous within the region, the end of the growing DNA strand may slip to form a complementary pair with the nucleotide adjacent to the dimer according to the Streisinger model, thus producing a loop. A targeted insertion is thereby generated to make the daughter strand longer. Targeted insertions were for the first time assumed to result from the cis-syn cyclobutane thymine dimers wherein one or both of the bases occur in the specific tautomeric form that does not allow the addition and hydrogen bonding of any canonical nucleotide in the opposite position. A model was developed to explain how targeted insertions of one or more nucleotides are caused by cis-syn cyclobutane thymine dimers. Thus, the polymerase-tautomer model can explain the nature and formation of targeted frameshift mutations in addition to hot and cold spots or targeted or untargeted nucleotide substitutions.     

Escherichia coli DNA polymerase III is responsible for the high level of spontaneous mutations in mutT strains

Reactive oxygen species induce oxidative damage in DNA precursors, i.e. dNTPs, leading to point mutations upon incorporation. Escherichia coli mutT strains, deficient in the activity hydrolysing 8‐oxo‐7,8‐dihydro‐2′‐deoxyguanosine 5′‐triphosphate (8‐oxo‐dGTP), display more than a 100‐fold higher spontaneous mutation frequency over the wild‐type strain. 8‐oxo‐dGTP induces A to C transversions when misincorporated opposite template A. Here, we report that DNA pol III incorporates 8‐oxo‐dGTP ≈ 20 times more efficiently opposite template A compared with template C. Single, double or triple deletions of pol I, pol II, pol IV or pol V had modest effects on the mutT mutator phenotype. Only the deletion of all four polymerases led to a 70% reduction of the mutator phenotype. While pol III may account for nearly all 8‐oxo‐dGTP incorporation opposite template A, it only extends ≈ 30% of them, the remaining 70% being extended by the combined action of pol I, pol II, pol IV or pol V. The unique property of pol III, a C‐family DNA polymerase present only in eubacteria, to preferentially incorporate 8‐oxo‐dGTP opposite template A during replication might explain the high spontaneous mutation frequency in E. coli mutT compared with the mammalian counterparts lacking the 8‐oxo‐dGTP hydrolysing activities.     

Frameshift Deletion by Sulfolobus solfataricus P2 DNA Polymerase Dpo4 T239W Is Selective for Purines and Involves Normal Conformational Change Followed by Slow Phosphodiester Bond Formation

The human DNA polymerase κ homolog Sulfolobus solfataricus DNA polymerase IV (Dpo4) produces “−1” frameshift deletions while copying unmodified DNA and, more frequently, when bypassing DNA adducts. As judged by steady-state kinetics and mass spectrometry, bypass of purine template bases to produce these deletions occurred rarely but with 10-fold higher frequency than with pyrimidines. The DNA adduct 1,N²-etheno-2′-deoxyguanosine, with a larger stacking surface than canonical purines, showed the highest frequency of formation of −1 frameshift deletions. Dpo4 T239W, a mutant we had previously shown to produce fluorescence changes attributed to conformational change following dNTP binding opposite cognate bases (Beckman, J. W., Wang, Q., and Guengerich, F. P. (2008) J. Biol. Chem. 283, 36711–36723), reported similar conformational changes when the incoming dNTP complemented the base following a templating purine base or bulky adduct (i.e. the “+1” base). However, in all mispairing cases, phosphodiester bond formation was inefficient. The frequency of −1 frameshift events and the associated conformational changes were not dependent on the context of the remainder of the sequence. Collectively, our results support a mechanism for −1 frameshift deletions by Dpo4 that involves formation of active complexes via a favorable conformational change that skips the templating base, without causing slippage or flipping out of the base, to incorporate a complementary residue opposite the +1 base, in a mechanism previously termed “dNTP-stabilized incorporation.” The driving force is attributed to be the stacking potential between the templating base and the incoming dNTP base.     

Evidence for a Watson-Crick hydrogen bonding requirement in DNA synthesis by human DNA polymerase kappa

The efficiency and fidelity of nucleotide incorporation by high-fidelity replicative DNA polymerases (Pols) are governed by the geometric constraints imposed upon the nascent base pair by the active site. Consequently, these polymerases can efficiently and accurately replicate through the template bases which are isosteric to natural DNA bases but which lack the ability to engage in Watson-Crick (W-C) hydrogen bonding. DNA synthesis by Poleta, a low-fidelity polymerase able to replicate through DNA lesions, however, is inhibited in the presence of such an analog, suggesting a dependence of this polymerase upon W-C hydrogen bonding. Here we examine whether human Polkappa, which differs from Poleta in having a higher fidelity and which, unlike Poleta, is inhibited at inserting nucleotides opposite DNA lesions, shows less of a dependence upon W-C hydrogen bonding than does Poleta. We find that an isosteric thymidine analog is replicated with low efficiency by Polkappa, whereas a nucleobase analog lacking minor-groove H bonding potential is replicated with high efficiency. These observations suggest that both Poleta and Polkappa rely on W-C hydrogen bonding for localizing the nascent base pair in the active site for the polymerization reaction to occur, thus overcoming these enzymes' low geometric selectivity.     

Mechanism of frameshift (deletion) generated by acetylaminofluorene-derived DNA adducts in vitro

We have investigated the mechanism of frameshift (deletion) mutagenesis induced by acetylaminofluorene- (AAF-) derived DNA adducts. dG-AAF-modified oligodeoxynucleotides, with different bases positioned 5' to the lesion, were annealed to (32)P-labeled 13-mer primers and then used in primer extension reactions catalyzed by the 3'-->5' exonuclease-free Klenow fragment of Escherichia coli DNA polymerase I. When the dNMP positioned opposite dG-AAF could pair with its complementary base at the 5' flanking position, single-base deletions were produced at high frequency. Similarly, when the complementary base was two positions 5' to the dG-AAF, two-base deletions occurred. The relative frequency of base insertions opposite dG-AAF followed the order dCMP > dAMP > dGMP > dTMP; the frequency of dNTP insertion opposite the lesion paralleled the formation of frameshift deletions. When a template designed to induce three-base deletions was used for translesion synthesis catalyzed by the exo(-) Klenow fragment, the expected three-base deletion was formed. When dG-AAF-modified templates containing iterated bases 5' to the lesion were annealed to primers with the complementary dNMP positioned opposite the lesion, the dNMP inserted opposite the dG-AAF tended to pair with the complementary base 5' to the lesion, thereby forming shorter deletions. Taken together, these results support the molecular mechanism for frameshift deletion proposed earlier by Shibutani and Grollman in which direct base insertion precedes misalignment [(1993) J. Biol. Chem. 268, 11703].     

7-Azido-Actinomycin D: A Photoaffinity Probe of the Sequence Specificity of DNA Binding by Actinomycin D

Abstract

Actinomycin D (ActD) is a DNA-binding antitumor antibiotic that appears to act in vivo by inhibiting RNA polymerase. The mechanism of DNA binding of ActD has attracted much attention because of its strong preference for 5′-dGpdC-3′ sequences. Binding is thought to involve intercalation of the tricyclic aromatic phenoxazone ring into a GC step, with the two equivalent cyclic pentapeptide lactone substituents lying in the minor groove and making hydrogen bond contacts with the 2-amino groups of the nearest neighbor guanines. Recent studies have indicated, however, that binding is also influenced by next-nearest neighboring bases. We have examined this higher order specificity using 7-azido-actinomycin-D as a photoaffinity probe, and DNA sequencing techniques to quantitatively monitor sites of covalent photoaddition. We found that GC doublets were strongly preferred only if the 5′- flanking base was a pyrimidine and the 3′-flanking base was not cytosine. In addition we observed a previously unreported preference for binding at a GG doublet in the sequence 5′- TGGG-3′.     

Frameshift mutagenesis of lambda prophage by 9-aminoacridine, proflavin and ICR-191

Summary The changes in DNA base sequence induced in the lambda cI gene in an E. coli lysogen have been determined following mutagenesis by three acridine derivatives: 9-aminoacridine and proflavin, which bind reversibly to DNA; and ICR-191, which attaches covalently to DNA through a half-mustard group. For all three derivatives, most mutations are +1 and-1 frameshifts in runs of adjacent G:C pairs. The specificity of mutagenesis at various sites is similar for all three compounds. Prophage in mutL host cells, deficient in mismatch repair, are much more susceptible to mutagenesis by 9-aminoacridine. The induced mutations are also frameshifts, and the site specificity is the same as in lysogens of wild type cells. Thus, additions or deletions of single bases can be corrected by the mismatch repair system, but mismatch repair does not play an important role in determining the sequence specificity of the mutational events.     

Synthesis of Modified RNA-Oligonucleotides for Structural Investigations

Abstract

RNA exhibits a higher structural diversity than DNA and is an important molecule in biology of life. It shows a number of secondary structures such as duplexes, hairpin loops, bulges, internal loops etc. However, in natural RNA, bases are limited to the four predominant structures U, C, A, and G and so the number of compounds that can be used for investigation of parameters of base stacking, base pairing and hydrogen bond, is limited. We synthesized different fluoromodifications of RNA building blocks: 1′-deoxy-1′-(2,4,6-trifluorophenyl)-ß-D-ribofuranose (F), 1′-deoxy-1′-(2,4,5-trifluorophenyl)-ß-D-ribofuranose (M) and 1′-deoxy-1′-(5-trifluoromethyl-1H-benzimidazol-1-yl)-ß-D-ribofuranose (D). Those amidites were incorporated and tested in a defined A, U- rich RNA sequence (12-mer, 5′-CUU UUC XUU CUU-3′ paired with 3′-GAA AAG YAA GAA-5’) (Schweitzer, B.A.; Kool, E.T. Aromatic nonpolar nucleosides as hydrophobic isosters of pyrimidine and purine nucleosides. J. Org. Chem. 1994, 59, 7238 pp.). Only one position was modified, marked as X and Y respectively. UV melting profiles of those oligonucleotides were measured.     

Intermolecular orientations of adenosine-5-monophosphate in aqueous solution as studied by fast fourier ytsndgotm 1H Nmr spectroscopy

Proton magnetic resonance spectra of 5′AMP were taken in the concentration range of 0.001–2.2M. The concentration profiles of all the nonexchangeable protons were determined. The data for 5′AMP was compared to those of adenine, adenosine, and poly(A). Theoretically computed isoshielding lines of the adenine moiety were used to qualitatively predict a preferred stacking geometry of 5′AMP in aqueous solution. It is concluded that 5′AMP at pH 8 forms multistacked aggregates at high concentration levels and that a preferred orientation is such that the bases are aligned face to back with considerable, though less than 100%, base overlap; and that the ribose moieties of adjacent molecules are near one another with the phosphate groups well separated. Mn(II) ion binding studies show that the stacks are not restricted to one unique orientation type. Specific evidence is given showing that base-stacking orientations in the solid state may in some cases be considerably different from that in aqueous solution, due in part to numerous hydrogen bonding differences, and this is shown to be the case for base-stacked adenosine. In the case of 5′AMP the stacking orientations between the solid and liquid states are also different, except in this comparison the solid-state structure carries a positive charge.     

The anti/syn conformation of 8-oxo-7,8-dihydro-2′-deoxyguanosine is modulated by Bacillus subtilis PolX active site residues His255 and Asn263. Efficient processing of damaged 3′-ends

8-oxo-7,8-dihydro-2′-deoxyguanosine (8oxodG) is a major lesion resulting from oxidative stress and found in both DNA and dNTP pools. Such a lesion is usually removed from DNA by the Base Excision Repair (BER), a universally conserved DNA repair pathway. 8oxodG usually adopts the favored and promutagenic syn-conformation at the active site of DNA polymerases, allowing the base to hydrogen bonding with adenine during DNA synthesis. Here, we study the structural determinants that affect the glycosidic torsion-angle of 8oxodGTP at the catalytic active site of the family X DNA polymerase from Bacillus subtilis (PolXBs). We show that, unlike most DNA polymerases, PolXBs exhibits a similar efficiency to stabilize the anti and syn conformation of 8oxodGTP at the catalytic site. Kinetic analyses indicate that at least two conserved residues of the nucleotide binding pocket play opposite roles in the anti/syn conformation selectivity, Asn263 and His255 that favor incorporation of 8oxodGMP opposite dA and dC, respectively. In addition, the presence in PolXBs of Mn²⁺-dependent 3′-phosphatase and 3′-phosphodiesterase activities is also shown. Those activities rely on the catalytic center of the C-terminal Polymerase and Histidinol Phosphatase (PHP) domain of PolXBs and, together with its 3′-5′ exonuclease activity allows the enzyme to resume gap-filling after processing of damaged 3′ termini.     

Sulfolobus solfataricus DNA polymerase Dpo4 is partially inhibited by "wobble" pairing between O6-methylguanine and cytosine, but accurate bypass is preferred

We examined the effect of a single O6-methylguanine (O6-MeG) template residue on catalysis by a model Y family polymerase, Dpo4 from Sulfolobus solfataricus. Mass spectral analysis of Dpo4-catalyzed extension products revealed that the enzyme accurately bypasses O6-MeG, with C being the major product (approximately 70%) and T or A being the minor species (approximately 20% or approximately 10%, respectively), consistent with steady-state kinetic parameters. Transient-state kinetic experiments revealed that kpol, the maximum forward rate constant describing polymerization, for dCTP incorporation opposite O6-MeG was approximately 6-fold slower than observed for unmodified G, and no measurable product was observed for dTTP incorporation in the pre-steady state. The lack of any structural information regarding how O6-MeG paired in a polymerase active site led us to perform x-ray crystallographic studies, which show that "wobble" pairing occurs between C and O6-MeG. A structure containing T opposite O6-MeG was solved, but much of the ribose and pyrimidine base density was disordered, in accordance with a much higher Km,dTTP that drives the difference in efficiency between C and T incorporation. The more stabilized C:O6-MeG pairing reinforces the importance of hydrogen bonding with respect to nucleotide selection within a geometrically tolerant polymerase active site.