Base excision and DNA binding activities of human alkyladenine DNA glycosylase are sensitive to the base paired with a lesion.

The human alkyladenine DNA glycosylase has a broad substrate specificity, excising a structurally diverse group of damaged purines from DNA. To more clearly define the structural and mechanistic bases for substrate specificity of human alkyladenine DNA glycosylase, kinetics of excision and DNA binding activities were measured for several different damaged and undamaged purines within identical DNA sequence contexts. We found that 1,N(6)-ethenoadenine (epsilonA) and hypoxanthine (Hx) were excised relatively efficiently, whereas 7,8-dihydro-8-oxoguanine, O(6)-methylguanine, adenine, and guanine were not. Single-turnover kinetics of excision of Hx and epsilonA paired with T showed that excision of Hx was about four times faster than epsilonA, whereas binding assays showed that the binding affinity was about five times greater for epsilonA than for Hx. The opposing pyrimidine base had a significant effect on the kinetics of excision and DNA binding affinity of Hx but a small effect on those for epsilonA. Surprisingly, replacing a T with a U opposite Hx dramatically reduced the excision rate by a factor of 15 and increased the affinity by a factor of 7-8. The binding affinity of human alkyladenine DNA glycosylase to a DNA product containing an abasic site was similar to that for an Hx lesion.

Molecular mechanism and energetics of clamp assembly in Escherichia coli. The role of ATP hydrolysis when gamma complex loads beta on DNA.

Escherichia coli DNA polymerase III holoenzyme is a multisubunit composite containing the beta sliding clamp and clamp loading gamma complex. The gamma complex requires ATP to load beta onto DNA. A two-color fluorescence spectroscopic approach was utilized to study this system, wherein both assembly (red fluorescence; X-rhodamine labeled DNA anisotropy assay) and ATP hydrolysis (green fluorescence; phosphate binding protein assay) were simultaneously measured with millisecond timing resolution. The two temporally correlated stopped-flow signals revealed that a preassembled beta. gamma complex composite rapidly binds primer/template DNA in an ATP hydrolysis independent step. Once bound, two molecules of ATP are rapidly hydrolyzed (approximately 34 s(-1)). Following hydrolysis, gamma complex dissociates from the DNA ( approximately 22 s(-1)). Once dissociated, the next cycle of loading is severely compromised, resulting in steady-state ATP hydrolysis rates with a maximum of only approximately 3 s(-1). Two single-site beta dimer interface mutants were examined which had impaired steady-state rates of ATP hydrolysis. The pre-steady-state correlated kinetics of these mutants revealed a pattern essentially identical to wild type. The anisotropy data showed that these mutants decrease the steady-state rates of ATP hydrolysis by causing a buildup of "stuck" binary-ternary complexes on the primer/template DNA.

A model for Escherichia coli DNA polymerase III holoenzyme assembly at primer/template ends. DNA triggers a change in binding specificity of the gamma complex clamp loader.

The gamma complex of the Escherichia coli DNA polymerase III holoenzyme assembles the beta sliding clamp onto DNA in an ATP hydrolysis-driven reaction. Interactions between gamma complex and primer/template DNA are investigated using fluorescence depolarization to measure binding of gamma complex to different DNA substrates under steady-state and presteady-state conditions. Surprisingly, gamma complex has a much higher affinity for single-stranded DNA (K(d) in the nM range) than for a primed template (K(d) in the microM range) under steady-state conditions. However, when examined on a millisecond time scale, we find that gamma complex initially binds very rapidly and with high affinity to primer/template DNA but is converted subsequently to a much lower affinity DNA binding state. Presteady-state data reveals an effective dissociation constant of 1.5 nM for the initial binding of gamma complex to DNA and a dissociation constant of 5.7 microM for the low affinity DNA binding state. Experiments using nonhydrolyzable ATPgammaS show that ATP binding converts gamma complex from a low affinity "inactive" to high affinity "active" DNA binding state while ATP hydrolysis has the reverse effect, thus allowing cycling between active and inactive DNA binding forms at steady-state. We propose that a DNA-triggered switch between active and inactive states of gamma complex provides a two-tiered mechanism enabling gamma complex to recognize primed template sites and load beta, while preventing gamma complex from competing with DNA polymerase III core for binding a newly loaded beta.DNA complex.

Division of labor--sequential ATP hydrolysis drives assembly of a DNA polymerase sliding clamp around DNA.

The beta sliding clamp encircles DNA and enables processive replication of the Escherichia coli genome by DNA polymerase III holoenzyme. The clamp loader, gamma complex, assembles beta around DNA in an ATP-fueled reaction. Previous studies have shown that gamma complex opens the beta ring and also interacts with DNA on binding ATP. Here, a rapid kinetic analysis demonstrates that gamma complex hydrolyzes two ATP molecules sequentially when placing beta around DNA. The first ATP is hydrolyzed fast, at 25-30 s(-1), while the second ATP hydrolysis is limited to the steady-state rate of 2 s(-1). This step-wise reaction depends on both primed DNA and beta. DNA alone promotes rapid hydrolysis of two ATP molecules, while beta alone permits hydrolysis of only one ATP. These results suggest that beta inserts a slow step between the two ATP hydrolysis events in clamp assembly, during which the clamp loader may perform work on the clamp. Moreover, one ATP hydrolysis is sufficient for release of beta from the gamma complex. This implies that DNA-dependent hydrolysis of the other ATP is coupled to a separate function, perhaps involving work on DNA. A model is presented in which sequential ATP hydrolysis drives distinct events in the clamp-assembly pathway. We also discuss underlying principles of this step-wise mechanism that may apply to the workings of other ATP-fueled biological machines.

Pre-steady state analysis of the assembly of wild type and mutant circular clamps of Escherichia coli DNA polymerase III onto DNA.

The beta protein, a dimeric ring-shaped clamp essential for processive DNA replication by Escherichia coli DNA polymerase III holoenzyme, is assembled onto DNA by the gamma complex. This study examines the clamp loading pathway in real time, using pre-steady state fluorescent depolarization measurements to investigate the loading reaction and ATP requirements for the assembly of beta onto DNA. Two beta dimer interface mutants, L273A and L108A, and a nonhydrolyzable ATP analog, adenosine 5'-O-(3-thiotriphosphate) (ATPgammaS), have been used to show that ATP binding is required for gamma complex and beta to associate with DNA, but that a gamma complex-catalyzed ATP hydrolysis is required for gamma complex to release the beta.DNA complex and complete the reaction. In the presence of ATP and gamma complex, the beta mutants associate with DNA as efficiently as wild type beta. However, completion of the reaction is much slower with the beta mutants because of decreased ATP hydrolysis by the gamma complex, resulting in a much slower release of the mutants onto DNA. The effects of mutations in the dimer interface were similar to the effects of replacing ATP with ATPgammaS in reactions using wild type beta. Thus, the assembly of beta around DNA is coupled tightly to the ATPase activity of the gamma complex, and completion of the assembly process requires ATP hydrolysis for turnover of the catalytic clamp loader.

The proofreading pathway of bacteriophage T4 DNA polymerase.

The base analog, 2-aminopurine (2AP), was used as a fluorescent reporter of the biochemical steps in the proofreading pathway catalyzed by bacteriophage T4 DNA polymerase. "Mutator" DNA polymerases that are defective in different steps in the exonucleolytic proofreading pathway were studied so that transient changes in fluorescence intensity could be equated with specific reaction steps. The G255S- and D131N-DNA polymerases can hydrolyze DNA, the final step in the proofreading pathway, but the mutator phenotype indicates a defect in one or more steps that prepare the primer-terminus for the cleavage reaction. The hydrolysis-defective D112A/E114A-DNA polymerase was also examined. Fluorescent enzyme-DNA complexes were preformed in the absence of Mg2+, and then rapid mixing, stopped-flow techniques were used to determine the fate of the fluorescent complexes upon the addition of Mg2+. Comparisons of fluorescence intensity changes between the wild type and mutant DNA polymerases were used to model the exonucleolytic proofreading pathway. These studies are consistent with a proofreading pathway in which the protein loop structure that contains residue Gly255 functions in strand separation and transfer of the primer strand from the polymerase active center to form a preexonuclease complex. Residue Asp131 acts at a later step in formation of the preexonuclease complex.

Exonuclease-polymerase active site partitioning of primer-template DNA strands and equilibrium Mg2+ binding properties of bacteriophage T4 DNA polymerase.

The binding of bacteriophage T4 DNA polymerase (T4 pol) to primer-template DNA with 2-aminopurine (2AP) located at the primer terminus results in the formation of a hyperfluorescent 2AP state. Changes in this hyperfluorescent state were utilized to investigate the fractional concentration of primer-templates bound at the exonuclease and statically quenched polymerase sites. In the absence of Mg2+, a hydrophobic exonuclease site dominates over the polymerase site for possession of the primer terminus. The fractional concentration of primer termini in the exonuclease site was found to be 64 and 84% for correct (AP-T) and mismatched (AP-C) primer-templates, respectively. Exonuclease-deficient mutants, polymerase-switching mutants, and nucleoside triphosphates all shift this equilibrium toward the polymerase site. Synthesis of stereospecific hydrolysis resistant phosphorothioate 2AP-labeled DNA allowed Mg2+ ion binding titrations to be performed in the presence of bound DNA without the complication of the excision reaction. High- and low-affinity Mg2+ binding sites were observed in the presence of bound double-stranded (ds) DNA, with dissociation constants in the micromolar (WT Kd = 5.1 microM) and millimolar (WT Kd = 2.5 mM) concentration ranges. Mg2+ binding was found to be a key "conformational switch" for T4 pol. As the high-affinity Mg2+ binding sites are filled, the primer terminus migrates from the exonuclease site to a highly based stacked polymerase active site. Filling the low-affinity Mg2+ sites further shifts the primer terminus into the polymerase site. As the low-affinity Mg2+ sites are filled, T4 pol "loosens its grip" on the primer terminus, as shown by a large amplitude increase in the nanosecond rotational mobility of 2AP within the bound T4 complex. The hyperfluorescent exonuclease site is spatially localized to 2AP positioned on the primer end. The penultimate (n - 1) position, as well as n - 2 and n - 5 positions, reveals no detectable fluorescent enhancement upon binding. The observed position-dependent fluorescence data, when combined with time-resolved total-intensity and anisotropy data, suggest that the creation of the hyperfluorescent state is caused by phenylalanine 120 (F120) of T4 pol intercalating into 2AP primers much like that observed for phenylalanine 123 of RB69 DNA polymerase intercalating into deoxythymidine primers [Wang, J., et al. (1997) Cell 89, 1087-1099]. As Mg2+ binds in the exonuclease site of T4 pol, the primer terminus appears to be "pulled backward" into the active site, decreasing the concentration of F120-intercalated primer termini, and bringing the exonuclease active site residues closer to the primer terminus scissile phosphate bond.

Stopped-flow fluorescence study of precatalytic primer strand base-unstacking transitions in the exonuclease cleft of bacteriophage T4 DNA polymerase.

DNA polymerases are complex enzymes which bind primer-template DNA and subsequently either extend or excise the terminal nucleotide on the primer strand. In this study, a stopped-flow fluorescence anisotropy binding assay is combined with real-time measurements of a fluorescent adenine analogue (2-aminopurine) located at the 3'-primer terminus. Using this combined approach, the exact time course associated with protein binding, primer terminus unstacking, and base excision by the 3' --> 5' exonuclease of bacteriophage T4 (T4 pol) was examined. T4 pol binding and dissociation kinetics were found to obey simple kinetics, with identical on rates (kon = 4.6 x 10(8) M-1 s-1) and off rates (koff = 9.3 s-1) for both single-stranded primers and double-stranded primer-templates (at 100 microM Mg2+). Although the time course for T4 pol-DNA association and dissociation obeyed simple kinetics, at suboptimal Mg2+ concentrations (e.g., 100 microM), non-first-order sigmoidal kinetics were observed for the base-unstacking reaction of the primer terminus in double-stranded primer-templates. The observed sigmoidal kinetics for base unstacking demonstrate that T4 pol is a hysteretic enzyme [Frieden, C. (1970) J. Biol. Chem. 245, 5788-5799] and must exist in two DNA bound conformations which differ greatly in base-unstacking properties. A Mg2+-dependent time lag of 10 ms is observed between primer-template binding and the beginning of the unstacking transition, which is 50% complete at 22 +/- 1 ms after addition of 100 microM Mg2+. Following the hysteretic lag, a simple first-order primer terminus unstacking rate of 130 s-1 is resolved, which is protein and Mg2+ concentration-independent. For the processing of single-stranded primers, all kinetic complexity is lost, and T4 pol binding and primer end base-unstacking kinetics can be superimposed. These data reveal that the kinetic processing of double-stranded primer-template DNA by T4 pol is much more complex than that of single-stranded primers, and suggest that the intrinsic "switching rate" between the polymerase and exonuclease sites may be much faster than previously proposed.

Fidelity of Escherichia coli DNA polymerase III holoenzyme. The effects of beta, gamma complex processivity proteins and epsilon proofreading exonuclease on nucleotide misincorporation efficiencies.

The fidelity of Escherichia coli DNA polymerase III (pol III) is measured and the effects of beta, gamma processivity and epsilon proofreading subunits are evaluated using a gel kinetic assay. Pol III holoenzyme synthesizes DNA with extremely high fidelity, misincorporating dTMP, dAMP, and dGMP opposite a template G target with efficiencies finc = 5.6 x 10(-6), 4.2 x 10(-7), and 7 x 10(-7), respectively. Elevated dGMP.G and dTMP.G misincorporation efficiencies of 3.2 x 10(-5) and 5.8 x 10(-4), attributed to a "dNTP-stabilized" DNA misalignment mechanism, occur when C and A, respectively, are located one base downstream from the template target G. At least 92% of misinserted nucleotides are excised by pol III holoenzyme in the absence of a next correct "rescue" nucleotide. As rescue dNTP concentrations are increased, pol III holoenzyme suffers a maximum 8-fold reduction in fidelity as proofreading of mispaired primer termini are reduced in competition with incorporation of a next correct nucleotide. Compared with pol III holoenzyme, the alpha holoenzyme, which cannot proofread, has 47-, 32-, and 13-fold higher misincorporation rates for dGMP.G, dTMP.G, and dAMP.G mispairs. Both the beta, gamma complex and the downstream nucleotide have little effect on the fidelity of catalytic alpha subunit. An analysis of the gel kinetic fidelity assay when multiple polymerase-DNA encounters occur is presented in the "Appendix" (see Fygenson, D. K., and Goodman, M. F. (1997) J. Biol. Chem. 272, 27931-27935 (accompanying paper)).

Dynamics of loading the beta sliding clamp of DNA polymerase III onto DNA.

A "minimal" DNA primer-template system, consisting of an 80-mer template and 30-mer primer, supports processive DNA synthesis by DNA polymerase III core in the presence of the beta sliding clamp, gamma complex clamp loader, and single-stranded binding protein from Escherichia coli. This primer-template system was used to measure the loading of the beta sliding clamp by the gamma complex in an ATP-dependent reaction. Bound protein-DNA complexes were detected by monitoring fluorescence depolarization of DNA. Steady state and time-resolved anisotropies were measured, and stopped-flow pre-steady state fluorescence measurements allowed visualization of the loading reactions in real time. The rate of loading beta onto DNA was 12 s-1, demonstrating that clamp assembly is rapid on the time scale required for lagging strand Okazaki fragment synthesis. The association rate appears to be limited by an intramolecular step occurring prior to the clamp-loading reaction, possibly the opening of the toroidal beta dimer.

Base analog and neighboring base effects on substrate specificity of recombinant human G:T mismatch-specific thymine DNA-glycosylase.

We studied the substrate specificity of the human G:T mismatch-specific thymine glycosylase that initiates the repair of G:T and G:U base mismatches to G:C base pairs. Such mismatches arise when 5-methylcytosine or cytosine deaminate spontaneously (and hydrolytically) in DNA. Substrates were 45-bp DNA heteroduplexes that bore single G:T, m6G:T, 2,6-diaminopurine:T, 2-amino-6-(methylamino)-purine:T, 2-aminopurine:T, and G:m4T mispairs. The bases 5' to the poorly matched G were altered in selected G:T substrates to yield mispairs in four different contexts, ApG, CpG, GpG, and TpG. The recombinant thymine glycosylase was incubated with the 45-bp DNA substrates, each labeled at the 5'-terminus of the strand containing the mismatched T. The DNAs were then treated with 0.1 N NaOH to catalyze phosphodiester bond breakage at the newly-generated AP sites, and the products were analyzed on DNA sequencing gels. As indicated by the amounts of the 20-nt incision product, the removal of the thymine base by the enzyme increased linearly between 0 and 40 min at which time the generation of product from all substrates ceased, probably because of enzyme inactivation. The rate of incision was greatest (0.7 fmol/min) with DNA containing the G:T mispair followed by the DNA containing the m6G:T mispair (0.38 fmol/min) and the DNA with the 2-amino-6-(methylamino)purine:T mispair (0.15 fmol/ min); the extent of reaction was 90%, 40%, and 20% respectively. By contrast to previous findings with cell-free extracts, DNA substrates containing 2,6-diaminopurine:T, 2-aminopurine:T, and G:m4T mispairs were not incised (< 2%). The amount of incision of the 45-bp DNA substrates containing G:T mispairs in the CpG context was 3-12-fold greater than in the TpG, GpG, and ApG contexts.

Nucleotide insertion and primer extension at abasic template sites in different sequence contexts.

Efficiencies of insertion and extension at a single site-directed abasic lesion, X, were measured while varying 5'- and 3'-template bases adjacent to X. The preference for insertion was found to be A > G > T approximately C, with the "upstream" (3'-neighboring) template base perturbing insertion efficiencies by an order of magnitude or more. Efficiencies of synthesis past the abasic lesion depended strongly on the "downstream" (5'-neighboring) template base and on the properties of the polymerase. HIV-1 RT favored "direct" extension of X.A > X.G > X.T > X.C, by addition of the next correct nucleotide. However, it was found that X.C, least favored for direct extension, was most favored for "misalignment" extension, occurring when the DNA structure in the vicinity of the lesion collapsed to realign a primer 3'-C terminus opposite a downstream template G site. Polymerase properties have an important role in copying abasic lesions. Drosophila DNA polymerase alpha, HIV-1, and AMV reverse transcriptases had "little" difficulty inserting opposite abasic lesions, with efficiencies comparable to misinsertions opposite normal template bases. However, AMV RT did not extent past the lesion using direct or misalignment mechanisms. Wild-type and mutant T4 DNA polymerases were used to show that although exonucleolytic proofreading inhibits lesion bypass, the presence of a highly active proofreading exonuclease is not sufficient to prevent bypass.

Pre-steady-state kinetic analysis of sequence-dependent nucleotide excision by the 3'-exonuclease activity of bacteriophage T4 DNA polymerase.

The effects of local DNA sequence on the proofreading efficiency of wild-type T4 DNA polymerase were examined by measuring the kinetics of removal of the fluorescent nucleotide analog 2-aminopurine deoxynucleoside monophosphate (dAPMP) from primer/templates of defined sequences. The effects of (1) interactions with the 5'-neighboring bases, (2) base pair stability, and (3) G.C content of the surrounding sequences on the pre-steady-state kinetics of dAPMP excision were measured. Rates of excision dAPMP from a primer 3'-terminus located opposite a template T (AP.T base pair) increased, over a 3-fold range, with the 5'-neighbor to AP in the order C < G < T < A. Rates of removal of dAPMP from AP.X base pairs located in the same surrounding sequence increased as AP.T < AP.A < AP.C < AP.G, which correlates with the decrease in the stabilities of these base pairs predicted by Tm measurements. A key finding was that AP was excised at a slower rate when mispaired opposite C located next to four G.C base pairs than when correctly paired opposite T next to four A.T base pairs, suggesting that exonuclease mismatch removal specificities may be enhanced to a much greater extent by instabilities of local primer termini than by specific recognition of incorrect base pairs. In polymerase-initiated reactions, biphasic reaction kinetics were observed for the excision of AP within most but not all sequence contexts. Rates of the rapid phases (30-40 s-1) were relatively insensitive to sequence context. Rapid-phase rates reflect the rate constants for exonucleolytic excision of dAPMP from melted primer termini for both correct and incorrect base pairs and were roughly comparable to rates of removal of dAPMP from single-stranded DNA (65-80 s-1). Rates of the slow phases (3-13 s-1) were dependent on sequence context; the slow phase may reflect the rate of switching from the polymerase to the exonuclease active site, or perhaps the conversion of a primer/template terminus from an annealed to a melted state in the exonuclease active site. These data, using wild-type T4 DNA polymerase and two exonuclease-deficient T4 polymerases, support a model in which exonuclease excision occurs on melted primer 3'-termini for both mismatched and correctly matched primer termini, and where specificity favoring removal of terminally mismatched base pairs is determined by the much larger fraction of melted-out primer 3'-termini for mispairs compared to that for correct pairs.

Kinetics of deoxyribonucleotide insertion and extension at abasic template lesions in different sequence contexts using HIV-1 reverse transcriptase.

Deoxyribonucleotide insertion efficiencies were measured opposite site-directed abasic template lesions using human immunodeficiency virus 1 reverse transcriptase (HIV-1RT), and the efficiencies to continue primer synthesis beyond the lesion, by addition of the "next correct" deoxynucleotide, were measured as a function of sequence context. Insertion of purines was favored over pyrimidines, A > G > T approximately C. Primer extension past the lesion occurred by two distinct mechanisms, either by direct or by misalignment extension. An "A-rule" appeared to hold for the case of direct extension, where the abasic template moiety is intrahelical, aligned opposite the primer 3'-terminus. In misalignment extension, the primer terminus is realigned from a site directly opposite the lesion to a new position opposite a neighboring template base 5' to the lesion. Direct extension efficiencies were measured in 16 different configurations, by varying 4 bases at the primer 3'-termini and 4 at the 5'-side (downstream) of the lesion. The predominant order of direct extension was A > G > T approximately C, similar to that observed for insertion. Reduced primer extension rates were not caused by a reduction in HIV-1 RT-DNA binding. Primers terminating in C showed inefficient direct extension, but were readily extended via misaligned configurations. The ratios of direct-to-misalignment extension efficiencies were 27:1, 2.5:1, and 1:25 for A, G, and C opposite the lesion, respectively. For the case of primers terminating in T, misalignment extension was not observed. A striking result was that while primers were extended past an abasic lesion by HIV-1 RT in both direct and misalignment modes, avian myeloblastosis virus RT failed to catalyze significant extension by either mode.

Influence of 5'-nearest neighbors on the insertion kinetics of the fluorescent nucleotide analog 2-aminopurine by Klenow fragment.

The effects of nearest neighbor interactions between a nucleotide base at the primer 3'-terminus and an incoming deoxyribonucleoside triphosphate on DNA polymerase catalyzed insertion were examined. Kinetics of inserting the fluorescent nucleotide analog 2-aminopurine deoxyribonucleotide (dAPMP) and dAMP opposite a template T by 3'-->5' exonuclease-deficient mutants of Klenow fragment (KF-) were measured on primer/templates of identical sequence except for the base pair at the 3'-primer terminus. In addition to its fluorescence properties, 2-aminopurine (AP) is an attractive probe because it is misinserted opposite T by polymerases at much higher frequencies than natural nucleotides. Misinsertion frequencies for AP are on the same order of magnitude as variations in misinsertion frequencies due to changes in local DNA sequence, which makes the statistical significance of these variations easier to document. We have established that changes in the fluorescence of AP can be used to follow the insertion of dAPMP on both steady-state and pre-steady-state time scales. Rates of insertion of dAPMP measured by fluorescence and by a polyacrylamide gel assay were similar and are sensitive to the identity of the base at the 3'-primer twice as fast as insertion following a primer terminus T. The difference in rates arises primarily from differences in kcat values, which were fastest next to G and slowest next to T, while apparent Km values were similar next to each of the 4 different nearest neighbors. The gel assay was used to measure AP misinsertion efficiencies by two methods: (1) by having dAPTP and dATP directly compete for insertion opposite T in the same reaction and (2) by measuring Vmax/Km values for each substrate in separate reactions. The results from the direct competition and separate kinetics measurements are similar. The misinsertion efficiency of dAPMP relative to dAMP opposite a template T was significantly higher next to a 3'-primer terminus G (f(ins) = 0.31 +/- 0.06) than next to T (f(ins) = 0.15 +/- 0.03) for the KF- single mutant (D42A). The corresponding misinsertion efficiencies next to a 3'-primer terminus G and T were 0.20 +/- 0.02 and 0.16, respectively, for the KF- double mutant (D355A, E357A). Relative rates of insertion of dAPMP and dAMP correlate with melting temperatures calculated for nearest neighbor doublets which reflect the relative base-stacking energies. In addition to changes in insertion kinetics, polymerase-DNA dissociation rates varied with the identity of the 3'-primer terminus, differing by as much as 7-20-fold depending on the polymerase and the primer/template.

Effect of a template-located 2',2'-difluorodeoxycytidine on the kinetics and fidelity of base insertion by Klenow (3'-->5'exonuclease-) fragment.

Gemcitabine [2',2'-difluorodeoxycytidine (dFdCyd)], a potent antitumor agent, inhibits DNA synthesis and is incorporated internally into DNA. The effect of a template-incorporated dFdCyd molecule (dFdCyd-) on DNA polymerase function was examined. Two 25-base deoxyoligonucleotides were synthesized with either a single dFdCyd- or template-incorporated deoxycytidine molecule (dCyd-) at the same position. Each was annealed separately to an identical complementary 5'-32P-labeled primer and extended by the Klenow fragment (3'-->5' exo-) of DNA polymerase I. "Correct" insertion of dGMP was 80-fold less efficient opposite dFdCyd- than dCyd-. A comparison of misinsertion efficiencies opposite template dFdCyd gave values of 2.7 x 10(-2) for dAMP insertion, 1.1 x 10(-3) for dTMP insertion, and 5.9 x 10(-4) for dCMP insertion. A similar measurement opposite template dC gave values of 1.8 x 10(-4), 1.7 x 10(-4), and 2.9 x 10(-6) for dAMP, dTMP, and dCMP insertion, respectively. Thus, the presence of dFdCyd on the template strand inhibited "normal" DNA synthesis and increased deoxyribonucleotide misinsertion frequencies. Pausing during DNA synthesis occurred directly opposite template dFdCyd suggesting that dFdC.dG base pairs might be less stable than normal dC.dG pairs, resulting in a decreased rate of primer extension beyond this site. Consistent with kinetic data, thermal denaturation measurements using comparable surrounding sequences showed that dFdC.dG "correct" pairs were less stable than dC.dG base pairs. Measurements on base mispairs showed that dFdC.dC was more stable than dC.dC, while no measurable Tm differences were found between polymers containing dFdC.dA and dC.dA or dFdC.dT, and dC.dT.

Ionization of bromouracil and fluorouracil stimulates base mispairing frequencies with guanine.

To test whether ionized base pairs influence polymerase-catalyzed misinsertion rates, we measured the efficiency of forming 5-bromouracil (B), 5-fluorouracil (F), and thymine base pairs with guanine and adenine as a function of pH using avian myeloblastosis reverse transcriptase. When B, F, and T were present as dNTP substrates, misincorporation efficiencies opposite G, normalized to incorporation of C opposite G, increased by about 20-, 13-, and 7-fold, respectively, as reaction pH increased from 7.0 to 9.5. Incorporation efficiencies to form the correct base pairs, B.A and F.A, normalized to T.A, decreased by 4- and 8-fold, respectively, with increasing pH. The effects of pH on misincorporation efficiencies were about 10-fold greater when B, F, and T were present as template bases. The relative misincorporation efficiencies of G opposite template B, F, and T, normalized to incorporation of A opposite B, F, and T, increased by about 430-, 370-, and 70-fold, respectively, as pH was increased from 6.5 to 9.5, while correct incorporation of A opposite template B and F decreased about 10-fold over the same pH range. Plots depicting incorrect and correct incorporation efficiencies versus pH were fit to a pH titration equation giving the fraction of ionized base as a function of pH. We conclude that avian myeloblastosis reverse transcriptase forms B.G and F.G mispairs in an ionized Watson-Crick conformation in preference to a neutral wobble structure containing favored keto tautomers of B or F. Although participation of disfavored enol tautomers in enzyme-catalyzed base mispair formation cannot be ruled out, the results are inconsistent with the "standard" disfavored tautomer model of mutagenesis. Instead, the data support a model in which ionization of halouracil bases is primarily responsible for B- and F-induced mutagenesis.

Biochemical basis of DNA replication fidelity.

DNA polymerase is the critical enzyme maintaining genetic integrity during DNA replication. Individual steps in the replication process that contribute to DNA synthesis fidelity include nucleotide insertion, exonucleolytic proofreading, and binding to and elongation of matched and mismatched primer termini. Each process has been investigated using polyacrylamide gel electrophoresis (PAGE) to resolve 32P-labeled primer molecules extended by polymerase. We describe how integrated gel band intensities can be used to obtain site-specific velocities for addition of correct and incorrect nucleotides, extending mismatched compared to correctly matched primer termini and measuring polymerase dissociation rates and equilibrium DNA binding constants. The analysis is based on steady-state "single completed hit conditions", where polymerases encounter many DNA molecules but where each DNA encounters an enzyme at most once. Specific topics addressed include nucleotide misinsertion, mismatch extension, exonucleolytic proofreading, single nucleotide discrimination using PCR, promiscuous mismatch extension by HIV-1 and AMV reverse transcriptases, sequence context effects on fidelity and polymerase dissociation, structural and kinetic properties of mispairs relating to fidelity, error avoidance mechanisms, kinetics of copying template lesions, the "A-rule" for insertion at abasic template lesions, an interesting exception to the "A-rule", thermodynamic and kinetic determinants of base pair discrimination by polymerases.