Pre-steady-state kinetic studies of the fidelity and mechanism of polymerization catalyzed by truncated human DNA polymerase lambda

DNA polymerase lambda (Pollambda), a member of the X-family DNA polymerases, possesses an N-terminal BRCT domain, a proline-rich domain, and a C-terminal polymerase beta-like domain (tPollambda). In this paper, we determined a minimal kinetic mechanism and the fidelity of tPollambda using pre-steady-state kinetic analysis of the incorporation of a single nucleotide into a one-nucleotide gapped DNA substrate, 21-19/41-mer (primer-primer/template). Our kinetic studies revealed an incoming nucleotide bound to the enzyme.DNA binary complex at a rate constant of 1.55 x 10(8) M(-1) s(-1) to form a ground-state ternary complex while the nucleotide dissociated from this complex at a rate constant of 300 s(-1). Since DNA dissociation from tPollambda (0.8 s(-1)) was less than 3-fold slower than polymerization, we measured saturation kinetics for all 16 possible nucleotide incorporations under single turnover conditions to eliminate the complication resulting from multiple turnovers. The fidelity of tPollambda was estimated to be in the range of 10(-2)-10(-4) and was sequence-dependent. Surprisingly, the ground-state binding affinity of correct (1.1-2.4 microM) and incorrect nucleotides (1.4-8.4 microM) was very similar while correct nucleotides (3-6 s(-1)) were incorporated much faster than incorrect nucleotides (0.001-0.2 s(-1)). Interestingly, the misincorporation of dGTP opposite a template base thymine (0.2 s(-1)) was more rapid than all other misincorporations, leading to the lowest fidelity (3.2 x 10(-2)) among all mismatched base pairs. Additionally, tPollambda was found to possess weak strand-displacement activity during polymerization. These biochemical properties suggest that Pollambda likely fills short-patched DNA gaps in base excision repair pathways and participates in mammalian nonhomologous end-joining pathways to repair double-stranded DNA breaks.     

Distinct complexes of DNA polymerase I (Klenow fragment) for base and sugar discrimination during nucleotide substrate selection

During each catalytic cycle, DNA polymerases select deoxyribonucleoside triphosphate (dNTP) substrates complementary to a templating base with high fidelity from a pool that includes noncomplementary dNTPs and both complementary and noncomplementary ribonucleoside triphosphates (rNTPs). The Klenow fragment of Escherichia coli DNA polymerase I (KF) achieves this through a series of conformational transitions that precede the chemical step of phosphodiester bond formation. Kinetic evidence from fluorescence and FRET experiments indicates that discrimination of the base and sugar moieties of the incoming nucleotide occurs in distinct, sequential steps during the selection pathway. Here we show that KF-DNA complexes formed with complementary rNTPs or with noncomplementary nucleotides can be distinguished on the basis of their properties when captured in an electric field atop the α-hemolysin nanopore. The average nanopore dwell time of KF-DNA complexes increased as a function of complementary rNTP concentration. The increase was less than that promoted by complementary dNTP, indicating that the rNTP complexes are more stable than KF-DNA binary complexes but less stable than KF-DNA-dNTP ternary complexes. KF-DNA-rNTP complexes could also be distinguished from KF-DNA-dNTP complexes on the basis of ionic current amplitude. In contrast to complementary rNTPs, noncomplementary dNTPs and rNTPs diminished the average nanopore dwell time of KF-DNA complexes in a concentration-dependent manner, suggesting that binding of a noncomplementary nucleotide keeps the KF-DNA complex in a less stable state. These results imply that nucleotide selection proceeds through a series of complexes of increasing stability in which substrates with the correct moiety promote the forward transitions.     

Fidelity of DNA synthesis by the Thermococcus litoralis DNA polymerase--an extremely heat stable enzyme with proofreading activity

We demonstrate that the DNA polymerase isolated from Thermococcus litoralis (VentTM DNA polymerase) is the first thermostable DNA polymerase reported having a 3'----5' proofreading exonuclease activity. This facilitates a highly accurate DNA synthesis in vitro by the polymerase. Mutational frequencies observed in the base substitution fidelity assays were in the range of 30 x 10(-6). These values were 5-10 times lower compared to other thermostable DNA polymerases lacking the proofreading activity. All classes of DNA polymerase errors (transitions, transversions, frameshift mutations) were assayed using the forward mutational assay (1). The mutation frequencies of Thermococcus litoralis DNA polymerase varied between 15-35 x 10(-4) being 2-4 times lower than the respective values obtained using enzymes without proofreading activity. We also noticed that the fidelity of the DNA polymerase from Thermococcus litoralis responds to changes in dNTP concentration, units of enzyme used per one reaction and the concentration of MgSO4 relative to the total concentration of dNTPs present in the reaction. The high fidelity DNA synthesis in vitro by Thermococcus litoralis DNA polymerase provides good possibilities for maintaining the genetic information of original target DNA sequences intact in the DNA amplification applications.     

Mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase IV

The kinetic mechanism of DNA polymerization catalyzed by Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) is resolved by pre-steady-state kinetic analysis of single-nucleotide (dTTP) incorporation into a DNA 21/41-mer. Like replicative DNA polymerases, Dpo4 utilizes an "induced-fit" mechanism to select correct incoming nucleotides. The affinity of DNA and a matched incoming nucleotide for Dpo4 was measured to be 10.6 nM and 230 microM, respectively. Dpo4 binds DNA with an affinity similar to that of replicative polymerases due to the presence of an atypical little finger domain and a highly charged tether that links this novel domain to its small thumb domain. On the basis of the elemental effect between the incorporations of dTTP and its thio analogue S(p)-dTTPalphaS, the incorporation of a correct incoming nucleotide by Dpo4 was shown to be limited by the protein conformational change step preceding the chemistry step. In contrast, the chemistry step limited the incorporation of an incorrect nucleotide. The measured dissociation rates of the enzyme.DNA binary complex (0.02-0.07 s(-1)), the enzyme.DNA.dNTP ternary complex (0.41 s(-1)), and the ternary complex after the protein conformational change (0.004 s(-1)) are significantly different and support the existence of a bona fide protein conformational change step. The rate-limiting protein conformational change was further substantiated by the observation of different reaction amplitudes between pulse-quench and pulse-chase experiments. Additionally, the processivity of Dpo4 was calculated to be 16 at 37 degrees C from analysis of a processive polymerization experiment. The structural basis for both the protein conformational change and the low processivity of Dpo4 was discussed.     

Significance of nucleobase shape complementarity and hydrogen bonding in the formation and stability of the closed polymerase-DNA complex

DNA polymerases insert a dNTP by a multistep mechanism that involves a conformational rearrangement from an open to a closed ternary complex, a process that positions the incoming dNTP in the proper orientation for phosphodiester bond formation. In this work, the importance and relative contribution of hydrogen-bonding interactions and the geometric shape of the base pair that forms during this process were studied using Escherichia coli DNA polymerase I (Klenow fragment, 3'-exonuclease deficient) and natural dNTPs or non-hydrogen-bonding dNTP analogues. Both the geometric fit of the incoming nucleotide and its ability to form Watson-Crick hydrogen bonds with the template were found to contribute to the stability of the closed ternary complex. Although the formation of a closed complex in the presence of a non-hydrogen-bonding nucleotide analogue could be detected by limited proteolysis analysis, a comparison of the stabilities of the ternary complexes indicated that hydrogen-bonding interactions between the incoming dNTP and the template increase the stability of the complex by 6-20-fold. Any deviation from the Watson-Crick base pair geometry was shown to have a destabilizing effect on the closed complex. This degree of destabilization varied from 3- to 730-fold and was found to be correlated with the size of the mismatched base pair. Finally, a stable closed complex is not formed in the presence of a ddNTP or rNTP. These results are discussed in relation to the steric exclusion model for the nucleotide insertion.     

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.     

Altering DNA polymerase incorporation fidelity by distorting the dNTP binding pocket with a bulky carcinogen-damaged template

Fidelity of DNA polymerases is predominantly governed by an induced fit mechanism in which the incoming dNTP in the ternary complex fits tightly into a binding pocket whose geometry is determined by the nature of the templating base. However, modification of the template with a bulky carcinogen may alter the dNTP binding pocket and thereby the polymerase incorporation fidelity. High fidelity DNA polymerases, such as bacteriophage T7 DNA polymerase, are predominantly blocked by bulky chemical lesions on the template strand during DNA replication. However, some mutagenic bypass can occur, which may lead to carcinogenesis. Experimental studies have shown that a DNA covalent adduct derived from (+)-anti-BPDE [(+)-(7R,8S,9S,10R)-7,8-dihydroxy-9,10-epoxy-7,8,9,10-tetrahydrobenzo[a]pyrene], a carcinogenic metabolite of benzo[a]pyrene (BP), primarily blocks Sequenase 2.0, an exo(-) T7 DNA polymerase; however, a mismatched dATP can be preferentially inserted opposite the damaged adenine templating base within the active site of the polymerase [Chary, P., and Lloyd, R. S. (1995) Nucleic Acids Res. 23, 1398-1405]. The goal of this work is to elucidate structural features that contribute to DNA polymerase incorporation fidelity in the presence of this bulky covalent adduct and to interpret the experimental findings on a molecular level. We have carried out molecular modeling and molecular dynamics simulations with AMBER 6.0, investigating a T7 DNA polymerase primer-template closed ternary complex containing this 10S (+)-trans-anti-[BP]-N(6)-dA adduct in the templating position within the polymerase active site. All four incoming dNTPs were studied. The simulations show that the BP ring system fits well into an open pocket on the major groove side of the modified template adenine with anti glycosidic bond conformation, without disturbing critical polymerase-DNA interactions. However, steric hindrance between the BP ring system and the primer-template DNA causes displacement of the modified template adenine, so that the dNTP base binding pocket is enlarged. This alteration can explain the experimentally observed preference for incorporation of dATP opposite this lesion. These studies also rationalize the observed lower probabilities of incorporation of the other three nucleotides. Our results suggest that the differences in incorporation of dGTP, dCTP, and dTTP are due to the effects of imperfect geometric complementarity. Thus, the simulations suggest that altered DNA polymerase incorporation fidelity can result from adduct-induced changes in the dNTP base binding pocket geometry. Furthermore, plausible structural explanations for the observed effects of [BP]-N(6)-dA adduct stereochemistry on the observed stalling patterns are proposed.     

Mismatched and matched dNTP incorporation by DNA polymerase beta proceed via analogous kinetic pathways

While matched nucleotide incorporation by DNA polymerase beta (Pol beta) has been well-studied, a true understanding of polymerase fidelity requires comparison of both matched and mismatched dNTP incorporation pathways. Here we examine the mechanism of misincorporation for wild-type (WT) Pol beta and an error-prone I260Q variant using stopped-flow fluorescence assays and steady-state fluorescence spectroscopy. In stopped-flow, a biphasic fluorescence trace is observed for both enzymes during mismatched dNTP incorporation. The fluorescence transitions are in the same direction as that observed for matched dNTP, albeit with lower amplitude. Assignments of the fast and slow fluorescence phases are designated to the same mechanistic steps previously determined for matched dNTP incorporation. For both WT and I260Q mismatched dNTP incorporation, the rate of the fast phase, reflecting subdomain closing, is comparable to that induced by correct dNTP. Pre-steady-state kinetic evaluation reveals that both enzymes display similar correct dNTP insertion profiles, and the lower fidelity intrinsic to the I260Q mutant results from enhanced efficiency of mismatched incorporation. Notably, in comparison to WT, I260Q demonstrates enhanced intensity of fluorescence emission upon mismatched ternary complex formation. Both kinetic and steady-state fluorescence data suggest that relaxed discrimination against incorrect dNTP by I260Q is a consequence of a loss in ability to destabilize the mismatched ternary complex. Overall, our results provide first direct evidence that mismatched and matched dNTP incorporations proceed via analogous kinetic pathways, and support our standing hypothesis that the fidelity of Pol beta originates from destabilization of the mismatched closed ternary complex and chemical transition state.     

Escherichia coli DNA polymerase I (Klenow fragment) uses a hydrogen-bonding fork from Arg668 to the primer terminus and incoming deoxynucleotide triphosphate to catalyze DNA replication

Interactions between the minor groove of the DNA and DNA polymerases appear to play a major role in the catalysis and fidelity of DNA replication. In particular, Arg668 of Escherichia coli DNA polymerase I (Klenow fragment) makes a critical contact with the N-3-position of guanine at the primer terminus. We investigated the interaction between Arg668 and the ring oxygen of the incoming deoxynucleotide triphosphate (dNTP) using a combination of site-specific mutagenesis of the protein and atomic substitution of the DNA and dNTP. Hydrogen bonds from Arg668 were probed with the site-specific mutant R668A. Hydrogen bonds from the DNA were probed with oligodeoxynucleotides containing either guanine or 3-deazaguanine (3DG) at the primer terminus. Hydrogen bonds from the incoming dNTP were probed with (1 'R,3 'R,4 'R)-1-[3-hydroxy-4-(triphosphorylmethyl)cyclopent-1-yl]uracil (dcUTP), an analog of dUTP in which the ring oxygen of the deoxyribose moiety was replaced by a methylene group. We found that the pre-steady-state parameter kpol was decreased 1,600 to 2,000-fold with each of the single substitutions. When the substitutions were combined, there was no additional decrease (R668A and 3DG), a 5-fold decrease (3DG and dcUTP), and a 50-fold decrease (R668A and dcUTP) in kpol. These results are consistent with a hydrogen-bonding fork from Arg668 to the primer terminus and incoming dNTP. These interactions may play an important role in fidelity as well as catalysis of DNA replication.     

Mismatched dNTP incorporation by DNA polymerase beta does not proceed via globally different conformational pathways

Understanding how DNA polymerases control fidelity requires elucidation of the mechanisms of matched and mismatched dNTP incorporations. Little is known about the latter because mismatched complexes do not crystallize readily. In this report, we employed small-angle X-ray scattering (SAXS) and structural modeling to probe the conformations of different intermediate states of mammalian DNA polymerase β (Pol β) in its wild-type and an error-prone variant, I260Q. Our structural results indicate that the mismatched ternary complex lies in-between the open and the closed forms, but more closely resembles the open form for WT and the closed form for I260Q. On the basis of molecular modeling, this over-stabilization of mismatched ternary complex of I260Q is likely caused by formation of a hydrogen bonding network between the side chains of Gln²⁶⁰, Tyr²⁹⁶, Glu²⁹⁵ and Arg²⁵⁸, freeing up Asp¹⁹² to coordinate MgdNTP. These results argue against recent reports suggesting that mismatched dNTP incorporations follow a conformational path distinctly different from that of matched dNTP incorporation, or that its conformational closing is a major contributor to fidelity.     

Efficiency of correct nucleotide insertion governs DNA polymerase fidelity

DNA polymerase fidelity or specificity expresses the ability of a polymerase to select a correct nucleoside triphosphate (dNTP) from a pool of structurally similar molecules. Fidelity is quantified from the ratio of specificity constants (catalytic efficiencies) for alternate substrates (i.e. correct and incorrect dNTPs). An analysis of the efficiency of dNTP (correct and incorrect) insertion for a low fidelity mutant of DNA polymerase beta (R283A) and exonuclease-deficient DNA polymerases from five families derived from a variety of biological sources reveals that a strong correlation exists between the ability to synthesize DNA and the probability that the polymerase will make a mistake (i.e. base substitution error). Unexpectedly, this analysis indicates that the difference between low and high fidelity DNA polymerases is related to the efficiency of correct, but not incorrect, nucleotide insertion. In contrast to the loss of fidelity observed with the catalytically inefficient R283A mutant, the fidelity of another inefficient mutant of DNA polymerase beta (G274P) is not altered. Thus, although all natural low fidelity DNA polymerases are inefficient, not every inefficient DNA polymerase has low fidelity. Low fidelity polymerases appear to be an evolutionary solution to how to replicate damaged DNA or DNA repair intermediates without burdening the genome with excessive polymerase-initiated errors.     

噬菌体RB69 DNA聚合酶以不正确的核苷酸为底物的聚合反应的稳态动力学研究

测定了ＲＢ６９ ＤＮＡ 聚合酶以不正确的核苷酸（ｒＮＴＰ、ｄｄＮＴＰ以及碱基不配对的ｄＮＴＰ）为底物进行聚合反应的稳态动力学常数,并与Ｋｌｅｎｏｗ 酶进行了比较．结果表明,ＲＢ６９ ＤＮＡ 聚合酶在以不正确的核苷酸为底物进行聚合反应时,其Ｋｍ 值与正确底物参入时相比有大幅度提高,而ｋｃａｔ保持不变或下降幅度较小．而Ｋｌｅｎｏｗ 酶在利用不正确的核苷酸为底物时,与正确底物参入时相比,其ｋｃａｔ大幅度下降,而Ｋｍ （或ＫＤ）基本保持不变或上升较小幅度．两种酶不同的动力学特点反映出它们不同的底物选择机制．     

Pre-steady-state kinetic studies of the fidelity of Sulfolobus solfataricus P2 DNA polymerase IV

Sulfolobus solfataricus P2 DNA polymerase IV (Dpo4) is a thermostable archaeal enzyme and a member of the error-prone and lesion-bypass Y-family. In this paper, for the first time, the fidelity of a Y-family polymerase, Dpo4, was determined using pre-steady-state kinetic analysis of the incorporation of a single nucleotide into an undamaged DNA substrate 21/41-mer at 37 degrees C. We assessed single-turnover (with Dpo4 in molar excess over DNA) saturation kinetics for all 16 possible nucleotide incorporations. The fidelity of Dpo4 was estimated to be in the range of 10(-3)-10(-4). Interestingly, the ground-state binding affinity of correct nucleotides (70-230 microM) is 10-50-fold weaker than those of replicative DNA polymerases. Such a low affinity is consistent with the lack of interactions between Dpo4 and the bound nucleotides as revealed in the crystal structure of Dpo4, DNA, and a matched nucleotide. The affinity of incorrect nucleotides for Dpo4 is approximately 2-10-fold weaker than that of correct nucleotides. Intriguingly, the mismatched dCTP has an affinity similar to that of the matched nucleotides when it is incorporated against a pyrimidine template base flanked by a 5'-template guanine. The incoming dCTP likely skips the first available template base and base pairs with the 5'-template guanine, as observed in the crystal structure of Dpo4, DNA, and a mismatched nucleotide. The mismatch incorporation rates, regardless of the 5'-template base, were approximately 2-3 orders of magnitude slower than the incorporation rates for matched nucleotides, which is the predominant contribution to the fidelity of Dpo4.     

PCR fidelity of pfu DNA polymerase and other thermostable DNA polymerases.

The replication fidelities of Pfu, Taq, Vent, Deep Vent and UlTma DNA polymerases were compared using a PCR-based forward mutation assay. Average error rates (mutation frequency/bp/duplication) increased as follows: Pfu (1.3 x 10(-6)) < Deep Vent (2.7 x 10(-6)) < Vent (2.8 x 10(-6)) < Taq (8.0 x 10(-6)) < < exo- Pfu and UlTma (approximately 5 x 10(-5)). Buffer optimization experiments indicated that Pfu fidelity was highest in the presence of 2-3 mM MgSO4 and 100-300 microM each dNTP and at pH 8.5-9.1. Under these conditions, the error rate of exo- Pfu was approximately 40-fold higher (5 x 10(-5)) than the error rate of Pfu. As the reaction pH was raised from pH 8 to 9, the error rate of Pfu decreased approximately 2-fold, while the error rate of exo- Pfu increased approximately 9-fold. An increase in error rate with pH has also been noted for the exonuclease-deficient DNA polymerases Taq and exo- Klenow, suggesting that the parameters which influence replication error rates may be similar in pol l- and alpha-like polymerases. Finally, the fidelity of 'long PCR' DNA polymerase mixtures was examined. The error rates of a Taq/Pfu DNA polymerase mixture and a Klentaq/Pfu DNA polymerase mixture were found to be less than the error rate of Taq DNA polymerase, but approximately 3-4-fold higher than the error rate of Pfu DNA polymerase.     

A conserved Tyr residue is required for sugar selectivity in a Pol alpha DNA polymerase

Many DNA polymerases select their natural substrates, deoxy- as opposed to ribonucleoside triphosphates, with a selectivity greater than 10000-fold. The function of a highly conserved residue, Tyr416, in the palm domain of the parental enzyme, an exo(-) derivative of RB69 DNA polymerase (gp43), a member of the pol alpha DNA polymerase family, was examined for its role in helping the polymerase discriminate between ribo-, dideoxyribo-, and deoxyribonucleoside triphosphates. The parental enzyme selected dNTPs vs rNTPs with about the same preference as dNTPs vs ddNTPs. Pre-steady-state kinetic analysis was carried out with the parental enzyme and two mutants, Y416A and Y416F. The Y416A mutant incorporated ribonucleotide residues much more efficiently than the parental enzyme, whereas the Y416F mutant was more permissive toward ddNTP vs rNTP utilization than either the Y416A mutant or the parental enzyme. We also found that both dCDP and rCDP inhibited dCTP incorporation by the Y416A mutant, while only dCDP but not rCDP inhibited dCTP incorporation by the parental enzyme and the Y416F mutant. The parental enzyme and the Y416A and Y416F mutants were all able to add araCTP (1-beta-D-arabinofuranosylcytosine-5'-triphosphate) to a primer but with reduced efficiency relative to dCTP. Based on our kinetic results, interpreted in the context of the crystal structure of the RB69 gp43 ternary complex, we suggest that sugar discrimination is provided mainly by the Tyr416 side chain which can sterically block the 2'-OH group of an incoming rNTP.     

Highly Frequent Frameshift DNA Synthesis by Human DNA Polymerase μ

DNA polymerase mu (Polmu) is a newly identified member of the polymerase X family. The biological function of Polmu is not known, although it has been speculated that human Polmu may be a somatic hypermutation polymerase. To help understand the in vivo function of human Polmu, we have performed in vitro biochemical analyses of the purified polymerase. Unlike any other DNA polymerases studied thus far, human Polmu catalyzed frameshift DNA synthesis with an unprecedentedly high frequency. In the sequence contexts examined, -1 deletion occurred as the predominant DNA synthesis mechanism opposite the single-nucleotide repeat sequences AA, GG, TT, and CC in the template. Thus, the fidelity of DNA synthesis by human Polmu was largely dictated by the sequence context. Human Polmu was able to efficiently extend mismatched bases mainly by a frameshift synthesis mechanism. With the primer ends, containing up to four mismatches, examined, human Polmu effectively realigned the primer to achieve annealing with a microhomology region in the template several nucleotides downstream. As a result, human Polmu promoted microhomology search and microhomology pairing between the primer and the template strands of DNA. These results show that human Polmu is much more prone to cause frameshift mutations than base substitutions. The biochemical properties of human Polmu suggest a function in nonhomologous end joining and V(D)J recombination through its microhomology searching and pairing activities but do not support a function in somatic hypermutation.     

phi 29 DNA polymerase residue Leu384, highly conserved in motif B of eukaryotic type DNA replicases,is involved in nucleotide insertion fidelity

Replicative DNA polymerases achieve insertion fidelity by geometric selection of a complementary nucleotide followed by induced fit: movement of the fingers subdomain toward the active site to enclose the incoming and templating nucleotides generating a binding pocket for the nascent base pair. Several residues of motif B of DNA polymerases from families A and B, localized in the fingers subdomain, have been described to be involved in template/primer binding and dNTP selection. Here we complete the analysis of this motif, which has the consensus "KLX2NSXYG" in DNA polymerases from family B, characterized by mutational analysis of conserved leucine, Leu384 of phi 29 DNA polymerase. Mutation of Leu384 into Arg resulted in a phi 29 DNA polymerase with reduced nucleotide insertion fidelity during DNA-primed polymerization and protein-primed initiation reactions. However, the mutation did not alter the intrinsic affinity for the different dNTPs, as shown in the template-independent terminal protein-deoxynucleotidylation reaction. We conclude that Leu384 of phi 29 DNA polymerase plays an important role in positioning the templating nucleotide at the polymerization active site and in controlling nucleotide insertion fidelity. This agrees with the localization of the corresponding residue in the closed ternary complexes of family A and family B DNA polymerases, contributing to form the binding pocket for the nascent base pair. As an additional effect, mutant polymerase L384R was strongly reduced in DNA binding, resulting in reduced processivity during polymerization.