Structural insights into the generation of single-base deletions by the Y family DNA polymerase dbh

Structural basis of multitasking by the apicoplast DNA polymerase from Plasmodium falciparum

Plasmodium falciparum is a unicellular eukaryotic pathogen responsible for the majority of malaria-related fatalities. Plasmodium belongs to the phylum Apicomplexa and like most members of this phylum, contains a non-photosynthetic plastid called the apicoplast. The apicoplast has its own genome, which is replicated by a dedicated apicoplast replisome. Unlike other cellular replisomes, the apicoplast replisome uses a single DNA polymerase (apPol) for copying the apicoplast DNA. Being the only DNA polymerase in the apicoplast, apPol is expected to multitask, catalysing both replicative and lesion bypass synthesis. Replicative synthesis typically relies on a restrictive active site for high accuracy while lesion bypass requires an open active site. This raises the question how does apPol combine the structural features of multiple DNA polymerases in a single protein. Using single particle electron cryomicroscopy (cryoEM), we have solved the structures of apPol bound to its DNA and nucleotide substrates in five pre-chemistry conformational states, allowing us to describe the events leading up to nucleotide incorporation and answer how apPol incorporates features of multiple polymerases. We found that, unlike most replicative polymerases, apPol can accommodate a nascent base pair with the fingers in an open configuration, which might facilitate the lesion bypass activity. In the fingers open state we identified a nascent base pair checkpoint that can preferentially select a Watson-Crick base pair, an essential requirement for replicative synthesis. Taken together these structural features explain how apPol may balance replicative and lesion bypass synthesis.

Dynamics and thermal stability of the bypass polymerase, DinB homolog (Dbh)

The DinB homolog polymerase (Dbh) is a member of the Y-family of translesion DNA polymerases that can synthesize using a damaged DNA template. Since Dbh comes from the thermophilic archaeon Sulfolobus acidocaldarius, it is capable of functioning over a wide range of temperatures. Existing X-ray structures were determined at temperatures where the protein is least active. Here we use NMR and circular dichroism to understand how the structure and dynamics of Dbh are affected by temperature (2°C-65°C) and metal ion binding in solution. We measured hydrogen exchange protection factors, temperature coefficients, and chemical shift perturbations with and without magnesium and manganese. We report on regions of the protein that become more dynamic as the temperature is increased toward the functional temperature. Hydrogen exchange protection factors and temperature coefficients reveal that both the thumb and finger domains are very dynamic relative to the palm and little-finger (LF) domains. These trends remain true at high temperature with dynamics increasing as temperatures increase from 35°C to 50°C. Notably, NMR spectra show that the Dbh tertiary structure cold denatures beginning at 25°C and increases in denaturation as the temperature is lowered to 5°C with little change observed by CD. Above 35°C, chemical shift perturbation analysis in the presence and absence of magnesium and manganese reveals three ion binding sites, without DNA bound. In contrast, these bound metals are not apparent in any Dbh crystal structures of the protein without DNA. Two ion binding sites are confirmed to be near the active site, as reported in other Y-family polymerases, and we report a novel ion binding site in the LF domain. Thus, the solution-state structure of the Dbh polymerase is distinct from that of the solid-state structures and shows an unusually high cold denaturation temperature.

Structure and function of extreme TLS DNA polymerase TTEDbh from Thermoanaerobacter tengcongensis

Translesion synthesis (TLS) is a kind of DNA repair that maintains the stability of the genome and ensures the normal growth of life in cells under emergencies. Y-family DNA polymerases, as a kind of error-prone DNA polymerase, mainly perform TLS. Previous studies have suggested that the occurrence of tumors is associated with the overexpression of human DNA polymerase of the Y family. And the combination of Y-family DNA polymerase inhibitors is promising for cancer therapy. Here we report the functional and structural characterization of a member of the Y-family DNA polymerases, TTEDbh. We determine TTEDbh is an extreme TLS polymerase that can cross oxidative damage sites, and further identify the amino acids and novel structures that are critical for DNA binding, synthesis, fidelity, and oxidative damage bypass. Moreover, previously unnoticed structural elements with important functions have been discovered and analyzed. These studies provide a more experimental basis for further elucidating the molecular mechanisms of DNA polymerase in the Y family. It could also shed light on the design of drugs to target tumors.

Mechanism Underlying the Bypass of Apurinic/Pyrimidinic Site Analogs by Sulfolobus acidocaldarius DNA Polymerase IV

The spontaneous depurination of genomic DNA occurs frequently and generates apurinic/pyrimidinic (AP) site damage that is mutagenic or lethal to cells. Error-prone DNA polymerases are specifically responsible for the translesion synthesis (TLS) of specific DNA damage, such as AP site damage, generally with relatively low fidelity. The Y-family DNA polymerases are the main error-prone DNA polymerases, and they employ three mechanisms to perform TLS, including template-skipping, dNTP-stabilized misalignment, and misincorporation-misalignment. The bypass mechanism of the dinB homolog (Dbh), an archaeal Y-family DNA polymerase from Sulfolobus acidocaldarius, is unclear and needs to be confirmed. In this study, we show that the Dbh primarily uses template skipping accompanied by dNTP-stabilized misalignment to bypass AP site analogs, and the incorporation of the first nucleotide across the AP site is the most difficult. Furthermore, based on the reported crystal structures, we confirmed that three conserved residues (Y249, R333, and I295) in the little finger (LF) domain and residue K78 in the palm subdomain of the catalytic core domain are very important for TLS. These results deepen our understanding of how archaeal Y-family DNA polymerases deal with intracellular AP site damage and provide a biochemical basis for elucidating the intracellular function of these polymerases.

Heterotrimeric PCNA increases the activity and fidelity of Dbh, a Y-family translesion DNA polymerase prone to creating single-base deletion mutations

Dbh is a Y-family translesion DNA polymerase from Sulfolobus acidocaldarius, an archaeal species that grows in harsh environmental conditions. Biochemically, Dbh displays a distinctive mutational profile, creating single-base deletion mutations at extraordinarily high frequencies (up to 50 %) in specific repeat sequences. In cells, however, Dbh does not appear to contribute significantly to spontaneous frameshifts in these same sequence contexts. This suggests that either the error-prone DNA synthesis activity of Dbh is reduced in vivo and/or Dbh is restricted from replicating these sequences. Here, we test the hypothesis that the propensity for Dbh to make single base deletion mutations is reduced through interaction with the S. acidocaldarius heterotrimeric sliding clamp processivity factor, PCNA-123. We first confirm that Dbh physically interacts with PCNA-123, with the interaction requiring both the PCNA-1 subunit and the C-terminal 10 amino acids of Dbh, which contain a predicted PCNA-interaction peptide (PIP) motif. This interaction stimulates the polymerase activity of Dbh, even on short, linear primer-template DNA, by increasing the rate of nucleotide incorporation. This stimulation requires an intact PCNA-123 heterotrimer and a DNA duplex length of at least 18 basepairs, the minimal length predicted from structural data to bind to both the polymerase and the clamp. Finally, we find that PCNA-123 increases the fidelity of Dbh on a single-base deletion hotspot sequence 3-fold by promoting an increase in the rate of correct, but not incorrect, nucleotide addition and propose that PCNA-123 induces Dbh to adopt a more active conformation that is less prone to creating deletions during DNA synthesis.

Translesion and Repair DNA Polymerases: Diverse Structure and Mechanism

The number of DNA polymerases identified in each organism has mushroomed in the past two decades. Most newly found DNA polymerases specialize in translesion synthesis and DNA repair instead of replication. Although intrinsic error rates are higher for translesion and repair polymerases than for replicative polymerases, the specialized polymerases increase genome stability and reduce tumorigenesis. Reflecting the numerous types of DNA lesions and variations of broken DNA ends, translesion and repair polymerases differ in structure, mechanism, and function. Here, we review the unique and general features of polymerases specialized in lesion bypass, as well as in gap-filling and end-joining synthesis.

DNA binding strength increases the processivity and activity of a Y-Family DNA polymerase

DNA polymerase (pol) processivity, i.e., the bases a polymerase extends before falling off the DNA, and activity are important for copying difficult DNA sequences, including simple repeats. Y-family pols would be appealing for copying difficult DNA and incorporating non-natural dNTPs, due to their low fidelity and loose active site, but are limited by poor processivity and activity. In this study, the binding between Dbh and DNA was investigated to better understand how to rationally design enhanced processivity in a Y-family pol. Guided by structural simulation, a fused pol Sdbh with non-specific dsDNA binding protein Sso7d in the N-terminus was designed. This modification increased in vitro processivity 4-fold as compared to the wild-type Dbh. Additionally, bioinformatics was used to identify amino acid mutations that would increase stabilization of Dbh bound to DNA. The variant SdbhM76I further improved the processivity of Dbh by 10 fold. The variant SdbhKSKIP241–245RVRKS showed higher activity than Dbh on the incorporation of dCTP (correct) and dATP (incorrect) opposite the G (normal) or 8-oxoG(damaged) template base. These results demonstrate the capability to rationally design increases in pol processivity and catalytic efficiency through computational DNA binding predictions and the addition of non-specific DNA binding domains.

Mechanisms of mutagenesis: DNA replication in the presence of DNA damage

Environmental mutagens cause DNA damage that disturbs replication and produces mutations, leading to cancer and other diseases. We discuss mechanisms of mutagenesis resulting from DNA damage, from the level of DNA replication by a single polymerase to the complex DNA replisome of some typical model organisms (including bacteriophage T7, T4, Sulfolobus solfataricus, Escherichia coli, yeast and human). For a single DNA polymerase, DNA damage can affect replication in three major ways: reducing replication fidelity, causing frameshift mutations, and blocking replication. For the DNA replisome, protein interactions and the functions of accessory proteins can yield rather different results even with a single DNA polymerase. The mechanism of mutation during replication performed by the DNA replisome is a long-standing question. Using new methods and techniques, the replisomes of certain organisms and human cell extracts can now be investigated with regard to the bypass of DNA damage. In this review, we consider the molecular mechanism of mutagenesis resulting from DNA damage in replication at the levels of single DNA polymerases and complex DNA replisomes, including translesion DNA synthesis.

Translesion DNA Synthesis

All living organisms are continually exposed to agents that damage their DNA, which threatens the integrity of their genome. As a consequence, cells are equipped with a plethora of DNA repair enzymes to remove the damaged DNA. Unfortunately, situations nevertheless arise where lesions persist, and these lesions block the progression of the cell's replicase. In these situations, cells are forced to choose between recombination-mediated "damage avoidance" pathways or a specialized DNA polymerase (pol) to traverse the blocking lesion. The latter process is referred to as Translesion DNA Synthesis (TLS). As inferred by its name, TLS not only results in bases being (mis)incorporated opposite DNA lesions but also bases being (mis)incorporated downstream of the replicase-blocking lesion, so as to ensure continued genome duplication and cell survival. Escherichia coli and Salmonella typhimurium possess five DNA polymerases, and while all have been shown to facilitate TLS under certain experimental conditions, it is clear that the LexA-regulated and damage-inducible pols II, IV, and V perform the vast majority of TLS under physiological conditions. Pol V can traverse a wide range of DNA lesions and performs the bulk of mutagenic TLS, whereas pol II and pol IV appear to be more specialized TLS polymerases.

(1)H, (13)C, and (15)N backbone resonance assignments of the full-length 40 kDa S. acidocaldarius Y-family DNA polymerase, dinB homolog

The dinB homolog (Dbh) is a member of the Y-family of translesion DNA polymerases, which are specialized to accurately replicate DNA across from a wide variety of lesions in living cells. Lesioned bases block the progression of high-fidelity polymerases and cause detrimental replication fork stalling; Y-family polymerases can bypass these lesions. The active site of the translesion synthesis polymerase is more open than that of a replicative polymerase; consequently Dbh polymerizes with low fidelity. Bypass polymerases also have low processivity. Short extension past the lesion allows the high-fidelity polymerase to switch back onto the site of replication. Dbh and the other Y-family polymerases have been used as structural models to investigate the mechanisms of DNA polymerization and lesion bypass. Many high-resolution crystal structures of Y-family polymerases have been reported. NMR dynamics studies can complement these structures by providing a measure of protein motions. Here we report the (15)N, (1)H, and (13)C backbone resonance assignments at two temperatures (35 and 50 °C) for Sulfolobus acidocaldarius Dbh polymerase. Backbone resonance assignments have been obtained for 86 % of the residues. The polymerase active site is assigned as well as the majority of residues in each of the four domains.

Lesion-Induced Mutation in the Hyperthermophilic Archaeon Sulfolobus acidocaldarius and Its Avoidance by the Y-Family DNA Polymerase Dbh

Hyperthermophilic archaea offer certain advantages as models of genome replication, and Sulfolobus Y-family polymerases Dpo4 (S. solfataricus) and Dbh (S. acidocaldarius) have been studied intensively in vitro as biochemical and structural models of trans-lesion DNA synthesis (TLS). However, the genetic functions of these enzymes have not been determined in the native context of living cells. We developed the first quantitative genetic assays of replication past defined DNA lesions and error-prone motifs in Sulfolobus chromosomes and used them to measure the efficiency and accuracy of bypass in normal and dbh(-) strains of Sulfolobus acidocaldarius. Oligonucleotide-mediated transformation allowed low levels of abasic-site bypass to be observed in S. acidocaldarius and demonstrated that the local sequence context affected bypass specificity; in addition, most erroneous TLS did not require Dbh function. Applying the technique to another common lesion, 7,8-dihydro-8-oxo-deoxyguanosine (8-oxo-dG), revealed an antimutagenic role of Dbh. The efficiency and accuracy of replication past 8-oxo-dG was higher in the presence of Dbh, and up to 90% of the Dbh-dependent events inserted dC. A third set of assays, based on phenotypic reversion, showed no effect of Dbh function on spontaneous -1 frameshifts in mononucleotide tracts in vivo, despite the extremely frequent slippage at these motifs documented in vitro. Taken together, the results indicate that a primary genetic role of Dbh is to avoid mutations at 8-oxo-dG that occur when other Sulfolobus enzymes replicate past this lesion. The genetic evidence that Dbh is recruited to 8-oxo-dG raises questions regarding the mechanism of recruitment, since Sulfolobus spp. have eukaryotic-like replisomes but no ubiquitin.

Cytosine unstacking and strand slippage at an insertion-deletion mutation sequence in an overhang-containing DNA duplex

Base unstacking in template strands, when accompanied by strand slippage, can result in deletion mutations during strand extension by nucleic acid polymerases. In a GCCC mutation hot-spot sequence, which was previously identified to have a 50% probability of causing such mutations during DNA replication by a Y-family polymerase, a single-base deletion mutation could result from such unstacking of any one of its three template cytosines. In this study, the intrinsic energetic differences in unstacking among these three cytosines in a solvated DNA duplex overhang model were examined using umbrella sampling molecular dynamics simulations. The free energy profiles obtained show that cytosine unstacking grows progressively more unfavorable as one moves inside the duplex from the 5′-end of the overhang template strand. Spontaneous strand slippage occurs in response to such base unstacking in the direction of both the major and minor grooves for all three cytosines. Unrestrained simulations run from three distinct strand-slipped states and one non-strand-slipped state suggest that a more duplexlike environment can help stabilize strand slippage. The possible underlying reasons and biological implications of these observations are discussed in the context of nucleic acid replication active site dynamics.

RB69 DNA polymerase structure, kinetics, and fidelity

This review will summarize our structural and kinetic studies of RB69 DNA polymerase (RB69pol) as well as selected variants of the wild-type enzyme that were undertaken to obtain a deeper understanding of the exquisitely high fidelity of B family replicative DNA polymerases. We discuss how the structures of the various RB69pol ternary complexes can be used to rationalize the results obtained from pre-steady-state kinetic assays. Our main findings can be summarized as follows. (i) Interbase hydrogen bond interactions can increase catalytic efficiency by 5000-fold; meanwhile, base selectivity is not solely determined by the number of hydrogen bonds between the incoming dNTP and the templating base. (ii) Minor-groove hydrogen bond interactions at positions n – 1 and n – 2 of the primer strand and position n – 1 of the template strand in RB69pol ternary complexes are essential for efficient primer extension and base selectivity. (iii) Partial charge interactions among the incoming dNTP, the penultimate base pair, and the hydration shell surrounding the incoming dNTP modulate nucleotide insertion efficiency and base selectivity. (iv) Steric clashes between mismatched incoming dNTPs and templating bases with amino acid side chains in the nascent base pair binding pocket (NBP) as well as weak interactions and large gaps between the incoming dNTPs and the templating base are some of the reasons that incorrect dNTPs are incorporated so inefficiently by wild-type RB69pol. In addition, we developed a tC°–tC_nitro Förster resonance energy transfer assay to monitor partitioning of the primer terminus between the polymerase and exonuclease subdomains.

An overview of Y-Family DNA polymerases and a case study of human DNA polymerase η

Y-Family DNA polymerases specialize in translesion synthesis, bypassing damaged bases that would otherwise block the normal progression of replication forks. Y-Family polymerases have unique structural features that allow them to bind damaged DNA and use a modified template base to direct nucleotide incorporation. Each Y-Family polymerase is unique and has different preferences for lesions to bypass and for dNTPs to incorporate. Y-Family polymerases are also characterized by a low catalytic efficiency, a low processivity, and a low fidelity on normal DNA. Recruitment of these specialized polymerases to replication forks is therefore regulated. The catalytic center of the Y-Family polymerases is highly conserved and homologous to that of high-fidelity and high-processivity DNA replicases. In this review, structural differences between Y-Family and A- and B-Family polymerases are compared and correlated with their functional differences. A time-resolved X-ray crystallographic study of the DNA synthesis reaction catalyzed by the Y-Family DNA polymerase human polymerase η revealed transient elements that led to the nucleotidyl-transfer reaction.

Three residues of the interdomain linker determine the conformation and single-base deletion fidelity of Y-family translesion polymerases

Dpo4 and Dbh are from two closely related Sulfolobus species and are well studied archaeal homologues of pol IV, an error prone Y-family polymerase from Escherichia coli. Despite sharing 54% amino acid identity, these polymerases display distinct mutagenic and translesion specificities. Structurally, Dpo4 and Dbh adopt different conformations because of the difference in relative orientation of their N-terminal catalytic and C-terminal DNA binding domains. Using chimeric constructs of these two polymerases, we have previously demonstrated that the interdomain linker is a major determinant of polymerase conformation, base-substitution fidelity, and abasic-site translesion synthesis. Here we find that the interdomain linker also affects the single-base deletion frequency and the mispair extension efficiency of these polymerases. Exchanging just three amino acids in the linkers of Dbh and Dpo4 is sufficient to change the fidelity by up to 30-fold, predominantly by altering the rate of correct (but not incorrect) nucleotide incorporation. Additionally, from a 2.4 Å resolution crystal structure, we have found that the three linker amino acids from Dpo4 are sufficient to allow Dbh to adopt the standard conformation of Dpo4. Thus, a small region of the interdomain linker, located more than 11 Å away from the catalytic residues, determines the fidelity of these Y-family polymerases, by controlling the alignment of substrates at the active site.

Analyzing the relationship between single base flipping and strand slippage near DNA duplex termini

Insertion-deletion (indel) mutations are caused by strand slippage between pairing primer and template strands during nucleic acid strand extension. A possible causative factor for such strand slippage is base flipping in the primer strand or template strand, for insertion or deletion mutations, respectively. A simple mechanistic description is that the "hole" in the nucleic acid duplex left behind by a flipping base is occupied by a neighboring base on the same strand, resulting in slippage with respect to its paired strand. The extent of single base flipping required for occupation of its former place in the double helix by a neighboring base is not fully understood. The present study uses restrained molecular dynamics (MD) simulations along a pseudohedihedral base flipping parameter to construct two-dimensional free energy profiles along base flipping and strand slippage geometric parameters. These profiles, generated for both cytosine and guanine single base flipping in a short repetitive indel mutation hot-spot DNA sequence, illustrate the extent of single base flipping that can allow strand slippage by one base position. Relatively minor base flipping into both the major and minor grooves can result in strand slippage. Deconstruction of the collective variable strand slippage geometric parameter into its component distances illustrates the details of how strand slippage can accompany base flipping. The trans Watson-Crick:sugar edge interaction that stabilizes cytosine flipping in this hot-spot sequence is also characterized energetically. The impact of these results on understanding sequence dependence of indel errors in nucleic acid strand extension is discussed, along with a suggestion for future studies that can generalize the present findings to all nearest-neighbor sequence contexts.

Translesion DNA polymerases

Living cells are continually exposed to DNA-damaging agents that threaten their genomic integrity. Although DNA repair processes rapidly target the damaged DNA for repair, some lesions nevertheless persist and block genome duplication by the cell's replicase. To avoid the deleterious consequence of a stalled replication fork, cells use specialized polymerases to traverse the damage. This process, termed "translesion DNA synthesis" (TLS), affords the cell additional time to repair the damage before the replicase returns to complete genome duplication. In many cases, this damage-tolerance mechanism is error-prone, and cell survival is often associated with an increased risk of mutagenesis and carcinogenesis. Despite being tightly regulated by a variety of transcriptional and posttranslational controls, the low-fidelity TLS polymerases also gain access to undamaged DNA where their inaccurate synthesis may actually be beneficial for genetic diversity and evolutionary fitness.

Partial base flipping is sufficient for strand slippage near DNA duplex termini

Strand slippage is a structural mechanism by which insertion-deletion (indel) mutations are introduced during replication by polymerases. Three-dimensional atomic-resolution structural pathways are still not known for the decades-old template slippage description. The dynamic nature of the process and the higher energy intermediates involved increase the difficulty of studying these processes experimentally. In the present study, restrained and unrestrained molecular dynamics simulations, carried out using multiple nucleic acid force fields, are used to demonstrate that partial base-flipping can be sufficient for strand slippage at DNA duplex termini. Such strand slippage can occur in either strand, i.e. near either the 3' or the 5' terminus of a DNA strand, which suggests that similar structural flipping mechanisms can cause both primer and template slippage. In the repetitive mutation hot-spot sequence studied, non-canonical base-pairing with exposed DNA groove atoms of a neighboring G:C base-pair stabilizes a partially flipped state of the cytosine. For its base-pair partner guanine, a similar partially flipped metastable intermediate was not detected, and the propensity for sustained slippage was also found to be lower. This illustrates that a relatively small metastable DNA structural distortion in polymerase active sites could allow single base insertion or deletion mutations to occur, and stringent DNA groove molecular recognition may be required to maintain intrinsic DNA polymerase fidelity. The implications of a close relationship between base-pair dissociation, base unstacking, and strand slippage are discussed in the context of sequence dependence of indel mutations.

Human polymerase kappa uses a template-slippage deletion mechanism, but can realign the slipped strands to favour base substitution mutations over deletions

Polymerases belonging to the DinB class of the Y-family translesion synthesis DNA polymerases have a preference for accurately and efficiently bypassing damaged guanosines. These DinB polymerases also generate single-base (-1) deletions at high frequencies with most occurring on repetitive 'deletion hotspot' sequences. Human DNA polymerase kappa (hPolκ), the eukaryotic DinB homologue, displays an unusual efficiency for to extend from mispaired primer termini, either by extending directly from the mispair or by primer-template misalignment. This latter property explains how hPolκ creates single-base deletions in non-repetitive sequences, but does not address how deletions occur in repetitive deletion hotspots. Here, we show that hPolκ uses a classical Streisinger template-slippage mechanism to generate -1 deletions in repetitive sequences, as do the bacterial and archaeal homologues. After the first nucleotide is added by template slippage, however, hPolκ can efficiently realign the primer-template duplex before continuing DNA synthesis. Strand realignment results in a base-substitution mutation, minimizing generation of more deleterious frameshift mutations. On non-repetitive sequences, we find that nucleotide misincorporation is slower if the incoming nucleotide can correctly basepair with the nucleotide immediately 5' to the templating base, thereby competing against the mispairing with the templating base.

A strategically located serine residue is critical for the mutator activity of DNA polymerase IV from Escherichia coli

The Y-family DNA polymerase IV or PolIV (Escherichia coli) is the founding member of the DinB family and is known to play an important role in stress-induced mutagenesis. We have determined four crystal structures of this enzyme in its pre-catalytic state in complex with substrate DNA presenting the four possible template nucleotides that are paired with the corresponding incoming nucleotide triphosphates. In all four structures, the Ser42 residue in the active site forms interactions with the base moieties of the incipient Watson–Crick base pair. This residue is located close to the centre of the nascent base pair towards the minor groove. In vitro and in vivo assays show that the fidelity of the PolIV enzyme increases drastically when this Ser residue was mutated to Ala. In addition, the structure of PolIV with the mismatch A:C in the active site shows that the Ser42 residue plays an important role in stabilizing dCTP in a conformation compatible with catalysis. Overall, the structural, biochemical and functional data presented here show that the Ser42 residue is present at a strategic location to stabilize mismatches in the PolIV active site, and thus facilitate the appearance of transition and transversion mutations.

Y-family polymerase conformation is a major determinant of fidelity and translesion specificity

Y-family polymerases help cells tolerate DNA damage by performing translesion synthesis opposite damaged DNA bases, yet they also have a high intrinsic error rate. We constructed chimeras of two closely related Y-family polymerases that display distinctly different activity profiles and found that the polypeptide linker that tethers the catalytic polymerase domain to the C-terminal DNA-binding domain is a major determinant of overall polymerase activity, nucleotide incorporation fidelity, and abasic site-bypass ability. Exchanging just 3 out of the 15 linker residues is sufficient to interconvert the polymerase activities tested. Crystal structures of four chimeras show that the conformation of the protein correlates with the identity of the interdomain linker sequence. Thus, residues that are more than 15 Å away from the active site are able to influence many aspects of polymerase activity by altering the relative orientations of the catalytic and DNA-binding domains.

DNA mismatch synthesis complexes provide insights into base selectivity of a B family DNA polymerase

Current hypotheses that attempt to rationalize the high degree of base selectivity exhibited by replicative DNA polymerases (pols) concur that ternary complexes formed with incorrect dNTPs are destabilized. Knowing what accounts for this destabilization is likely to be the key to understanding base discrimination. To address this issue, we have determined crystal structures of ternary complexes with all 12 mismatches using an engineered RB69 pol quadruple mutant (qm, L415A/L561A/S565G/Y567A) that enabled us to capture nascent mispaired dNTPs. These structures show that mismatches in the nascent base-pair binding pocket (NBP) of the qm pol differ markedly from mismatches embedded in binary pol-DNA complexes. Surprisingly, only 3 of 12 mismatches clash with the NBP when they are modeled into the wild-type (wt) pol. The remaining can fit into a wt pol ternary complex but deviate from normal Watson-Crick base-pairs. Repositioning of the templating nucleotide residue and the enlarged NBP in qm ternary complex play important roles in accommodating incorrect incoming dNTPs. From these structures, we propose additional reasons as to why incorrect dNTPs are incorporated so inefficiently by wt RB69 pol: (i) steric clashes with side chains in the NBP after Fingers closing; (ii) weak interactions or large gaps between the incoming dNTP and the templating base; and (iii) burying a protonated base in the hydrophobic environment of the NBP. All of these possibilities would be expected to destabilize the closed ternary complex so that incorporation of incorrect dNTP would be a rare event.

Differential temperature-dependent multimeric assemblies of replication and repair polymerases on DNA increase processivity

Differentiation of binding accurate DNA replication polymerases over error prone DNA lesion bypass polymerases is essential for the proper maintenance of the genome. The hyperthermophilic archaeal organism Sulfolobus solfataricus (Sso) contains both a B-family replication (Dpo1) and a Y-family repair (Dpo4) polymerase and serves as a model system for understanding molecular mechanisms and assemblies for DNA replication and repair protein complexes. Protein cross-linking, isothermal titration calorimetry, and analytical ultracentrifugation have confirmed a previously unrecognized dimeric Dpo4 complex bound to DNA. Binding discrimination between these polymerases on model DNA templates is complicated by the fact that multiple oligomeric species are influenced by concentration and temperature. Temperature-dependent fluorescence anisotropy equilibrium binding experiments were used to separate discrete binding events for the formation of trimeric Dpo1 and dimeric Dpo4 complexes on DNA. The associated equilibria are found to be temperature-dependent, generally leading to improved binding at higher temperatures for both polymerases. At high temperatures, DNA binding of Dpo1 monomer is favored over binding of Dpo4 monomer, but binding of Dpo1 trimer is even more strongly favored over binding of Dpo4 dimer, thus providing thermodynamic selection. Greater processivities of nucleotide incorporation for trimeric Dpo1 and dimeric Dpo4 are also observed at higher temperatures, providing biochemical validation for the influence of tightly bound oligomeric polymerases. These results separate, quantify, and confirm individual and sequential processes leading to the formation of oligomeric Dpo1 and Dpo4 assemblies on DNA and provide for a concentration- and temperature-dependent discrimination of binding undamaged DNA templates at physiological temperatures.

The PAD region in the mycobacterial DinB homologue MsPolIV exhibits positional heterogeneity

Y-family DNA polymerases (dPols) have evolved to carry out translesion bypass to rescue stalled replication; prokaryotic members of this family also participate in the phenomenon of adaptive mutagenesis to relieve selection pressure imposed by a maladapted environment. In this study, the first structure of a member of this family from a prokaryote has been determined. The structure of MsPolIV, a Y-family dPol from Mycobacterium smegmatis, shows the presence of the characteristic finger, palm and thumb domains. Surprisingly, the electron-density map of the intact protein does not show density for the PAD region that is unique to members of this family. Analysis of the packing of the molecules in the crystals showed the existence of large solvent-filled voids in which the PAD region could be located in multiple conformations. In line with this observation, analytical gel-filtration and dynamic light-scattering studies showed that MsPolIV undergoes significant compaction upon DNA binding. The PAD region is known to insert into the major groove of the substrate DNA and to play a major role in shaping the active site. Comparison with structures of other Y-family dPols shows that in the absence of tertiary contacts between the PAD domain and the other domains this region has the freedom to adopt multiple orientations. This structural attribute of the PAD will allow these enzymes to accommodate the alterations in the width of the DNA double helix that are necessary to achieve translesion bypass and adaptive mutagenesis and will also allow regulation of their activity to prevent adventitious error-prone DNA synthesis.

Structural basis of human DNA polymerase η-mediated chemoresistance to cisplatin

Cisplatin (cis-diamminedichloroplatinum) and related compounds cause DNA damage and are widely used as anticancer agents. Chemoresistance to cisplatin treatment is due in part to translesion synthesis by human DNA polymerase η (hPol η). Here, we report crystal structures of hPol η complexed with intrastrand cisplatin-1,2-cross-linked DNA, representing four consecutive steps in translesion synthesis. In contrast to the generally enlarged and nondiscriminating active site of Y-family polymerases like Dpo4, Pol η is specialized for efficient bypass of UV-cross-linked pyrimidine dimers. Human Pol η differs from the yeast homolog in its binding of DNA template. To incorporate deoxycytidine opposite cisplatin-cross-linked guanines, hPol η undergoes a specific backbone rearrangement to accommodate the larger base dimer and minimizes the DNA distortion around the lesion. Our structural analyses show why Pol η is inefficient at extending primers after cisplatin lesions, which necessitates a second translesion DNA polymerase to complete bypass in vivo. A hydrophobic pocket near the primer-binding site in human Pol η is identified as a potential drug target for inhibiting translesion synthesis and, thereby, reducing chemoresistance.

Sequence context effect on strand slippage in natural DNA primer-templates

Strand slippage has been found to occur in primer-templates containing a templating thymine, cytosine, and guanine, leading to the formation of misaligned structures with a single-nucleotide bulge. If remained in the active site of low-fidelity polymerases during DNA replication, these misaligned structures can ultimately bring about deletion mutations. In this study, we performed NMR investigations on primer-template models containing a templating adenine. Similar to our previous results on guanine, adenine templates are also less prone to strand slippage than pyrimidine templates. Misalignment occurs only in primer-templates that form a terminal C·G or G·C base pair. Together with our previous findings on thymine, cytosine, and guanine templates, the present study reveals strand slippage can occur in any kind of natural templating bases during DNA replication, providing insights into the origin of mutation hotspots in natural DNA sequences. In addition to the type of incoming base upon misincorporation, the propensity of strand slippage in primer-templates depends also on the type of templating base, its upstream and downstream bases.

Beyond translesion synthesis: polymerase κ fidelity as a potential determinant of microsatellite stability

Microsatellite DNA synthesis represents a significant component of human genome replication that must occur faithfully. However, yeast replicative DNA polymerases do not possess high fidelity for microsatellite synthesis. We hypothesized that the structural features of Y-family polymerases that facilitate accurate translesion synthesis may promote accurate microsatellite synthesis. We compared human polymerases κ (Pol κ) and η (Pol η) fidelities to that of replicative human polymerase δ holoenzyme (Pol δ4), using the in vitro HSV-tk assay. Relative polymerase accuracy for insertion/deletion (indel) errors within 2-3 unit repeats internal to the HSV-tk gene concurred with the literature: Pol δ4 >> Pol κ or Pol η. In contrast, relative polymerase accuracy for unit-based indel errors within [GT](10) and [TC](11) microsatellites was: Pol κ ≥ Pol δ4 > Pol η. The magnitude of difference was greatest between Pols κ and δ4 with the [GT] template. Biochemically, Pol κ displayed less synthesis termination within the [GT] allele than did Pol δ4. In dual polymerase reactions, Pol κ competed with either a stalled or moving Pol δ4, thereby reducing termination. Our results challenge the ideology that pol κ is error prone, and suggest that DNA polymerases with complementary biochemical properties can function cooperatively at repetitive sequences.

Cloning, expression, purification, crystallization and preliminary crystallographic analysis of MsDpo4: a Y-family DNA polymerase from Mycobacterium smegmatis

The expression of error-prone DNA polymerases belonging to the Y-family is upregulated in prokaryotes under adverse conditions to facilitate adaptive mutagenesis. However, it has been suggested that representatives of this family in mycobacteria do not participate in adaptive mutagenesis. These studies raise the possibility that mycobacterial representatives might be devoid of biochemical activity. In order to determine whether this possible loss of activity is a consequence of significant changes in the structure of these enzymes, structural studies on a representative enzyme from Mycobacterium smegmatis, MsDpo4, were initiated. The protein crystallized in space group P6(1)22 or P6(5)22. The Matthews coefficient was 4.0 Å3 Da(-1) assuming the presence of one molecule in the asymmetric unit; the corresponding solvent content was 69%. X-ray diffraction data were collected to a minimum Bragg spacing of 2.6 Å and crystals of selenomethionine-labelled MsDpo4 have been prepared for ab initio phasing.

A nucleotide binding rectification Brownian ratchet model for translocation of Y-family DNA polymerases

Y-family DNA polymerases are characterized by low-fidelity synthesis on undamaged DNA and ability to catalyze translesion synthesis over the damaged DNA. Their translocation along the DNA template is an important event during processive DNA synthesis. In this work we present a Brownian ratchet model for this translocation, where the directed translocation is rectified by the nucleotide binding to the polymerase. Using the model, different features of the available structures for Dpo4, Dbh and polymerase ι in binary and ternary forms can be easily explained. Other dynamic properties of the Y-family polymerases such as the fast translocation event upon dNTP binding for Dpo4 and the considerable variations of the processivity among the polymerases can also be well explained by using the model. In addition, some predicted results of the DNA synthesis rate versus the external force acting on Dpo4 and Dbh polymerases are presented. Moreover, we compare the effect of the external force on the DNA synthesis rate of the Y-family polymerase with that of the replicative DNA polymerase.

The Y-family DNA polymerase Dpo4 uses a template slippage mechanism to create single-base deletions

The Y-family polymerases help cells tolerate DNA damage by performing translesion synthesis, yet they also can be highly error prone. One distinctive feature of the DinB class of Y-family polymerases is that they make single-base deletion errors at high frequencies in repetitive sequences, especially those that contain two or more identical pyrimidines with a 5' flanking guanosine. Intriguingly, different deletion mechanisms have been proposed, even for two archaeal DinB polymerases that share 54% sequence identity and originate from two strains of Sulfolobus. To reconcile these apparent differences, we have characterized Dpo4 from Sulfolobus solfataricus using the same biochemical and crystallographic approaches that we have used previously to characterize Dbh from Sulfolobus acidocaldarius. In contrast to previous suggestions that Dpo4 uses a deoxynucleoside triphosphate (dNTP)-stabilized misalignment mechanism when creating single-base deletions, we find that Dpo4 predominantly uses a template slippage deletion mechanism when replicating repetitive DNA sequences, as was previously shown for Dbh. Dpo4 stabilizes the skipped template base in an extrahelical conformation between the polymerase and the little-finger domains of the enzyme. This contrasts with Dbh, in which the extrahelical base is stabilized against the surface of the little-finger domain alone. Thus, despite sharing a common deletion mechanism, these closely related polymerases use different contacts with the substrate to accomplish the same result.

Efficient extension of slipped DNA intermediates by DinB is required to escape primer template realignment by DnaQ

We show that Escherichia coli DinB polymerase, which creates single-base deletions, prefers to extend slipped DNA substrates with the skipped base at the -4 position. A DinB(Y79L) variant, which extends these substrates less efficiently in vitro, allows the proofreading function of polymerase III to reverse their formation in vivo.

DNA pol λ's extraordinary ability to stabilize misaligned DNA

DNA polymerases have the venerable task of maintaining genome stability during DNA replication and repair. Errors, nonetheless, occur with error propensities that are polymerase specific. For example, DNA polymerase λ (pol λ) generates single-base deletions through template-strand slippage within short repetitive DNA regions much more readily than does the closely related polymerase β (pol β). Here we present in silico evidence to help interpret pol λ's greater tendency for deletion errors than pol β by its more favorable protein/DNA electrostatic interactions immediately around the extrahelical nucleotide on the template strand. Our molecular dynamics and free energy analyses suggest that pol λ provides greater stabilization to misaligned DNA than aligned DNA. Our study of several pol λ mutants of Lys544 (Ala, Phe, Glu) probes the interactions between the extrahelical nucleotide and the adjacent Lys544 to show that the charge of the 544 residue controls stabilization of the DNA misalignment. In addition, we identify other thumb residues (Arg538, Lys521, Arg517, and Arg514) that play coordinating roles in stabilizing pol λ's interactions with misaligned DNA. Interestingly, their aggregate stabilization effect is more important than that of any one component residue, in contrast to aligned DNA systems, as we determined from mutations of these key residues and energetic analyses. No such comparable network of stabilizing misaligned DNA exists in pol β. Evolutionary needs for DNA repair on substrates with minimal base-pairing, such as those encountered by pol λ in the non-homologous end-joining pathway, may have been solved by a greater tolerance to deletion errors. Other base-flipping proteins share similar binding properties and motions for extrahelical nucleotides.

Kinetic basis of sugar selection by a Y-family DNA polymerase from Sulfolobus solfataricus P2

DNA polymerases use either a bulky active site residue or a backbone segment to select against ribonucleotides in order to faithfully replicate cellular genomes. Here, we demonstrated that an active site mutation (Y12A) within Sulfolobus solfataricus DNA polymerase IV (Dpo4) caused an average increase of 220-fold in matched ribonucleotide incorporation efficiency and an average decrease of 9-fold in correct deoxyribonucleotide incorporation efficiency, leading to an average reduction of 2000-fold in sugar selectivity. Thus, the bulky side chain of Tyr12 is important for both ribonucleotide discrimination and efficient deoxyribonucleotide incorporation. Other than synthesizing DNA as the wild-type Dpo4, the Y12A Dpo4 mutant incorporated more than 20 consecutive ribonucleotides into primer/template (DNA/DNA) duplexes, suggesting that this mutant protein possesses both a DNA-dependent DNA polymerase activity and a DNA-dependent RNA polymerase activity. Moreover, the binary and ternary crystal structures of Dpo4 have revealed that this DNA lesion bypass polymerase can bind up to eight base pairs of double-stranded DNA which is entirely in B-type. Thus, the DNA binding cleft of Dpo4 is flexible and can accommodate both A- and B-type oligodeoxyribonucleotide duplexes as well as damaged DNA.

Structure and mechanism of human DNA polymerase eta

The variant form of human xeroderma pigmentosum syndrome (XPV) is caused by a deficiency in DNA polymerase η (Pol η) that enables replication through sunlight-induced pyrimidine dimers. We report high-resolution crystal structures of human Pol η at four consecutive steps during DNA synthesis through cis-syn cyclobutane thymine dimers. Pol η acts like a molecular splint to stabilize damaged DNA in a normal B-form conformation. An enlarged active site accommodates the thymine dimer with excellent stereochemistry for two-metal ion catalysis. Two residues conserved among Pol η orthologs form specific hydrogen bonds with the lesion and the incoming nucleotide to assist translesion synthesis. Based on the structures, eight Pol η missense mutations causing XPV can be rationalized as undermining the “molecular splint” or perturbing the active-site alignment. The structures also shed light on the role of Pol η in replicating through D loop and DNA fragile sites.

UmuD(2) inhibits a non-covalent step during DinB-mediated template slippage on homopolymeric nucleotide runs

Escherichia coli DinB (DNA polymerase IV) possesses an enzyme architecture resulting in specialized lesion bypass function and the potential for creating -1 frameshifts in homopolymeric nucleotide runs. We have previously shown that the mutagenic potential of DinB is regulated by the DNA damage response protein UmuD(2). In the current study, we employ a pre-steady-state fluorescence approach to gain a mechanistic understanding of DinB regulation by UmuD(2). Our results suggest that DinB, like its mammalian and archaeal orthologs, uses a template slippage mechanism to create single base deletions on homopolymeric runs. With 2-aminopurine as a fluorescent reporter in the DNA substrate, the template slippage reaction results in a prechemistry fluorescence change that is inhibited by UmuD(2). We propose a model in which DNA templates containing homopolymeric nucleotide runs, when bound to DinB, are in an equilibrium between non-slipped and slipped conformations. UmuD(2), when bound to DinB, displaces the equilibrium in favor of the non-slipped conformation, thereby preventing frameshifting and potentially enhancing DinB activity on non-slipped substrates.

Mechanism of error-free and semitargeted mutagenic bypass of an aromatic amine lesion by Y-family polymerase Dpo4

The aromatic amine carcinogen 2-aminofluorene (AF) forms covalent adducts with DNA, predominantly with guanine at the C8 position. Such lesions are bypassed by Y-family polymerases such as Dpo4 via error-free and error-prone mechanisms. We show that Dpo4 catalyzes elongation from a correct 3′-terminal C opposite [AF]G in a nonrepetitive template sequence with low efficiency. This extension leads to cognate full-length product, as well as mis-elongated products containing base mutations and deletions. Crystal structures of the Dpo4 ternary complex with the 3′-terminal primer C base opposite [AF]G in the anti conformation and with the AF-moiety positioned in the major groove, revealed both accurate and misalignment-mediated mutagenic extension pathways. The mutagenic template/primer-dNTP arrangement is promoted by interactions between the polymerase and the bulky lesion, rather than by a base pairstabilized misaligment. Further extension leads to semi-targeted mutations via this proposed polymerase-guided mechanism.

Structural diversity of the Y-family DNA polymerases

The Y-family translesion DNA polymerases enable cells to tolerate many forms of DNA damage, yet these enzymes have the potential to create genetic mutations at high rates. Although this polymerase family was defined less than a decade ago, more than 90 structures have already been determined so far. These structures show that the individual family members bypass damage and replicate DNA with either error-free or mutagenic outcomes, depending on the polymerase, the lesion and the sequence context. Here, these structures are reviewed and implications for polymerase function are discussed.

Structural insight into translesion synthesis by DNA Pol II

E. coli DNA Pol II and eukaryotic Rev3 are B-family polymerases that can extend primers past a damaged or mismatched site when the high-fidelity replicative polymerases in the same family are ineffective. We report here the biochemical and structural properties of DNA Pol II that facilitate this translesion synthesis. DNA Pol II can extend primers past lesions either directly or by template skipping, in which small protein cavities outside of the active site accommodate looped-out template nucleotides 1 or 2 bp upstream. Because of multiple looping-out alternatives, mutation spectra of bypass synthesis are complicated. Moreover, translesion synthesis is enhanced by altered partitioning of DNA substrate between the polymerase active site and the proofreading exonuclease site. Compared to the replicative B family polymerases, DNA Pol II has subtle amino acid changes remote from the active site that allow it to replicate normal DNA with high efficiency yet conduct translesion synthesis when needed.

NMR investigation of DNA primer-template models: guanine templates are less prone to strand slippage upon misincorporation

Misaligned structures can result from strand slippage during DNA replication and, if not repaired, would lead to mutations. Previously, we showed that strand slippage can occur upon misincorporation of a dNTP opposite thymine and cytosine templates, resulting in a misaligned structure with a T- or C-bulge. The formation propensity for misaligned structures was found to depend on the type of terminal base pair. In this study, we performed NMR investigations on primer-template models containing a guanine template. Our results reveal guanine templates are less prone to strand slippage than pyrimidine templates. Misalignment was found to occur only in 5'-CG templates with a downstream purine. In addition to the significance of terminal base pair and upstream nucleotide, the present study reveals the importance of the templating base and its downstream nucleotide, which also determine the propensity of strand slippage in primer-templates.

A DinB variant reveals diverse physiological consequences of incomplete TLS extension by a Y-family DNA polymerase

The only Y-family DNA polymerase conserved among all domains of life, DinB and its mammalian ortholog pol kappa, catalyzes proficient bypass of damaged DNA in translesion synthesis (TLS). Y-family DNA polymerases, including DinB, have been implicated in diverse biological phenomena ranging from adaptive mutagenesis in bacteria to several human cancers. Complete TLS requires dNTP insertion opposite a replication blocking lesion and subsequent extension with several dNTP additions. Here we report remarkably proficient TLS extension by DinB from Escherichia coli. We also describe a TLS DNA polymerase variant generated by mutation of an evolutionarily conserved tyrosine (Y79). This mutant DinB protein is capable of catalyzing dNTP insertion opposite a replication-blocking lesion, but cannot complete TLS, stalling three nucleotides after an N(2)-dG adduct. Strikingly, expression of this variant transforms a bacteriostatic DNA damaging agent into a bactericidal drug, resulting in profound toxicity even in a dinB(+) background. We find that this phenomenon is not exclusively due to a futile cycle of abortive TLS followed by exonucleolytic reversal. Rather, gene products with roles in cell death and metal homeostasis modulate the toxicity of DinB(Y79L) expression. Together, these results indicate that DinB is specialized to perform remarkably proficient insertion and extension on damaged DNA, and also expose unexpected connections between TLS and cell fate.

Separate roles of structured and unstructured regions of Y-family DNA polymerases

All organisms have multiple DNA polymerases specialized for translesion DNA synthesis (TLS) on damaged DNA templates. Mammalian TLS DNA polymerases include Pol eta, Pol iota, Pol kappa, and Rev1 (all classified as "Y-family" members) and Pol zeta (a "B-family" member). Y-family DNA polymerases have highly structured catalytic domains; however, some of these proteins adopt different structures when bound to DNA (such as archaeal Dpo4 and human Pol kappa), while others maintain similar structures independently of DNA binding (such as archaeal Dbh and Saccharomyces cerevisiae Pol eta). DNA binding-induced structural conversions of TLS polymerases depend on flexible regions present within the catalytic domains. In contrast, noncatalytic regions of Y-family proteins, which contain multiple domains and motifs for interactions with other proteins, are predicted to be mostly unstructured, except for short regions corresponding to ubiquitin-binding domains. In this review we discuss how the organization of structured and unstructured regions in TLS polymerases is relevant to their regulation and function during lesion bypass.

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 kappa 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,N(2)-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.

Probing conformational changes of human DNA polymerase lambda using mass spectrometry-based protein footprinting

Crystallographic studies of the C-terminal DNA polymerase-beta-like domain of full-length human DNA polymerase lambda (fPollambda) suggested that the catalytic cycle might not involve a large protein domain rearrangement as observed with several replicative DNA polymerases and DNA polymerase beta. To examine solution-phase protein conformational changes in fPollambda, which also contains a breast cancer susceptibility gene 1 C-terminal domain and a proline-rich domain at its N-terminus, we used a mass spectrometry-based protein footprinting approach. In parallel experiments, surface accessibility maps for Arg residues were compared for the free fPollambda versus the binary complex of enzyme*gapped DNA and the ternary complex of enzyme*gapped DNA*dNTP (2'-deoxynucleotide triphosphate). These experiments suggested that fPollambda does not undergo major conformational changes during the catalysis in the solution phase. Furthermore, the mass spectrometry-based protein footprinting experiments revealed that active site residue R386 was shielded from the surface only in the presence of both a gapped DNA substrate and an incoming nucleotide. Site-directed mutagenesis and pre-steady-state kinetic studies confirmed the importance of R386 for the enzyme activity and indicated the key role for its guanidino group in stabilizing the negative charges of an incoming nucleotide and the leaving pyrophosphate product. We suggest that such interactions could be shared by and important for catalytic functions of other DNA polymerases.