Characterization of Family D DNA polymerase from Thermococcus sp. 9°N

Accurate DNA replication is essential for maintenance of every genome. All archaeal genomes except Crenarchaea, encode for a member of Family B (polB) and Family D (polD) DNA polymerases. Gene deletion studies in Thermococcus kodakaraensis and Methanococcus maripaludis show that polD is the only essential DNA polymerase in these organisms. Thus, polD may be the primary replicative DNA polymerase for both leading and lagging strand synthesis. To understand this unique archaeal enzyme, we report the biochemical characterization of a heterodimeric polD from Thermococcus. PolD contains both DNA polymerase and proofreading 3′–5′ exonuclease activities to ensure efficient and accurate genome duplication. The polD incorporation fidelity was determined for the first time. Despite containing 3′–5′ exonuclease proofreading activity, polD has a relatively high error rate (95 × 10^?5) compared to polB (19 × 10^?5) and at least 10-fold higher than the polB DNA polymerases from yeast (polε and polδ) or Escherichia coli DNA polIII holoenzyme. The implications of polD fidelity and biochemical properties in leading and lagging strand synthesis are discussed.     

Slipped Misalignment Mechanisms of Deletion Formation: In Vivo Susceptibility to Nucleases

Misalignment of repeated sequences during DNA replication can lead to deletions or duplications in genomic DNA. In Escherichia coli, such genetic rearrangements can occur at high frequencies, independent of the RecA-homologous recombination protein, and are sometimes associated with sister chromosome exchange (SCE). Two mechanisms for RecA-independent genetic rearrangements have been proposed: simple replication misalignment of the nascent strand and its template and SCE-associated misalignment involving both nascent strands. We examined the influence of the 3′ exonuclease of DNA polymerase III and exonuclease I on deletion via these mechanisms in vivo. Because mutations in these exonucleases stimulate tandem repeat deletion, we conclude that displaced 3′ ends are a common intermediate in both mechanisms of slipped misalignments. Our results also confirm the notion that two distinct mechanisms contribute to slipped misalignments: simple replication misalignment events are sensitive to DNA polymerase III exonuclease, whereas SCE-associated events are sensitive to exonuclease I. If heterologies are present between repeated sequences, the mismatch repair system dependent on MutS and MutH aborts potential deletion events via both mechanisms. Our results suggest that simple slipped misalignment and SCE-associated misalignment intermediates are similarly susceptible to destruction by the mismatch repair system.     

RPA activates the XPF‐ERCC1 endonuclease to initiate processing of DNA interstrand crosslinks

During replication‐coupled DNA interstrand crosslink (ICL) repair, the XPF‐ERCC1 endonuclease is required for the incisions that release, or “unhook”, ICLs, but the mechanism of ICL unhooking remains largely unknown. Incisions are triggered when the nascent leading strand of a replication fork strikes the ICL. Here, we report that while purified XPF‐ERCC1 incises simple ICL‐containing model replication fork structures, the presence of a nascent leading strand, modelling the effects of replication arrest, inhibits this activity. Strikingly, the addition of the single‐stranded DNA (ssDNA)‐binding replication protein A (RPA) selectively restores XPF‐ERCC1 endonuclease activity on this structure. The 5′–3′ exonuclease SNM1A can load from the XPF‐ERCC1‐RPA‐induced incisions and digest past the crosslink to quantitatively complete the unhooking reaction. We postulate that these collaborative activities of XPF‐ERCC1, RPA and SNM1A might explain how ICL unhooking is achieved in vivo.     

Identification of RNase T as a high-copy suppressor of the UV sensitivity associated with single-strand DNA exonuclease deficiency in Escherichia coli

There are three known single-strand DNA-specific exonucleases in Escherichia coli: RecJ, exonuclease I (ExoI), and exonuclease VII (ExoVII). E. coli that are deficient in all three exonucleases are abnormally sensitive to UV irradiation, most likely because of their inability to repair lesions that block replication. We have performed an iterative screen to uncover genes capable of ameliorating the UV repair defect of xonA (ExoI-) xseA (ExoVII-) recJ triple mutants. In this screen, exonuclease-deficient cells were transformed with a high-copy E. coli genomic library and then irradiated; plasmids harvested from surviving cells were used to seed subsequent rounds of transformation and selection. After several rounds of selection, multiple plasmids containing the rnt gene, which encodes RNase T, were found. An rnt plasmid increased the UV resistance of a xonA xseA recJ mutant and uvrA and uvrC mutants; however, it did not alter the survival of xseA recJ or recA mutants. RNase T also has amino acid sequence similarity to other 3' DNA exonucleases, including ExoI. These results suggest that RNase T may possess a 3' DNase activity capable of substituting for ExoI in the recombinational repair of UV-induced lesions.     

Increased and Imbalanced dNTP Pools Symmetrically Promote Both Leading and Lagging Strand Replication Infidelity

The fidelity of DNA replication requires an appropriate balance of dNTPs, yet the nascent leading and lagging strands of the nuclear genome are primarily synthesized by replicases that differ in subunit composition, protein partnerships and biochemical properties, including fidelity. These facts pose the question of whether imbalanced dNTP pools differentially influence leading and lagging strand replication fidelity. Here we test this possibility by examining strand-specific replication infidelity driven by a mutation in yeast ribonucleotide reductase, rnr1-Y285A, that leads to elevated dTTP and dCTP concentrations. The results for the CAN1 mutational reporter gene present in opposite orientations in the genome reveal that the rates, and surprisingly even the sequence contexts, of replication errors are remarkably similar for leading and lagging strand synthesis. Moreover, while many mismatches driven by the dNTP pool imbalance are efficiently corrected by mismatch repair, others are repaired less efficiently, especially those in sequence contexts suggesting reduced proofreading due to increased mismatch extension driven by the high dTTP and dCTP concentrations. Thus the two DNA strands of the nuclear genome are at similar risk of mutations resulting from this dNTP pool imbalance, and this risk is not completely suppressed even when both major replication error correction mechanisms are genetically intact.     

Exonuclease X of Escherichia coli. A novel 3'-5' DNase and Dnaq superfamily member involved in DNA repair.

DNA exonucleases are critical for DNA replication, repair, and recombination. In the bacterium Escherichia coli there are 14 DNA exonucleases including exonucleases I-IX (including the two DNA polymerase I exonucleases), RecJ exonuclease, SbcCD exonuclease, RNase T, and the exonuclease domains of DNA polymerase II and III. Here we report the discovery and characterization of a new E. coli exonuclease, exonuclease X. Exonuclease X is a member of a superfamily of proteins that have homology to the 3'-5' exonuclease proofreading subunit (DnaQ) of E. coli DNA polymerase III. We have engineered and purified a (His)(6)-exonuclease X fusion protein and characterized its activity. Exonuclease X is a potent distributive exonuclease, capable of degrading both single-stranded and duplex DNA with 3'-5' polarity. Its high affinity for single-strand DNA and its rapid catalytic rate are similar to the processive exonucleases RecJ and exonuclease I. Deletion of the exoX gene exacerbated the UV sensitivity of a strain lacking RecJ, exonuclease I, and exonuclease VII. When overexpressed, exonuclease X is capable of substituting for exonuclease I in UV repair. As we have proposed for the other single-strand DNA exonucleases, exonuclease X may facilitate recombinational repair by pre-synaptic and/or post-synaptic DNA degradation.     

Chlamydophila pneumoniae endonuclease IV prefers to remove mismatched 3′ ribonucleotides: Implication in proofreading mismatched 3′-terminal nucleotides in short-patch repair synthesis

DNA polymerase I (DNApolI) catalyzes DNA synthesis during Okazaki fragment maturation, base excision repair, and nucleotide excision repair. Some bacterial DNApolIs are deficient in 3′–5′ exonuclease, which is required for removing an incorrectly incorporated 3′-terminal nucleotide during DNA elongation by DNA polymerase activity. The key amino acid residues in the exonuclease center of Chlamydophila pneumoniae DNApolI (CpDNApolI) are naturally mutated, resulting in the loss of 3′–5′ exonuclease. Hence, the manner by which CpDNApolI proofreads the incorrectly incorporated nucleotide during DNA synthesis warrants clarification. C. pneumoniae encodes three 3′–5′ exonuclease activities: one endonuclease IV and two homologs of the epsilon subunit of replicative DNA polymerase III. The three proteins were biochemically characterized using single- and double-stranded DNA substrate. Among them, C. pneumoniae endonuclease IV (CpendoIV) possesses 3′–5′ exonuclease activity that prefers to remove mismatched 3′-terminal nucleotides in the nick, gap, and 3′ recess of a double-stranded DNA (dsDNA). Finally, we reconstituted the proofreading reaction of the mismatched 3′-terminal nucleotide using the dsDNA with a nick or 3′ recess as substrate. Upon proofreading of the mismatched 3′-terminal nucleotide by CpendoIV, CpDNApolI can correctly reincorporate the matched nucleotide and the nick is further sealed by DNA ligase. Based on our biochemical results, we proposed that CpendoIV was responsible for proofreading the replication errors of CpDNApolI.     

Exonuclease VII is involved in “reckless” DNA degradation in UV-irradiated Escherichia coli

The recA mutants of Escherichia coli exhibit an abnormal DNA degradation that starts at sites of double-strand DNA breaks (DSBs), and is mediated by RecBCD exonuclease (ExoV). This “reckless” DNA degradation occurs spontaneously in exponentially growing recA cells, and is stimulated by DNA-damaging agents. We have previously found that the xonA and sbcD mutations, which inactivate exonuclease I (ExoI) and SbcCD nuclease, respectively, markedly suppress “reckless” DNA degradation in UV-irradiated recA cells. In the present work, we show that inactivation of exonuclease VII (ExoVII) by an xseA mutation contributes to attenuation of DNA degradation in UV-irradiated recA mutants. The xseA mutation itself has only a weak effect, however, it acts synergistically with the xonA or sbcD mutations in suppressing “reckless” DNA degradation. The quadruple xseA xonA sbcD recA mutants show no sign of DNA degradation during post-irradiation incubation, suggesting that ExoVII, together with ExoI and SbcCD, plays a crucial role in regulating RecBCD-catalyzed chromosome degradation. We propose that these nucleases act on DSBs to create blunt DNA ends, the preferred substrates for the RecBCD enzyme. In addition, our results show that in UV-irradiated recF recA⁺ cells, the xseA, xonA, and sbcD mutations do not affect RecBCD-mediated DNA repair, suggesting that ExoVII, ExoI and SbcCD nucleases are not essential for the initial targeting of RecBCD to DSBs. It is possible that the DNA-blunting activity provided by ExoVII, ExoI and SbcCD is required for an exchange of RecBCD molecules on dsDNA ends during ongoing “reckless” DNA degradation.     

DNA polymerase B from wheat embryos: a plant delta-like DNA polymerase.

Studies in eucaryotic cells (mainly animals and yeast) indicate that at least two DNA polymerases are involved in DNA replication at the level of the replication fork: DNA polymerase alpha, which is associated with DNA primase, is involved in the replication of the lagging strand; DNA polymerase delta, associated with an exonuclease activity, synthesizes the forward continuous DNA strand. Much less information exists concerning plant systems. Previous work from this laboratory provided preliminary evidence of an association between DNA polymerase B from wheat embryo and an exonucleolytic activity. In this paper, we present additional data on the biochemical properties of DNA polymerase B. An improved purification procedure described in this article has been developed. During all the purification steps the nuclease activity was associated with DNA polymerase activity. A biochemical study of this enzyme activity shows that it is an exonuclease which hydrolyses DNA in the 3' to 5' direction. Moreover, this exonuclease confers a proofreading function to DNA polymerase B. Comparison of DNA polymerase B properties (template specificity, sensitivity to DNA replication inhibitors like aphidicolin and butyl-phenyl dGTP, copurification of DNA polymerase and exonuclease activities) with those of animal DNA polymerase delta indicates that these enzymes share many common features. To our knowledge, this is the first report of DNA polymerase delta in higher plants.     

Influence of Oxidized Purine Processing on Strand Directionality of Mismatch Repair

Replicative DNA polymerases are high fidelity enzymes that misincorporate nucleotides into nascent DNA with a frequency lower than [1/10⁵], and this precision is improved to about [1/10⁷] by their proofreading activity. Because this fidelity is insufficient to replicate most genomes without error, nature evolved postreplicative mismatch repair (MMR), which improves the fidelity of DNA replication by up to 3 orders of magnitude through correcting biosynthetic errors that escaped proofreading. MMR must be able to recognize non-Watson-Crick base pairs and excise the misincorporated nucleotides from the nascent DNA strand, which carries by definition the erroneous genetic information. In eukaryotes, MMR is believed to be directed to the nascent strand by preexisting discontinuities such as gaps between Okazaki fragments in the lagging strand or breaks in the leading strand generated by the mismatch-activated endonuclease of the MutL homologs PMS1 in yeast and PMS2 in vertebrates. We recently demonstrated that the eukaryotic MMR machinery can make use also of strand breaks arising during excision of uracils or ribonucleotides from DNA. We now show that intermediates of MutY homolog-dependent excision of adenines mispaired with 8-oxoguanine (G^O) also act as MMR initiation sites in extracts of human cells or Xenopus laevis eggs. Unexpectedly, G^O/C pairs were not processed in these extracts and failed to affect MMR directionality, but extracts supplemented with exogenous 8-oxoguanine DNA glycosylase (OGG1) did so. Because OGG1-mediated excision of G^O might misdirect MMR to the template strand, our findings suggest that OGG1 activity might be inhibited during MMR.     

Insights into mutagenesis using Escherichia coli chromosomal lacZ strains that enable detection of a wide spectrum of mutational events

Strand misalignments at DNA repeats during replication are implicated in mutational hotspots. To study these events, we have generated strains carrying mutations in the Escherichia coli chromosomal lacZ gene that revert via deletion of a short duplicated sequence or by template switching within imperfect inverted repeat (quasipalindrome, QP) sequences. Using these strains, we demonstrate that mutation of the distal repeat of a quasipalindrome, with respect to replication fork movement, is about 10-fold higher than the proximal repeat, consistent with more common template switching on the leading strand. The leading strand bias was lost in the absence of exonucleases I and VII, suggesting that it results from more efficient suppression of template switching by 3' exonucleases targeted to the lagging strand. The loss of 3' exonucleases has no effect on strand misalignment at direct repeats to produce deletion. To compare these events to other mutations, we have reengineered reporters (designed by Cupples and Miller 1989) that detect specific base substitutions or frameshifts in lacZ with the reverting lacZ locus on the chromosome rather than an F' element. This set allows rapid screening of potential mutagens, environmental conditions, or genetic loci for effects on a broad set of mutational events. We found that hydroxyurea (HU), which depletes dNTP pools, slightly elevated templated mutations at inverted repeats but had no effect on deletions, simple frameshifts, or base substitutions. Mutations in nucleotide diphosphate kinase, ndk, significantly elevated simple mutations but had little effect on the templated class. Zebularine, a cytosine analog, elevated all classes.     

Exonuclease 1 preferentially repairs mismatches generated by DNA polymerase α

The Saccharomyces cerevisiae EXO1 gene encodes a 5′ exonuclease that participates in mismatch repair (MMR) of DNA replication errors. Deleting EXO1 was previously shown to increase mutation rates to a greater extent when combined with a mutator variant (pol3-L612M) of the lagging strand replicase, DNA polymerase δ (Pol δ), than when combined with a mutator variant (pol2-M644G) of the leading strand replicase, DNA polymerase ? (Pol ?). Here we confirm that result, and extend the approach to examine the effect of deleting EXO1 in a mutator variant (pol1-L868M) of Pol α, the proofreading-deficient and least accurate of the three nuclear replicases that is responsible for initiating Okazaki fragment synthesis. We find that deleting EXO1 increases the mutation rate in the Pol α mutator strain to a significantly greater extent than in the Pol δ or Pol ? mutator strains, thereby preferentially reducing the efficiency of MMR of replication errors generated by Pol α. Because these mismatches are closer to the 5′ ends of Okazaki fragments than are mismatches made by Pol δ or Pol ?, the results not only support the previous suggestion that Exo1 preferentially excises lagging strand replication errors during mismatch repair, they further imply that the 5′ ends serve as entry points for 5′ excision of replication errors made by Pol α, and possibly as strand discrimination signals for MMR. Nonetheless, mutation rates in the Pol α mutator strain are 5- to 25-fold lower in an exo1Δ strain as compared to an msh2Δ strain completely lacking MMR, indicating that in the absence of Exo1, most replication errors made by Pol α can still be removed in an Msh2-dependent manner by other nucleases and/or by strand displacement.     

An Oak Ridge legacy: the specific locus test and its role in mouse mutagenesis.

Mutations in the genes encoding single-strand DNA-specific exonucleases (ssExos) of Escherichia coli were examined for effects on mutation avoidance, UV repair, and conjugational recombination. Our results indicate complex and partially redundant roles for ssExos in these processes. Although biochemical experiments have implicated RecJ exonuclease, Exonuclease I (ExoI), and Exonuclease VII (ExoVII) in the methyl-directed mismatch repair pathway, the RecJ- ExoI- ExoVII- mutant did not exhibit a mutator phenotype in several assays for base substitution mutations. If these exonucleases do participate in mismatch excision, other exonucleases in E. coli can compensate for their loss. Frameshift mutations, however, were stimulated in the RecJ- ExoI- ExoVII- mutant. For acridine-induced frameshifts, this mutator effect was due to a synergistic effect of ExoI- and ExoVII- mutations, implicating both ExoI and ExoVII in avoidance of frameshift mutations. Although no single exonuclease mutant was especially sensitive to UV irradiation, the RecJ- ExoVII- double mutant was extremely sensitive. The addition of an ExoI- mutation augmented this sensitivity, suggesting that all three exonucleases play partially redundant roles in DNA repair. The ability to inherit genetic markers by conjugation was reduced modestly in the ExoI- RecJ- mutant, implying that the function of either ExoI or RecJ exonucleases enhances RecBCD-dependent homologous recombination.     

Cis and trans-acting effects on a mutational hotspot involving a replication template switch

A natural mutational hotspot in the thyA gene of Escherichia coli accounts for over half of the mutations that inactivate this gene, which can be selected by resistance to the antibiotic trimethoprim. This T to A transversion, at base 131 of the coding sequence, occurs within a 17 bp quasi-palindromic sequence. To clarify the mechanism of mutagenesis, we examine here cis and trans-acting factors affecting thyA131 mutational hotspot activity at its natural location on the E.coli chromosome. Confirming a template-switch mechanism for mutagenesis, an alteration that strengthens base-pairing between the inverted repeat DNA sequences surrounding the hotspot stimulated mutagenesis and, conversely, mutations that weakened pairing reduced hotspot activity. In addition, consistent with the idea that the hotspot mutation is templated from DNA synthesis from mispaired strands of the inverted repeats, co-mutation of multiple sites within the quasipalindrome was observed as predicted from the DNA sequence of the corresponding repeat. Surprisingly, inversion of the thyA operon on the chromosome did not abolish thyA131 hotspot mutagenesis, indicating that mutagenesis at this site occurs during both leading and lagging-strand synthesis. Loss of the SOS-induced DNA polymerases PolII, PolIV, and PolV, caused a marked increase in the hotspot mutation rate, indicating a heretofore unknown and redundant antimutagenic effect of these repair polymerases. Hotspot mutagenesis did not require the PriA replication restart factor and hence must not require fork reassembly after the template-switch reaction. Deficiency in the two major 3' single-strand DNA exonucleases, ExoI and ExoVII, stimulated hotspot mutagenesis 30-fold and extended the mutagenic tract, indicating that these exonucleases normally abort a large fraction of premutagenic events. The high frequency of quasipalindrome-associated mutations suggests that template-switching occurs readily during chromosomal replication.     

Evidence that errors made by DNA polymerase alpha are corrected by DNA polymerase delta

Eukaryotic replication begins at origins and on the lagging strand with RNA-primed DNA synthesis of a few nucleotides by polymerase alpha, which lacks proofreading activity. A polymerase switch then allows chain elongation by proofreading-proficient pol delta and pol epsilon. Pol delta and pol epsilon are essential, but their roles in replication are not yet completely defined . Here, we investigate their roles by using yeast pol alpha with a Leu868Met substitution . L868M pol alpha copies DNA in vitro with normal activity and processivity but with reduced fidelity. In vivo, the pol1-L868M allele confers a mutator phenotype. This mutator phenotype is strongly increased upon inactivation of the 3' exonuclease of pol delta but not that of pol epsilon. Several nonexclusive explanations are considered, including the hypothesis that the 3' exonuclease of pol delta proofreads errors generated by pol alpha during initiation of Okazaki fragments. Given that eukaryotes encode specialized, proofreading-deficient polymerases with even lower fidelity than pol alpha, such intermolecular proofreading could be relevant to several DNA transactions that control genome stability.     

Structure of Escherichia coli exonuclease I suggests how processivity is achieved

Exonuclease I (ExoI) from Escherichia coli is a monomeric enzyme that processively degrades single stranded DNA in the 3' to 5' direction and has been implicated in DNA recombination and repair. Determination of the structure of ExoI to 2.4 A resolution using X-ray crystallography verifies the expected correspondence between a region of ExoI and the exonuclease (or proofreading) domains of the DNA polymerases. The overall fold of ExoI also includes two other regions, one of which extends the exonuclease domain and another that can be described as an elaborated SH3 domain. These three regions combine to form a molecule that is shaped like the letter C, although it also contains a segment that effectively converts the C into an O-like shape. The structure of ExoI thus provides additional support for the idea that DNA metabolizing enzymes achieve processivity by completely enclosing the DNA.     

Evidence for Extrinsic Exonucleolytic Proofreading

Exonucleolytic proofreading of DNA synthesis errors is one of the major determinants ofgenome stability. However, many DNA transactions that contribute to genome stability requiresynthesis by polymerases that naturally lack intrinsic 3´ exonuclease activity and some of whichare highly inaccurate. Here we discuss evidence that errors made by these polymerases may beedited by a separate 3´ exonuclease, and we consider how such extrinsic proofreading may differfrom proofreading by exonucleases that are intrinsic to replicative DNA polymerases.     

Substrate specificity and proposed structure of the proofreading complex of T7 DNA polymerase

Faithful replication of genomic DNA by high-fidelity DNA polymerases is crucial for the survival of most living organisms. While high-fidelity DNA polymerases favor canonical base pairs over mismatches by a factor of ∼1 × 10⁵, fidelity is further enhanced several orders of magnitude by a 3′–5′ proofreading exonuclease that selectively removes mispaired bases in the primer strand. Despite the importance of proofreading to maintaining genome stability, it remains much less studied than the fidelity mechanisms employed at the polymerase active site. Here we characterize the substrate specificity for the proofreading exonuclease of a high-fidelity DNA polymerase by investigating the proofreading kinetics on various DNA substrates. The contribution of the exonuclease to net fidelity is a function of the kinetic partitioning between extension and excision. We show that while proofreading of a terminal mismatch is efficient, proofreading a mismatch buried by one or two correct bases is even more efficient. Because the polymerase stalls after incorporation of a mismatch and after incorporation of one or two correct bases on top of a mismatch, the net contribution of the exonuclease is a function of multiple opportunities to correct mistakes. We also characterize the exonuclease stereospecificity using phosphorothioate-modified DNA, provide a homology model for the DNA primer strand in the exonuclease active site, and propose a dynamic structural model for the transfer of DNA from the polymerase to the exonuclease active site based on MD simulations.     

Comparison of the kinetic parameters of the truncated catalytic subunit and holoenzyme of human DNA polymerase ɛ

Numerous genetic studies have provided compelling evidence to establish DNA polymerase ɛ (Polɛ) as the primary DNA polymerase responsible for leading strand synthesis during eukaryotic nuclear genome replication. Polɛ is a heterotetramer consisting of a large catalytic subunit that contains the conserved polymerase core domain as well as a 3′ → 5′ exonuclease domain common to many replicative polymerases. In addition, Polɛ possesses three small subunits that lack a known catalytic activity but associate with components involved in a variety of DNA replication and maintenance processes. Previous enzymatic characterization of the Polɛ heterotetramer from budding yeast suggested that the small subunits slightly enhance DNA synthesis by Polɛ in vitro. However, similar studies of the human Polɛ heterotetramer (hPolɛ) have been limited by the difficulty of obtaining hPolɛ in quantities suitable for thorough investigation of its catalytic activity. Utilization of a baculovirus expression system for overexpression and purification of hPolɛ from insect host cells has allowed for isolation of greater amounts of active hPolɛ, thus enabling a more detailed kinetic comparison between hPolɛ and an active N-terminal fragment of the hPolɛ catalytic subunit (p261N), which is readily overexpressed in Escherichia coli. Here, we report the first pre-steady-state studies of fully-assembled hPolɛ. We observe that the small subunits increase DNA binding by hPolɛ relative to p261N, but do not increase processivity during DNA synthesis on a single-stranded M13 template. Interestingly, the 3′ → 5′ exonuclease activity of hPolɛ is reduced relative to p261N on matched and mismatched DNA substrates, indicating that the presence of the small subunits may regulate the proofreading activity of hPolɛ and sway hPolɛ toward DNA synthesis rather than proofreading.     

The 3′ → 5′ exonucleases of both DNA polymerases δ and ε participate in correcting errors of DNA replication in Saccharomyces cerevisiae

DNA polymerases II (ε) and III(δ) are the only nuclear DNA polymerases known to possess an intrinsic 3′ → 5′ exonuclease in Saccharomyces cerevisiae. We have investigated the spontaneous mutator phenotypes of DNA polymerase δ and ε 3′ → 5′ exonuclease-deficient mutants, pol3-01 and pol2-4, respectively. pol3-01 and pol2-4 increased spontaneous mutation rates by factors of the order of 10² and 10¹, respectively, measured as URA3 forward mutation and his7-2 reversion. Surprisingly, a double mutant pol2-4 pol3-01 haploid was inviable. This was probably due to accumulation of unedited errors, since a pol2-4/pol2-4 pol3-01/pol3-01 diploid was viable, with the spontaneous his7-2 reversion rate increased by about 2 × 10³-fold. Analysis of mutation rates of double mutants indicated that the 3′ → 5′ exonucleases of DNA polymerases δ and ε can act competitively and that, like the 3′ → 5′ exonuclease of DNA polymerase δ the 3′ → 5′ exonuclease of DNA polymerase ε acts in series with the PMS1 mismatch correction system. Mutational spectra at a URA3 gene placed in both orientations near to a defined replication origin provided evidence that the 3′ → 5′ exonucleases of DNA polymerases δ and ε act on opposite DNA strands, but were in sufficient to distinguish conclusively between different models of DNA replication.