Interacting fidelity defects in the replicative DNA polymerase of bacteriophage RB69

The DNA polymerases (gp43s) of the related bacteriophages T4 and RB69 are B family (polymerase alpha class) enzymes that determine the fidelity of phage DNA replication. A T4 whose gene 43 has been mutationally inactivated can be replicated by a cognate RB69 gp43 encoded by a recombinant plasmid in T4-infected Escherichia coli. We used this phage-plasmid complementation assay to obtain rapid and sensitive measurements of the mutational specificities of mutator derivatives of the RB69 enzyme. RB69 gp43s lacking proofreading function (Exo(-) enzymes) and/or substituted with alanine, serine, or threonine at the conserved polymerase function residue Tyr(567) (Pol(Y567(A/S/T)) enzymes) were examined for their effects on the reversion of specific mutations in the T4 rII gene and on forward mutation in the T4 rI gene. The results reveal that Tyr(567) is a key determinant of the fidelity of base selection and that the Pol and Exo functions are strongly coupled in this B family enzyme. In vitro assays show that the Pol(Y567A) Exo(-) enzyme generates mispairs more frequently but extends them less efficiently than does a Pol(+) Exo(-) enzyme. Other replicative DNA polymerases may control fidelity by strategies similar to those used by RB69 gp43.     

Processivity clamp gp45 and ssDNA-binding-protein gp32 modulate the fidelity of bacteriophage RB69 DNA polymerase in a sequence-specific manner, sometimes enhancing and sometimes compromising accuracy

Numerous studies of the impact of accessory proteins upon the fidelity of DNA synthesis have provided a complex and sometimes discordant picture. We previously described such an analysis conducted in vitro using various bacteriophage RB69 gp43 mutator DNA polymerases with or without the accessory proteins gp32 (which binds single-stranded DNA) plus gp45/44/62 (processivity clamp and its loaders). Mutations were scored at many sites in the lacZalpha mutation reporter sequence. Unexpectedly, the accessory proteins sometimes decreased and sometimes increased fidelity at a handful of specific sites. Here, we enlarge our analysis with one particular mutator polymerase compromised in both insertion accuracy and proofreading and also extend the analysis to reactions supplemented only with gp32 or only with gp45/44/62. An overall 1.56-fold increase in mutation frequencies was produced by adding single or multiple accessory proteins and was driven mainly by increased T(template)*G(primer) mispairs. Evidence was found for many additional sites where the accessory proteins influence fidelity, indicating the generality of the effect. Thus, accessory proteins contribute to the site-specific variability in mutation rates characteristically seen in mutational spectra.     

The roles of Tyr391 and Tyr619 in RB69 DNA polymerase replication fidelity

In the family-B DNA polymerase of bacteriophage RB69, the conserved aromatic palm-subdomain residues Tyr391 and Tyr619 interact with the last primer-template base-pair. Tyr619 interacts via a water-mediated hydrogen bond with the phosphate of the terminal primer nucleotide. The main-chain amide of Tyr391 interacts with the corresponding template nucleotide. A hydrogen bond has been postulated between Tyr391 and the hydroxyl group of Tyr567, a residue that plays a key role in base discrimination. This hydrogen bond may be crucial for forcing an infrequent Tyr567 rotamer conformation and, when the bond is removed, may influence fidelity. We investigated the roles of these residues in replication fidelity in vivo employing phage T4 rII reversion assays and an rI forward assay. Tyr391 was replaced by Phe, Met and Ala, and Tyr619 by Phe. The Y391A mutant, reported previously to decrease polymerase affinity for incoming nucleotides, was unable to support DNA replication in vivo, so we used an in vitro fidelity assay. Tyr391F/M replacements affect fidelity only slightly, implying that the bond with Tyr567 is not essential for fidelity. The Y391A enzyme has no mutator phenotype in vitro. The Y619F mutant displays a complex profile of impacts on fidelity but has almost the same mutational spectrum as the parental enzyme. The Y619F mutant displays reduced DNA binding, processivity, and exonuclease activity on single-stranded DNA and double-stranded DNA substrates. The Y619F substitution would disrupt the hydrogen bond network at the primer terminus and may affect the alignment of the 3' primer terminus at the polymerase active site, slowing chemistry and overall DNA synthesis.     

Steady-state kinetic characterization of RB69 DNA polymerase mutants that affect dNTP incorporation.

The function of six highly conserved residues (Arg482, Lys483, Lys486, Lys560, Asn564, and Tyr567) in the fingers domain of bacteriophage RB69 DNA polymerase (RB69 gp43) were analyzed by kinetic studies with mutants in which each of these residues was replaced with Ala. Our results suggest that Arg482, Lys486, Lys560, and Asn564 contact the incoming dNTP during the nucleotidyl transfer reaction as judged by variations in apparent Km and kcat values for dNTP incorporation by these mutants compared to those for the exonuclease deficient parental polymerase under steady-state conditions. On the basis of our studies, as well as on the basis of the crystal structure of RB69 gp43, we propose that a conformational change in the fingers domain, which presumably occurs prior to polymerization, brings the side chains of Arg482, Lys486, Lys560, and Asn564 into the vicinity of the primer-template terminus where they can contact the triphosphate moiety of the incoming dNTP. In particular, on the basis of structural studies reported for the "closed" forms of two other DNA polymerases and from the kinetic studies reported here, we suggest that (i) Lys560 and Asn564 contact the nonbonding oxygens of the alpha and beta phosphates, respectively, and (ii) both Arg482 and Lys486 contact the gamma phosphate oxygens of the incoming dNTP of RB69 gp43 prior to the nucleotidyl transfer reaction. We also found that Ala substitutions at each of these four RB69 gp43 sites could incorporate dGDP as a substrate, although with markedly reduced efficiency compared to that with dGTP. In contrast in the parental exo- background, the K483A and Y567A substituted enzymes could not use dGDP as a substrate for primer extension. These results, taken together, are consistent with the putative roles of the four conserved residues in RB69 gp43 as stated above.     

Reversal of a mutator activity by a nearby fidelity-neutral substitution in the RB69 DNA polymerase binding pocket

Phage RB69 B-family DNA polymerase is responsible for the overall high fidelity of RB69 DNA synthesis. Fidelity is compromised when conserved Tyr567, one of the residues that form the nascent polymerase base-pair binding pocket, is replaced by alanine. The Y567A mutator mutant has an enlarged binding pocket and can incorporate and extend mispairs efficiently. Ser565 is a nearby conserved residue that also contributes to the binding pocket, but a S565G replacement has only a small impact on DNA replication fidelity. When Y567A and S565G replacements were combined, mutator activity was strongly decreased compared to that with Y567A replacement alone. Analyses conducted both in vivo and in vitro revealed that, compared to Y567A replacement alone, the double mutant mainly reduced base substitution mutations and, to a lesser extent, frameshift mutations. The decrease in mutation rates was not due to increased exonuclease activity. Based on measurements of DNA binding affinity, mismatch insertion, and mismatch extension, we propose that the recovered fidelity of the double mutant may result, in part, from an increased dissociation of the enzyme from DNA, followed by the binding of the same or another polymerase molecule in either exonuclease mode or polymerase mode. An additional antimutagenic factor may be a structural alteration in the polymerase binding pocket described in this article.     

The high fidelity and unique error signature of human DNA polymerase epsilon

Bulk replicative DNA synthesis in eukaryotes is highly accurate and efficient, primarily because of two DNA polymerases (Pols): Pols δ and ε. The high fidelity of these enzymes is due to their intrinsic base selectivity and proofreading exonuclease activity which, when coupled with post-replication mismatch repair, helps to maintain human mutation rates at less than one mutation per genome duplication. Conditions that reduce polymerase fidelity result in increased mutagenesis and can lead to cancer in mice. Whereas yeast Pol ε has been well characterized, human Pol ε remains poorly understood. Here, we present the first report on the fidelity of human Pol ε. We find that human Pol ε carries out DNA synthesis with high fidelity, even in the absence of its 3'→5' exonucleolytic proofreading and is significantly more accurate than yeast Pol ε. Though its spectrum of errors is similar to that of yeast Pol ε, there are several notable exceptions. These include a preference of the human enzyme for T→A over A→T transversions. As compared with other replicative DNA polymerases, human Pol ε is particularly accurate when copying homonucleotide runs of 4-5 bases. The base pair substitution specificity and high fidelity for frameshift errors observed for human Pol ε are distinct from the errors made by human Pol δ.     

Protein determinants of RNA binding by DNA polymerase of the T4-related bacteriophage RB69

DNA polymerase (gp43) of phage T4 plays two biological roles, one as an essential DNA binding replication enzyme and the other as an mRNA-specific autogenous translational repressor. Binding of T4 gp43 to its mRNA target (translational operator RNA) interferes with gp43-DNA interactions, but it is unclear how the protein determinants for binding DNA are affected by the dynamics of gp43-mRNA interactions. We have used RB69 gp43, a natural variant of the T4 enzyme whose crystal structure has been determined to identify protein sites that respond to the interaction with specific RNA. We used protein phosphorylation markers, photocross-linking studies, protease sensitivity assays, and mutational analyses to examine the effects of operator RNA on the enzyme's five structural domains (N, exo, palm, fingers, and thumb). Our studies suggest that this RNA affects gp43-DNA interactions through global effects on protein structure that occlude DNA-binding sites but leave the enzyme accessible to interactions with the sliding clamp (RB69 gp45) and possibly other polymerase accessory proteins. We discuss the possible biological significance of putative RNA-binding motifs in the N and palm domains of RB69 gp43.     

Characterization of a replicative DNA polymerase mutant with reduced fidelity and increased translesion synthesis capacity

Changing a highly conserved amino acid in motif A of any of the four yeast family B DNA polymerases, DNA polymerase alpha, delta, epsilon or zeta, results in yeast strains with elevated mutation rates. In order to better understand this phenotype, we have performed structure-function studies of homologous mutants of RB69 DNA polymerase (RB69 pol), a structural model for family B members. When Leu415 in RB69 pol is replaced with phenylalanine or glycine, the mutant polymerases retain high-catalytic efficiency for correct nucleotide incorporation, yet have increased error rates due to increased misinsertion, increased mismatch extension and inefficient proofreading. The Leu415Phe mutant also has increased dNTP insertion efficiency opposite a template 8-oxoG and opposite an abasic site. The 2.5 A crystal structure of a ternary complex of RB69 L415F pol with a correctly base-paired incoming dTTP reveals that the phenylalanine ring is accommodated within a cavity seen in the wild-type enzyme, without steric clash or major change in active site geometry, consistent with retention of high-catalytic efficiency for correct incorporation. In addition, slight structural differences were observed that could be relevant to the reduced fidelity of L415F RB69 pol.     

Crystal structure of an archaebacterial DNA polymerase.

BACKGROUND: Members of the Pol II family of DNA polymerases are responsible for chromosomal replication in eukaryotes, and carry out highly processive DNA replication when attached to ring-shaped processivity clamps. The sequences of Pol II polymerases are distinct from those of members of the well-studied Pol I family of DNA polymerases. The DNA polymerase from the archaebacterium Desulfurococcus strain Tok (D. Tok Pol) is a member of the Pol II family that retains catalytic activity at elevated temperatures. RESULTS: The crystal structure of D. Tok Pol has been determined at 2.4 A resolution. The architecture of this Pol II type DNA polymerase resembles that of the DNA polymerase from the bacteriophage RB69, with which it shares less than approximately 20% sequence identity. As in RB69, the central catalytic region of the DNA polymerase is located within the 'palm' subdomain and is strikingly similar in structure to the corresponding regions of Pol I type DNA polymerases. The structural scaffold that surrounds the catalytic core in D. Tok Pol is unrelated in structure to that of Pol I type polymerases. The 3'-5' proofreading exonuclease domain of D. Tok Pol resembles the corresponding domains of RB69 Pol and Pol I type DNA polymerases. The exonuclease domain in D. Tok Pol is located in the same position relative to the polymerase domain as seen in RB69, and on the opposite side of the palm subdomain compared to its location in Pol I type polymerases. The N-terminal domain of D. Tok Pol has structural similarity to RNA-binding domains. Sequence alignments suggest that this domain is conserved in the eukaryotic DNA polymerases delta and epsilon. CONCLUSIONS: The structure of D. Tok Pol confirms that the modes of binding of the template and extrusion of newly synthesized duplex DNA are likely to be similar in both Pol II and Pol I type DNA polymerases. However, the mechanism by which the newly synthesized product transits in and out of the proofreading exonuclease domain has to be quite different. The discovery of a domain that seems to be an RNA-binding module raises the possibility that Pol II family members interact with RNA.     

DNA polymerase II as a fidelity factor in chromosomal DNA synthesis in Escherichia coli

Escherichia coli DNA polymerase III holoenzyme (HE) is the main replicase responsible for replication of the bacterial chromosome. E. coli contains four additional polymerases, and it is a relevant question whether these might also contribute to chromosomal replication and its fidelity. Here, we have investigated the role of DNA polymerase II (Pol II) (polB gene product). Mismatch repair-defective strains containing the polBex1 allele--encoding a polymerase-proficient but exonucleolytically defective Pol II--displayed a mutator activity for four different chromosomal lac mutational markers. The mutator effect was dependent on the chromosomal orientation of the lacZ gene. The results indicate that Pol II plays a role in chromosomal replication and that its role is not equal in leading- versus lagging-strand replication. In particular, the role of Pol II appeared larger in the lagging strand. When combined with dnaQ or dnaE mutator alleles, polBex1 showed strong, near multiplicative effects. The results fit a model in which Pol II acts as proofreader for HE-produced misinsertion errors. A second role of Pol II is to protect mismatched 3' termini against the mutagenic action of polymerase IV (dinB product). Overall, Pol II may be considered a main player in the polymerase trafficking at the replication fork.     

Mutational clusters generated by non-processive polymerases: A case study using DNA polymerase β in vitro

Available DNA mutational spectra reveal that the number of mutants with multiple mutations (“multiples”) is usually greater than expected from a random distribution of mutations among mutants. These overloads imply the occurrence of non-random clusters of mutations, probably generated during episodes of low-fidelity DNA synthesis. Excess multiples have been reported not only for viruses, bacteria, and eukaryotic cells but also for the DNA polymerases of phages T4 and RB69 in vitro. In the simplest case of a purified polymerase, non-random clusters may be generated by a subfraction of phenotypic variants able to introduce more errors per cycle of DNA synthesis than the normal enzyme. According to this hypothesis, excess multiples are not expected with non-processive polymerases even if they harbor rare mutator variants. DNA polymerase β (Pol β) is a mammalian DNA-repair polymerase with very low processivity. Although several Pol β mutational spectra have been described, there is conflicting evidence on whether or not excess multiples occur, with spectra based on the HSV-tk system tending to show excess multiples. Excess multiples generated by Pol β or any of its mutants might imply that the excesses of multiples observed in numerous other systems, especially those with processive polymerases, could be artifactual. Here, the distributions of mutations generated by native and recombinant rat Pol β and by the Pol β^Y265C mutator were analyzed in the M13mp2 lacZα system. Our results present no evidence for a significant excess of multiples over the expected numbers with any of the Pol β enzymes tested in this system. The reported excess of Pol β-generated multiples in the HSV-tk system may reflect a reduced efficiency of detection of base substitutions that cause weak phenotypes, which in turn may artifactually increase the frequency of multiples.     

Mutator suppression and escape from replication error-induced extinction in yeast

Cells rely on a network of conserved pathways to govern DNA replication fidelity. Loss of polymerase proofreading or mismatch repair elevates spontaneous mutation and facilitates cellular adaptation. However, double mutants are inviable, suggesting that extreme mutation rates exceed an error threshold. Here we combine alleles that affect DNA polymerase δ (Pol δ) proofreading and mismatch repair to define the maximal error rate in haploid yeast and to characterize genetic suppressors of mutator phenotypes. We show that populations tolerate mutation rates 1,000-fold above wild-type levels but collapse when the rate exceeds 10⁻³ inactivating mutations per gene per cell division. Variants that escape this error-induced extinction (eex) rapidly emerge from mutator clones. One-third of the escape mutants result from second-site changes in Pol δ that suppress the proofreading-deficient phenotype, while two-thirds are extragenic. The structural locations of the Pol δ changes suggest multiple antimutator mechanisms. Our studies reveal the transient nature of eukaryotic mutators and show that mutator phenotypes are readily suppressed by genetic adaptation. This has implications for the role of mutator phenotypes in cancer.     

The L561A substitution in the nascent base-pair binding pocket of RB69 DNA polymerase reduces base discrimination

Several variants of RB69 DNA polymerase (RB69 pol) with single-site replacements in the nascent base-pair binding pocket are less discriminating with respect to noncomplementary dNMP incorporation than the wild-type enzyme. To quantify the loss in base selectivity, we determined the transient-state kinetic parameters for incorporation of correct and all combinations of incorrect dNMPs by the exonuclease-deficient form of one of these RB69 pol variants, L561A, using rapid chemical quench assays. The L561A variant did not significantly alter the k(pol) and K(D) values for incorporation of correct dNMPs, but it showed increased incorporation efficiency (k(pol)/K(D)) for mispaired bases relative to the wild-type enzyme. The incorporation efficiency for mispaired bases by the L561A variant ranged from 1.5 x 10(-)(5) microM(-)(1) s(-)(1) for dCMP opposite templating C to 2 x 10(-)(3) microM(-)(1) s(-)(1) for dAMP opposite templating C. These k(pol)/K(D) values are 3-60-fold greater than those observed with the wild-type enzyme. The effect of the L561A replacement on the mutation frequency in vivo was determined by infecting Escherichia coli harboring a plasmid encoding the L561A variant of RB69 pol with T4 phage bearing a mutant rII locus, and the rates of reversions to rII(+) were scored. The exonuclease-proficient RB69 pol L561A displayed a weak mutator phenotype. In contrast, no progeny phage were produced after infection of E. coli, expressing an exonuclease-deficient RB69 pol L561A, with either mutant or wild-type T4 phage. This dominant-lethal phenotype was attributed to error catastrophe caused by the high rate of mutation expected from combining the pol L561A and exo(-) mutator activities.     

Autogenous translational operator recognized by bacteriophage T4 DNA polymerase

The synthesis of the DNA polymerase of bacteriophage T4 is autogenously regulated. This protein (gp43), the product of gene 43, binds to a segment of its mRNA that overlaps its ribosome binding site, and thereby blocks translation. We have determined the Kd of the gp43-operator interaction to be 1.0 x 10(-9) M. The minimum operator sequence to which gp43 binds consists of 36 nucleotides that include a hairpin (containing a 5 base-pair helix and an 8 nucleotide loop) and a single-stranded segment that contains the Shine-Dalgarno sequence of the ribosome binding site. In the distantly related bacteriophage RB69 there is a remarkable conservation of this hairpin and loop sequence at the ribosome binding site of its DNA polymerase gene. We have constructed phage operator mutants that overproduce gp43 in vivo, yet are unchanged for in vivo replication rates and phage yield. We present data that show that the replicative and autoregulatory functions are mutually exclusive activities of this polymerase, and suggest a model for gp43 synthesis that links autoregulation to replicative demand.     

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.     

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.     

Mutator effects of overproducing DNA polymerase eta (Rad30) and its catalytically inactive variant in yeast

DNA polymerase eta synthesizes DNA in vitro with low fidelity. Based on this, here we report the effects of deletion or increased expression of yeast RAD30 gene, encoding for polymerase eta (Pol eta), on spontaneous mutagenesis in vivo. Deletion of RAD30 did not affect spontaneous mutagenesis. Overproduction of Rad30p was slightly mutagenic in a wild-type yeast strain and moderately mutagenic in strains with inactive 3'-->5'-exonuclease of DNA polymerase epsilon or DNA mismatch repair. These data suggest that excess Rad30p reduces replication fidelity in vivo and that the induced errors may be corrected by exonucleolytic proofreading and DNA mismatch repair. However, the magnitude of mutator effect (only up to 10-fold) suggests that the replication fork is protected from inaccurate synthesis by Pol eta in the absence of DNA damage. Overproduction of catalytically inactive Rad30p was also mutagenic, suggesting that much of the mutator effect results from indirect perturbation of replication rather than from direct misincorporation by Pol eta. Moreover, while excess wild-type Pol eta primarily induced base substitutions in the msh6 and pms1 strains, excess inactive Rad30p induced both base substitutions and frameshifts. This suggests that more than one mutagenic mechanism is operating when RAD30 is overexpressed.     

Unique error signature of the four-subunit yeast DNA polymerase epsilon

We have purified wild type and exonuclease-deficient four-subunit DNA polymerase epsilon (Pol epsilon) complex from Saccharomyces cerevisiae and analyzed the fidelity of DNA synthesis by the two enzymes. Wild type Pol epsilon synthesizes DNA accurately, generating single-base substitutions and deletions at average error rates of 5' exonuclease activity is less accurate to a degree suggesting that wild type Pol epsilon proofreads at least 92% of base substitution errors and at least 99% of frameshift errors made by the polymerase. Surprisingly the base substitution fidelity of exonuclease-deficient Pol epsilon is severalfold lower than that of proofreading-deficient forms of other replicative polymerases. Moreover the spectrum of errors shows a feature not seen with other A, B, C, or X family polymerases: a high proportion of transversions resulting from T.dTTP, T.dCTP, and C.dTTP mispairs. This unique error specificity and amino acid sequence alignments suggest that the structure of the polymerase active site of Pol epsilon differs from those of other B family members. We observed both similarities and differences between the spectrum of substitutions generated by proofreading-deficient Pol epsilon in vitro and substitutions occurring in vivo in a yeast strain defective in Pol epsilon proofreading and DNA mismatch repair. We discuss the implications of these findings for the role of Pol epsilon polymerase activity in DNA replication.     

Increased rates of genomic deletions generated by mutations in the yeast gene encoding DNA polymerase delta or by decreases in the cellular levels of DNA polymerase delta

In Saccharomyces cerevisiae, POL3 encodes the catalytic subunit of DNA polymerase delta. While yeast POL3 mutant strains that lack the proofreading exonuclease activity of the polymerase have a strong mutator phenotype, little is known regarding the role of other Pol3p domains in mutation avoidance. We identified a number of pol3 mutations in regions outside of the exonuclease domain that have a mutator phenotype, substantially elevating the frequency of deletions. These deletions appear to reflect an increased frequency of DNA polymerase slippage. In addition, we demonstrate that reduction in the level of wild-type DNA polymerase results in a similar mutator phenotype. Lowered levels of DNA polymerase also result in increased sensitivity to the DNA-damaging agent methyl methane sulfonate. We conclude that both the quantity and the quality of DNA polymerase delta is important in ensuring genome stability.     

Antimutator variants of DNA polymerases

Evolution balances DNA replication speed and accuracy to optimize replicative fitness and genetic stability. There is no selective pressure to improve DNA replication fidelity beyond the background mutation rate from other sources, such as DNA damage. However, DNA polymerases remain amenable to amino acid substitutions that lower intrinsic error rates. Here, we review these ‘antimutagenic’ changes in DNA polymerases and discuss what they reveal about mechanisms of replication fidelity. Pioneering studies with bacteriophage T4 DNA polymerase (T4 Pol) established the paradigm that antimutator amino acid substitutions reduce replication errors by increasing proofreading efficiency at the expense of polymerase processivity. The discoveries of antimutator substitutions in proofreading-deficient ‘mutator’ derivatives of bacterial Pols I and III and yeast Pol δ suggest there must be additional antimutagenic mechanisms. Remarkably, many of the affected amino acid positions from Pol I, Pol III, and Pol δ are similar to the original T4 Pol substitutions. The locations of antimutator substitutions within DNA polymerase structures suggest that they may increase nucleotide selectivity and/or promote dissociation of primer termini from polymerases poised for misincorporation, leading to expulsion of incorrect nucleotides. If misincorporation occurs, enhanced primer dissociation from polymerase domains may improve proofreading in cis by an intrinsic exonuclease or in trans by alternate cellular proofreading activities. Together, these studies reveal that natural selection can readily restore replication error rates to sustainable levels following an adaptive mutator phenotype.