A DNA polymerase epsilon mutant that specifically causes +1 frameshift mutations within homonucleotide runs in yeast

The DNA polymerases delta and epsilon are the major replicative polymerases in the yeast Saccharomyces cerevisiae that possess 3' --> 5' exonuclease proofreading activity. Many errors arising during replication are corrected by these exonuclease activities. We have investigated the contributions of regions of Polepsilon other than the proofreading motifs to replication accuracy. An allele, pol2-C1089Y, was identified in a screen of Polepsilon mutants that in combination with an exonuclease I (exo1) mutation could cause a synergistic increase in mutations within homonucleotide runs. In contrast to other polymerase mutators, this allele specifically results in insertion frameshifts. When pol2-C1089Y was combined with deletions of EXO1 or RAD27 (homologue of human FEN1), mutation rates were increased for +1 frameshifts while there was almost no effect on -1 frameshifts. On the basis of genetic analysis, the pol2-C1089Y mutation did not cause a defect in proofreading. In combination with a deletion of the mismatch repair gene MSH2, the +1 frameshift mutation rate for a short homonucleotide run was increased nearly 100-fold whereas the -1 frameshift rate was unchanged. This suggests that the Pol2-C1089Y protein makes +1 frameshift errors during replication of homonucleotide runs and that these errors can be corrected by either mismatch repair (MMR) or proofreading (in short runs). This is the first report of a +1-specific mutator for homonucleotide runs in vivo. The pol2-C1089Y mutation defines a functionally important residue in Polepsilon.     

The 3'-->5' exonucleases of DNA polymerases delta and epsilon and the 5'-->3' exonuclease Exo1 have major roles in postreplication mutation avoidance in Saccharomyces cerevisiae

Replication fidelity is controlled by DNA polymerase proofreading and postreplication mismatch repair. We have genetically characterized the roles of the 5'-->3' Exo1 and the 3'-->5' DNA polymerase exonucleases in mismatch repair in the yeast Saccharomyces cerevisiae by using various genetic backgrounds and highly sensitive mutation detection systems that are based on long and short homonucleotide runs. Genetic interactions were examined among DNA polymerase epsilon (pol2-4) and delta (pol3-01) mutants defective in 3'-->5' proofreading exonuclease, mutants defective in the 5'-->3' exonuclease Exo1, and mismatch repair mutants (msh2, msh3, or msh6). These three exonucleases play an important role in mutation avoidance. Surprisingly, the mutation rate in an exo1 pol3-01 mutant was comparable to that in an msh2 pol3-01 mutant, suggesting that they participate directly in postreplication mismatch repair as well as in other DNA metabolic processes.     

Hypermutability of homonucleotide runs in mismatch repair and DNA polymerase proofreading yeast mutants.

Homonucleotide runs in coding sequences are hot spots for frameshift mutations and potential sources of genetic changes leading to cancer in humans having a mismatch repair defect. We examined frameshift mutations in homonucleotide runs of deoxyadenosines ranging from 4 to 14 bases at the same position in the LYS2 gene of the yeast Saccharomyces cerevisiae. In the msh2 mismatch repair mutant, runs of 9 to 14 deoxyadenosines are 1,700-fold to 51,000-fold, respectively, more mutable for single-nucleotide deletions than are runs of 4 deoxyadenosines. These frameshift mutations can account for up to 99% of all forward mutations inactivating the 4-kb LYS2 gene. Based on results with single and double mutations of the POL2 and MSH2 genes, both DNA polymerase epsilon proofreading and mismatch repair are efficient for short runs while only the mismatch repair system prevents frameshift mutations in runs of > or = 8 nucleotides. Therefore, coding sequences containing long homonucleotide runs are likely to be at risk for mutational inactivation in cells lacking mismatch repair capability.     

Fidelity of DNA polymerase epsilon holoenzyme from budding yeast Saccharomyces cerevisiae

DNA polymerases delta and epsilon (pol delta and epsilon) are the major replicative polymerases and possess 3'-5' proofreading exonuclease activities that correct errors arising during DNA replication in the yeast Saccharomyces cerevisiae. This study measures the fidelity of the holoenzyme of wild-type pol epsilon, the 3'-5' exonuclease-deficient pol2-4, a +1 frameshift mutator for homonucleotide runs, pol2C1089Y, and pol2C1089Y pol2-4 enzymes using a synthetic 30-mer primer/100-mer template. The nucleotide substitution rate for wild-type pol epsilon was 0.47 x 10(-5) for G:G mismatches, 0.15 x 10(-5) for T:G mismatches, and less than 0.01 x 10(-5) for A:G mismatches. The accuracy for A opposite G was not altered in the exonuclease-deficient pol2-4 pol epsilon; however, G:G and T:G misincorporation rates increased 40- and 73-fold, respectively. The pol2C1089Y pol epsilon mutant also exhibited increased G:G and T:G misincorporation rates, 22- and 10-fold, respectively, whereas A:G misincorporation did not differ from that of wild type. Since the fidelity of the double mutant pol2-4 pol2C1089Y was not greatly decreased, these results suggest that the proofreading 3'-5' exonuclease activity of pol2C1089Y pol epsilon is impaired even though it retains nuclease activity and the mutation is not in the known exonuclease domain.     

The DNA polymerase domain of pol(epsilon) is required for rapid,efficient, and highly accurate chromosomal DNA replication,telomere length maintenance,and normal cell senescence in Saccharomyces cerevisiae

Saccharomyces cerevisiae POL2 encodes the catalytic subunit of DNA polymerase epsilon. This study investigates the cellular functions performed by the polymerase domain of Pol2p and its role in DNA metabolism. The pol2-16 mutation has a deletion in the catalytic domain of DNA polymerase epsilon that eliminates its polymerase and exonuclease activities. It is a viable mutant, which displays temperature sensitivity for growth and a defect in elongation step of chromosomal DNA replication even at permissive temperatures. This mutation is synthetic lethal in combination with temperature-sensitive mutants or the 3'- to 5'-exonuclease-deficient mutant of DNA polymerase delta in a haploid cell. These results suggest that the catalytic activity of DNA polymerase epsilon participates in the same pathway as DNA polymerase delta, and this is consistent with the observation that DNA polymerases delta and epsilon colocalize in some punctate foci on yeast chromatids during S phase. The pol2-16 mutant senesces more rapidly than wild type strain and also has shorter telomeres. These results indicate that the DNA polymerase domain of Pol2p is required for rapid, efficient, and highly accurate chromosomal DNA replication in yeast.     

Isolation of thermotolerant mutants by using proofreading-deficient DNA polymerase delta as an effective mutator in Saccharomyces cerevisiae

Eukaryotic DNA polymerases delta and epsilon, both of which are required for chromosomal DNA replication, contain proofreading 3'-->5'exonuclease activity. DNA polymerases lacking proofreading activity act as strong mutators. Here we report isolation of thermotolerant mutants by using a proofreading-deficient DNA polymerase delta variant encoded by pol3-01 in the yeast Saccharomyces cerevisiae. The parental pol3-01 strain grew only poorly at temperatures higher than 38 degrees C. By stepwise elevation of the incubation temperature, thermotolerant mutants that could proliferate at 40 degrees C were successfully obtained; however, no such mutants were isolated with the isogenic POL3 strain. The recessive hot1-1 mutation was defined by genetic analysis of a weak thermotolerant mutant. Strong thermotolerance to 40 degrees C was attained by multiple mutations, at least one of which was recessive. These results indicate that a proofreading-deficient DNA delta polymerase variant is an effective mutator for obtaining yeast mutants that have gained useful characteristics, such as the ability to proliferate in harsh environments.     

Evidence from mutational specificity studies that yeast DNA polymerases delta and epsilon replicate different DNA strands at an intracellular replication fork

Although polymerases delta and epsilon are required for DNA replication in eukaryotic cells, whether each polymerase functions on a separate template strand remains an open question. To begin examining the relative intracellular roles of the two polymerases, we used a plasmid-borne yeast tRNA gene and yeast strains that are mutators due to the elimination of proofreading by DNA polymerases delta or epsilon. Inversion of the tRNA gene to change the sequence of the leading and lagging strand templates altered the specificities of both mutator polymerases, but in opposite directions. That is, the specificity of the polymerase delta mutator with the tRNA gene in one orientation bore similarities to the specificity of the polymerase epsilon mutator with the tRNA gene in the other orientation, and vice versa. We also obtained results consistent with gene orientation having a minor influence on mismatch correction of replication errors occurring in a wild-type strain. However, the data suggest that neither this effect nor differential replication fidelity was responsible for the mutational specificity changes observed in the proofreading-deficient mutants upon gene inversion. Collectively, the data argue that polymerases delta and epsilon each encounter a different template sequence upon inversion of the tRNA gene, and so replicate opposite strands at the plasmid DNA replication fork.     

Fidelity of mammalian DNA replication and replicative DNA polymerases.

Current models suggest that two or more DNA polymerases may be required for high-fidelity semiconservative DNA replication in eukaryotic cells. In the present study, we directly compare the fidelity of SV40 origin-dependent DNA replication in human cell extracts to the fidelity of mammalian DNA polymerases alpha, delta, and epsilon using lacZ alpha of M13mp2 as a reporter gene. Their fidelity, in decreasing order, is replication greater than or equal to pol epsilon greater than pol delta greater than pol alpha. DNA sequence analysis of mutants derived from extract reactions suggests that replication is accurate when considering single-base substitutions, single-base frameshifts, and larger deletions. The exonuclease-containing calf thymus DNA polymerase epsilon is also highly accurate. When high concentrations of deoxynucleoside triphosphates and deoxyguanosine monophosphate are included in the pol epsilon reaction, both base substitution and frameshift error rates increase. This response suggests that exonucleolytic proofreading contributes to the high base substitution and frameshift fidelity. Exonuclease-containing calf thymus DNA polymerase delta, which requires proliferating cell nuclear antigen for efficient synthesis, is significantly less accurate than pol epsilon. In contrast to pol epsilon, pol delta generates errors during synthesis at a relatively modest concentration of deoxynucleoside triphosphates (100 microM), and the error rate did not increase upon addition of adenosine monophosphate. Thus, we are as yet unable to demonstrate that exonucleolytic proofreading contributes to accuracy during synthesis by DNA polymerase delta. The four-subunit DNA polymerase alpha-primase complex from both HeLa cells and calf thymus is the least accurate replicative polymerase. Fidelity is similar whether the enzyme is assayed immediately after purification or after being stored frozen.(ABSTRACT TRUNCATED AT 250 WORDS)     

Division of labor at the eukaryotic replication fork

DNA polymerase delta (Pol delta) and DNA polymerase epsilon (Pol epsilon) are both required for efficient replication of the nuclear genome, yet the division of labor between these enzymes has remained unclear for many years. Here we investigate the contribution of Pol delta to replication of the leading and lagging strand templates in Saccharomyces cerevisiae using a mutant Pol delta allele (pol3-L612M) whose error rate is higher for one mismatch (e.g., T x dGTP) than for its complement (A x dCTP). We find that strand-specific mutation rates strongly depend on the orientation of a reporter gene relative to an adjacent replication origin, in a manner implying that >90% of Pol delta replication is performed using the lagging strand template. When combined with recent evidence implicating Pol epsilon in leading strand replication, these data support a model of the replication fork wherein the leading and lagging strand templates are primarily copied by Pol epsilon and Pol delta, respectively.     

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.     

Mutagenic DNA repair in Escherichia coli. XIII. Proofreading exonuclease of DNA polymerase III holoenzyme is not operational during UV mutagenesis

We have introduced a mutD5 mutation (which results in defective 3'-5'-exonuclease activity of the epsilon proofreading subunit of DNA polymerase III holoenzyme) into excision-defective Escherichia coli strains with varying SOS responses to UV light. MutD5 increased the spontaneous mutation frequency in all strains tested, including recA430, umuC122::Tn5, and umuC36 derivatives. It had no effect on UV mutability or immutability in any strain or on misincorporation revealed by delayed photoreversal in UV-irradiated umuC36, umuC122::Tn5, or recA430 bacteria. It is concluded that the epsilon proofreading subunit of DNA polymerase III holoenzyme is excluded, inhibited, or inoperative during misincorporation and mutagenesis after UV.     

Identification of a mutant DNA polymerase delta in Saccharomyces cerevisiae with an antimutator phenotype for frameshift mutations

We propose that a beta-turn-beta structure, which plays a critical role in exonucleolytic proofreading in the bacteriophage T4 DNA polymerase, is also present in the Saccharomyces cerevisiae DNA pol delta. Site-directed mutagenesis was used to test this proposal by introducing a mutation into the yeast POL3 gene in the region that encodes the putative beta-turn-beta structure. The mutant DNA pol delta has a serine substitution in place of glycine at position 447. DNA replication fidelity of the G447S-DNA pol delta was determined in vivo by using reversion and forward assays. An antimutator phenotype for frameshift mutations in short homopolymeric tracts was observed for the G447S-DNA pol delta in the absence of postreplication mismatch repair, which was produced by inactivation of the MSH2 gene. Because the G447S substitution reduced frameshift but not base substitution mutagenesis, some aspect of DNA polymerase proofreading appears to contribute to production of frameshifts. Possible roles of DNA polymerase proofreading in frameshift mutagenesis are discussed.     

An Escherichia coli dnaE mutation with suppressor activity toward mutator mutD5.

The Escherichia coli mutator mutD5 is a conditional mutator whose strength is moderate when the strain is growing in minimal medium but very strong when it is growing in rich medium. The primary defect of this strain resides in the dnaQ gene, which encodes the epsilon (exonucleolytic proofreading) subunit of the DNA polymerase III holoenzyme. In one of our mutD5 strains we discovered a mutation that suppressed the mutability of mutD5. Interestingly, the level of suppression was strong in minimal medium but weak in rich medium. The mutation was localized to the dnaE gene, which encodes the alpha (polymerase) subunit of the DNA polymerase III holoenzyme. This mutation, termed dnaE910, also conferred improved growth of the mutD5 strain and caused increased temperature sensitivity in both wild-type and dnaQ49 backgrounds. The reduction in mutator strength by dnaE910 was also observed when this allele was placed in a mutL, a mutT, or a dnaQ49 background. The results suggest that dnaE910 encodes an antimutator DNA polymerase whose effect might be mediated by improved insertion fidelity or by increased proofreading via its effect on the exonuclease activity.     

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.     

Isolation and characterization of mutants with deletions in dnaQ, the gene for the editing subunit of DNA polymerase III in Salmonella typhimurium.

dnaQ (mutD) encodes the editing exonuclease subunit (epsilon) of DNA polymerase III. Previously described mutations in dnaQ include dominant and recessive mutator alleles as well as leaky temperature-sensitive alleles. We describe the properties of strains bearing null mutations (deletion-substitution alleles) of this gene. Null mutants exhibited a growth defect as well as elevated spontaneous mutation. As a consequence of the poor growth of dnaQ mutants and their high mutation rate, these strains were replaced within single colonies by derivatives carrying an extragenic suppressor mutation that compensated the growth defect but apparently not the mutator effect. Sixteen independently derived suppressors mapped in the vicinity of dnaE, the gene for the polymerization subunit (alpha) of DNA polymerase III, and one suppressor that was sequenced encoded an altered alpha polypeptide. Partially purified DNA polymerase III containing this altered alpha subunit was active in polymerization assays. In addition to their dependence on a suppressor mutation affecting alpha, dnaQ mutants strictly required DNA polymerase I for viability. We argue from these data that in the absence of epsilon, DNA replication falters unless secondary mechanisms, including genetically coded alteration in the intrinsic replication capacity of alpha and increased use of DNA polymerase I, come into play. Thus, epsilon plays a role in DNA replication distinct from its known role in controlling spontaneous mutation frequency.     

DNA polymerases delta and epsilon are required for chromosomal replication in Saccharomyces cerevisiae.

Three DNA polymerases, alpha, delta, and epsilon are required for viability in Saccharomyces cerevisiae. We have investigated whether DNA polymerases epsilon and delta are required for DNA replication. Two temperature-sensitive mutations in the POL2 gene, encoding DNA polymerase epsilon, have been identified by using the plasmid shuffle technique. Alkaline sucrose gradient analysis of DNA synthesis products in the mutant strains shows that no chromosomal-size DNA is formed after shift of an asynchronous culture to the nonpermissive temperature. The only DNA synthesis observed is a reduced quantity of short DNA fragments. The DNA profiles of replication intermediates from these mutants are similar to those observed with DNA synthesized in mutants deficient in DNA polymerase alpha under the same conditions. The finding that DNA replication stops upon shift to the nonpermissive temperature in both DNA polymerase alpha- and DNA polymerase epsilon- deficient strains shows that both DNA polymerases are involved in elongation. By contrast, previous studies on pol3 mutants, deficient in DNA polymerase delta, suggested that there was considerable residual DNA synthesis at the nonpermissive temperature. We have reinvestigated the nature of DNA synthesis in pol3 mutants. We find that pol3 strains are defective in the synthesis of chromosomal-size DNA at the restrictive temperature after release from a hydroxyurea block. These results demonstrate that yeast DNA polymerase delta is also required at the replication fork.     

Saccharomyces cerevisiae DNA polymerase delta: high fidelity for base substitutions but lower fidelity for single- and multi-base deletions

Eukaryotic DNA polymerase delta (Pol delta) plays an essential role in replicating large nuclear genomes, a process that must be accurate to maintain stability over many generations. Based on kinetic studies of insertion of individual dNTPs opposite a template guanine, Pol delta is believed to have high selectivity for inserting correct nucleotides. This high selectivity, in conjunction with an intrinsic 3'-exonuclease activity, implies that Pol delta should have high base substitution fidelity. Here we demonstrate that the wild type Saccharomyces cerevisiae three-subunit Pol delta does indeed have high base substitution fidelity for the 12 possible base-base mismatches, producing on average less than 1.3 stable misincorporations/100,000 nucleotides polymerized. Measurements with exonuclease-deficient Pol delta confirm the high nucleotide selectivity of the polymerase and further indicate that proofreading enhances the base substitution fidelity of the wild type enzyme by at least 60-fold. However, Pol delta inefficiently proofreads single nucleotide deletion mismatches in homopolymeric runs, such that the error rate is 30 single nucleotide deletions/100,000 nucleotides polymerized. Moreover, wild type Pol delta frequently deletes larger numbers of nucleotides between distantly spaced direct repeats of three or more base pairs. Although wild type Pol delta and Pol epsilon both have high base substitution fidelity, Pol delta is much less accurate than Pol epsilon for deletions involving repetitive sequences. Thus, strand slippage during replication by wild type Pol delta may be a primary source of insertion and deletion mutagenesis in eukaryotic genomes.     

Replicative DNA polymerase defects in human cancers: Consequences,mechanisms, and implications for therapy

The fidelity of DNA replication relies on three error avoidance mechanisms acting in series: nucleotide selectivity of replicative DNA polymerases, exonucleolytic proofreading, and post-replicative DNA mismatch repair (MMR). MMR defects are well known to be associated with increased cancer incidence. Due to advances in DNA sequencing technologies, the past several years have witnessed a long-predicted discovery of replicative DNA polymerase defects in sporadic and hereditary human cancers. The polymerase mutations preferentially affect conserved amino acid residues in the exonuclease domain and occur in tumors with an extremely high mutation load. Thus, a concept has formed that defective proofreading of replication errors triggers the development of these tumors. Recent studies of the most common DNA polymerase variants, however, suggested that their pathogenicity may be determined by functional alterations other than loss of proofreading. In this review, we summarize our current understanding of the consequences of DNA polymerase mutations in cancers and the mechanisms of their mutator effects. We also discuss likely explanations for a high recurrence of some but not other polymerase variants and new ideas for therapeutic interventions emerging from the mechanistic studies.     

A strong mutator effect caused by an amino acid change in the alpha subunit of DNA polymerase III of Escherichia coli

Most potent mutators heretofore detected in Escherichia coli are associated with defects in epsilon subunit of DNA polymerase III, encoded by the dnaQ gene. To elucidate the role of the alpha subunit, the catalytic subunit of the polymerase, in maintaining the high fidelity of DNA replication, we isolated a mutator mutant, the mutation (dnaE173) of which resides on the dnaE gene, encoding the alpha subunit. The dnaE173 mutant was unable to grow in salt-free L broth at temperatures exceeding 44.5 degrees C and exhibited an increased frequency of spontaneous mutations, 1,000 to 10,000-fold the wild type level, at permissive temperatures. The mutator effect of dnaE173 mutation is dominant over the wild type allele. These phenotypes are caused by a single base substitution, resulting in one amino acid change, Glu612 (GAA)----Lys(AAA), in the alpha subunit molecule. DNA polymerase III purified from the dnaE173 mutant contained both alpha and epsilon subunits, in a normal molar ratio. We found no differences between wild type and mutant polymerases in the Vmax, thermolabilities, and salt sensitivities. However, the apparent Km for the substrate nucleotide of the mutant polymerase was 1/6 of that determined with the wild type polymerase. Although the mutant polymerase retained a normal level of 3'----5' exonuclease activity, the proofreading capacity determined by "turnover assay" was significantly lower in the mutant polymerase, as compared with findings in the normal enzyme. It seems likely that the enhanced mutability in the dnaE173 strain results from, at least in part, a defect in the editing function of DNA polymerase III, and further suggests that a portion of the alpha subunit in which the amino acid change resides may be important for the proper setting of the two subunits at the replication fork so as to facilitate efficient editing during the DNA replication.     

The extreme mutator effect of Escherichia coli mutD5 results from saturation of mismatch repair by excessive DNA replication errors.

Escherichia coli mutator mutD5 is the most potent mutator known. The mutD5 mutation resides in the dnaQ gene encoding the proofreading exonuclease of DNA polymerase III holoenzyme. It has recently been shown that the extreme mutability of this strain results, in addition to a proofreading defect, from a defect in mutH, L, S-encoded postreplicational DNA mismatch repair. The following measurements of the mismatch-repair capacity of mutD5 cells demonstrate that this mismatch-repair defect is not structural, but transient. mutD5 cells in early log phase are as deficient in mismatch repair as mutL cells, but they become as proficient as wild-type cells in late log phase. Second, arrest of chromosomal replication in a mutD5-dnaA(Ts) strain at a nonpermissive temperature restores mismatch repair, even from the early log phase of growth. Third, transformation of mutD5 strains with multicopy plasmids expressing the mutH or mutL gene restores mismatch repair, even in rapidly growing cells. These observations suggest that the mismatch-repair deficiency of mutD strains results from a saturation of the mutHLS-mismatch-repair system by an excess of primary DNA replication errors due to the proofreading defect.