Evidence for interplay among yeast replicative DNA polymerases alpha, delta and epsilon from studies of exonuclease and polymerase active site mutations

Background  

DNA polymerase ε (Pol ε) is essential for S-phase replication, DNA damage repair and checkpoint control in yeast. A pol2-Y831A mutation leading to a tyrosine to alanine change in the Pol ε active site does not cause growth defects and confers a mutator phenotype that is normally subtle but strong in a mismatch repair-deficient strain. Here we investigate the mechanism responsible for the mutator effect.     

Biochemical and functional comparison of DNA polymerases alpha, delta, and epsilon from calf thymus.

DNA polymerase alpha, delta and epsilon can be isolated simultaneously from calf thymus. DNA polymerase delta was purified to apparent homogeneity by a four-column procedure including DEAE-Sephacel, phenyl-Sepharose, phosphocellulose, and hydroxylapatite, yielding two polypeptides of 125 and 48 kDa, respectively. On hydroxylapatite DNA polymerase delta can completely be separated from DNA polymerase epsilon. By KCl DNA polymerase delta is eluted first, while addition of potassium phosphate elutes DNA polymerase epsilon. DNA polymerases delta and epsilon could be distinguished from DNA polymerase alpha by their (i) resistance to the monoclonal antibody SJK 132-20, (ii) relative resistance to N2-[p-(n-butyl)phenyl]-2-deoxyguanosine triphosphate and 2-[p-(n-butyl)anilino]-2-deoxyadenosine triphosphate, (iii) presence of a 3'----5' exonuclease, (iv) polypeptide composition, (v) template requirements, (vi) processivities on the homopolymer poly(dA)/oligo(dT12-18), and (vii) lack of primase. The following differences of DNA polymerase delta to DNA polymerase epsilon were evident: (i) the independence of DNA polymerase epsilon to proliferating cell nuclear antigen for processivity, (ii) utilization of deoxy- and ribonucleotide primers, (iii) template requirements in the absence of proliferating cell nuclear antigen, (iv) mode of elution from hydroxylapatite, and (v) sensitivity to d2TTP and to dimethyl sulfoxide. Both enzymes contain a 3'----5' exonuclease, but are devoid of endonuclease, RNase H, DNA helicase, DNA dependent ATPase, DNA primase, and poly(ADP-ribose) polymerase. DNA polymerase delta is 100-150 fold dependent on proliferating cell nuclear antigen for activity and processivity on poly(dA)/oligo(dT12-18) at base ratios between 1:1 to 100:1. The activity of DNA polymerase delta requires an acidic pH of 6.5 and is also found on poly(dT)/oligo(dA12-18) and on poly(dT)/oligo(A12-18) but not on 10 other templates tested. All three DNA polymerases can be classified according to the revised nomenclature for eukaryotic DNA polymerases (Burgers, P.M. J., Bambara, R. A., Campbell, J. L., Chang, L. M. S., Downey, K. M., Hübscher, U., Lee, M. Y. W. T., Linn, S. M., So, A. G., and Spadari, S. (1990) Eur. J. Biochem. 191, 617-618).     

Telomerase-mediated telomere addition in vivo requires DNA primase and DNA polymerases alpha and delta

To better understand the requirements for telomerase-mediated telomere addition in vivo, we developed an assay in S. cerevisiae that creates a chromosome end immediately adjacent to a short telomeric DNA tract. The de novo end acts as a telomere: it is protected from degradation in a CDC13-dependent manner, telomeric sequences are added efficiently, and addition occurs at a faster rate in mutant strains that have long telomeres. Telomere addition was detected in M phase arrested cells, which permitted us to determine that the essential DNA polymerases alpha and delta and DNA primase were required. This indicates that telomeric DNA synthesis by telomerase is tightly coregulated with the production of the opposite strand. Such coordination prevents telomerase from generating excessively long single-stranded tails, which may be deleterious to chromosome stability in S. cerevisiae.     

Interactions of azidothymidine triphosphate with the cellular DNA polymerases alpha, delta, and epsilon and with DNA primase.

The interactions of azidothymidine triphosphate, the metabolically active form of the anti-AIDS drug azidothymidine (zidovudine), with the cellular DNA polymerases alpha, delta, and epsilon, as well as with the RNA primer-forming enzyme DNA primase were studied in vitro. DNA polymerase alpha was shown to incorporate azidothymidine monophosphate into a growing polynucleotide chain. This occurred 2000-fold slower than the incorporation of natural dTTP. Despite the ability of polymerase alpha to use azidothymidine triphosphate as an alternate substrate, this compound was only marginally inhibitory to the enzyme (Ki greater than 1 mM). Furthermore, the DNA primase activity associated with DNA polymerase alpha was barely inhibited by azidothymidine triphosphate (Ki greater than 1 mM). Inhibition was more pronounced for DNA polymerases delta and epsilon. The type of inhibition was competitive with respect to dTTP, with Ki values of 250 and 320 microM, respectively. No incorporation of azidothymidine monophosphate was detectable with these two DNA polymerases because their associated 3'- to 5'-exonuclease activities degraded primer molecules prior to any measurable elongation. Template-primer systems with a preformed 3'-azidothymidine-containing primer terminus inhibited the three replicative polymerases rather potently. DNA polymerase alpha was inhibited with a Ki of 150 nM and polymerases delta and epsilon with Ki values of 25 and 20 nM, respectively. The type of inhibition was competitive with respect to the unmodified substrate poly(dA).oligo(dT) for all DNA polymerases tested. Performed 3'-azidothymidine-containing primers hybridized to poly(dA) were rather resistant to degradation by the 3'- to 5'-exonuclease of DNA polymerases epsilon and more susceptible to the analogous activity that copurified with DNA polymerase delta. It is proposed that the repair of 3'-azidothymidine-containing primers might become rate-limiting for the process of DNA replication in cells that have been treated with azidothymidine triphosphate.     

Differential inhibitors of DNA polymerases alpha and delta

DNA polymerases alpha and delta from bone marrow are similar in many respects, the major known difference being the exonuclease activity of delta. Differential inhibitors of alpha and delta have been sought to assist in their functional and physical separation. Butylphenyl deoxyguanosine triphosphate is one. It effectively inhibits alpha at less than 1 microM concentration, whereas more than 100 microM is required to similarly inhibit delta. Another is the monoclonal antibody, SJK 132-20, which neutralizes the polymerase activity of alpha but not delta. These differential inhibitors further define alpha and delta as separate categories of eukaryotic DNA polymerase and promise to facilitate the study of both.     

The essential DNA polymerases delta and epsilon are involved in repair of UV-damaged DNA in the yeast Saccharomyces cerevisiae.

We have studied the ability of yeast DNA polymerases to carry out repair of lesions caused by UV irradiation in Saccharomyces cerevisiae. By the analysis of postirradiation relative molecular mass changes in cellular DNA of different DNA polymerases mutant strains, it was established that mutations in DNA polymerases delta and epsilon showed accumulation of single-strand breaks indicating defective repair. Mutations in other DNA polymerase genes exhibited no defects in DNA repair. Thus, the data obtained suggest that DNA polymerases delta and epsilon are both necessary for DNA replication and for repair of lesions caused by UV irradiation. The results are discussed in the light of current concepts concerning the specificity of DNA polymerases in DNA repair.     

Lagging strand DNA synthesis by calf thymus DNA polymerases alpha, beta, delta and epsilon in the presence of auxiliary proteins.

By using a defined gapped DNA substrate that mimics a lagging strand of 230 nucleotides and that contains a defined pause site, we have analyzed calf thymus DNA polymerases (pol) alpha, beta, delta, and epsilon in the presence of the three auxiliary proteins proliferating cell nuclear antigen (PCNA), replication factor C (RF-C) and replication protein A (RP-A) for their ability to complete an Okazaki fragment. Pol alpha alone could fill the gap to near completion, but was strongly stopped by the pause site. Addition of low amounts of RP-A resulted in an increased synthesis by pol alpha past the pause site. In contrast, high amounts of RP-A strongly inhibited gap filling by pol alpha. Further inhibition was evident when the two other auxiliary proteins, PCNA and RF-C, were added in addition to RP-A. Pol beta could completely fill the gap without specific pausing and also was strongly inhibited by RP-A. PCNA and RF-C had no detectable effect on pol beta. Pol delta, relied as expected, on all three auxiliary proteins for complete gap filling synthesis and could, upon longer incubation, perform a limited amount of strand displacement synthesis. Pol epsilon core enzyme was able to fill the gap completely, but like pol alpha, essentially stopped at the pause site. This pausing could only be overcome upon addition of PCNA, RF-C and E. coli single-stranded DNA binding protein. Thus pol epsilon holoenzyme preferentially synthesized to the end of the gap without pausing. Ligation of the DNA products indicated that pol beta core enzyme, pol delta and pol epsilon holoenzymes (but not pol alpha and pol epsilon core enzyme) synthesized products that were easily ligatable. Our results indicate that pol epsilon holoenzyme fills a defined lagging strand gapped template to exact completion and is able to pass a pause site. The data favour the hypothesis of Burgers (Burgers, P.M.J. (1991) J. Biol. Chem. 266, 22698-22706) that pol epsilon might be a candidate for the second replication enzyme at the lagging strand of the replication fork.     

In vitro gap-directed translesion DNA synthesis of an abasic site involving human DNA polymerases epsilon, lambda, and beta

DNA polymerase (pol) ε is thought to be the leading strand replicase in eukaryotes, whereas pols λ and β are believed to be mainly involved in re-synthesis steps of DNA repair. DNA elongation by the human pol ε is halted by an abasic site (apurinic/apyrimidinic (AP) site). In this study, we present in vitro evidence that human pols λ, β, and η can perform translesion synthesis (TLS) of an AP site in the presence of pol ε, likely by initiating the 3'OHs created at the lesion by the arrested pol ε. However, in the case of pols λ and β, this TLS requires the presence of a DNA gap downstream from the product synthesized by the pol ε, and the optimal gap for efficient TLS is different for the two polymerases. The presence of gaps did not affect the TLS capacity of human pol η. Characterization of the reaction products showed that pol β inserted dAMP opposite the AP site, whereas gap filling synthesis by pol λ resulted in single or double deletions opposite the lesion. The synthesis up to the AP site by pol ε and the subsequent TLS by pols λ and β are not influenced by human processivity factor proliferating cell nuclear antigen and human single-stranded DNA-binding protein replication protein A. The bypass capacity of pol λ at the AP site is greatly reduced when a truncated form of the enzyme, which has lost the BRCA1 C-terminal and proline-rich domains, is used. Collectively, our in vitro results support the existence of a mechanism of gap-directed TLS at an AP site involving a switch between the replicative pol ε and the repair pols λ and β.     

DNA polymerases alpha and delta are immunologically and structurally distinct

The relationship between DNA polymerases alpha and delta are evaluated immunologically by monoclonal antibody specifically against DNA polymerase alpha and murine polyclonal antiserum against calf thymus DNA polymerase delta. DNA polymerases alpha and delta are found to be immunologically distinct. The structural relationship between the proliferating cell nuclear antigen (PCNA)-dependent calf DNA polymerase delta and DNA polymerase alpha from human and calf was analyzed by two-dimensional tryptic peptide mapping of the catalytic polypeptides. The results demonstrate that the catalytic polypeptides of the PCNA-dependent calf polymerase delta and DNA polymerase alpha are distinct, unrelated, and do not share any common structural determinants. The immunological and structural relationship between a recently identified PCNA-independent form of DNA polymerase delta from HeLa cells was also assessed. This PCNA-independent human polymerase delta was found to be immunologically unrelated to human polymerase alpha but to share some immunological and structural determinants with the PCNA-dependent calf thymus polymerase delta.     

Replication of single-stranded porcine circovirus DNA by DNA polymerases alpha and delta

Porcine circovirus is the only mammalian DNA virus so far known to contain a single-stranded circular genome (Tischer et al. (1982) Nature 295, 64-66). Replication of its small viral DNA (1.76 kb) appears to be dependent on cellular enzymes expressed during S-phase of the cell cycle (Tischer et al. (1987) Arch. Virol. 96, 39-57). In this paper we have exploited the porcine circovirus genome to probe for in vitro initiation and elongation of DNA replication by different preparations of calf thymus DNA polymerase alpha and delta as well as by a partially purified preparation from pig thymus. The results indicated that three different purification fractions of calf thymus DNA polymerase alpha and one from pig thymus initiate DNA synthesis at several sites on the porcine circovirus DNA. It appears that the sites at which DNA primase synthesizes primers are not entirely random. Subsequent DNA elongation by a highly purified DNA polymerase alpha holoenzyme which had been isolated by the criterion of replicating single-stranded M13 DNA (Ottiger et al. (1987) Nucleic Acids Res. 15, 4789-4807) is very efficient. Complete conversion to the double-stranded form is obtained in less than 1 min. When the DNA synthesis by DNA polymerase alpha is blocked with the DNA polymerase alpha specific monoclonal antibody SJK 132-20 after initiation by DNA primase, DNA polymerase delta can efficiently replicate from the primers. This in vitro DNA replication system may be used in analogy to the bacteriophage systems in E. coli to study initiation and elongation of DNA replication.     

An inhibitor of DNA polymerases alpha and delta in calf thymus DNA.

Most, although not all, samples of commercial calf thymus DNA were strongly inhibitory to DNA polymerase alpha; the inhibition made the DNA useless as a template for this enzyme. In a pre-assembled DNA polymerase assay mixture (minus enzyme but including activated DNA) the inhibition tended to diminish with time but at a rate that was not predictable, and some inhibition usually persisted. It was concluded that the inhibition was the result of contamination of the DNA by a heparin-like material on the basis of the following: 1) the inhibition could be reversed by treatment of the DNA with heparinase; 2) both the endogenous inhibitory effect of calf thymus DNA as well as the inhibitory effect of heparin on DNA polymerase alpha are reversed by protamine (which is known to prevent the antithrombin activity of heparin); 3) both the endogenous inhibition and inhibition by heparin are also reversed by ampholyte (which also prevents the antithrombin activity of heparin); and 4) both the endogenous and the heparin-induced inhibitory effects display the same spectrum of activity against mammalian DNA polymerases, i.e. both DNA polymerases alpha and delta are extremely sensitive whereas, DNA polymerases beta and gamma are resistant. The last result also suggests the use of heparin as a specific inhibitor of purified mammalian DNA polymerases alpha and delta, similar to the use of aphidicolin.     

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.     

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.     

Dpb11 controls the association between DNA polymerases alpha and epsilon and the autonomously replicating sequence region of budding yeast

Dpb11 is required for chromosomal DNA replication and the S-phase checkpoint in Saccharomyces cerevisiae. Here, we report detection of a physical complex containing Dpb11 and DNA polymerase epsilon (Dpb11-Polepsilon complex). During the S phase of the cell cycle, Dpb11 associated preferentially with DNA fragments containing autonomously replicating sequences (ARSs), at the same time as Polepsilon associated with these fragments. Association of Dpb11 and Polepsilon with these fragments was mutually dependent, suggesting that the Dpb11-Polepsilon complex associates with the ARS. Moreover, Dpb11 was required for the association of Polalpha-primase with the fragments. Thus, it seems likely that association of the Dpb11-Polepsilon complex with the ARS fragments is required for the association of the Polalpha-primase complex. Hydroxyurea inhibits late-origin firing in S. cerevisiae, and the checkpoint genes, RAD53 and MEC1, are involved in this inhibition. In the presence of hydroxyurea at temperatures permissive for cell growth, Polepsilon in dpb11-1 cells associated with early- and late-origin fragments. In wild-type cells, however, it associated only with early-origin fragments. This indicates that Dpb11 may also be involved in the regulation of late-origin firing. Overall, these results suggest that Dpb11 controls the association between DNA polymerases alpha and epsilon and the ARS.     

Calf thymus DNA polymerases alpha and delta are capable of highly processive DNA synthesis

We have demonstrated that calf thymus DNA polymerases alpha and delta are capable of highly processive DNA synthesis. Processivity values between 300 and 2000 nucleotides were observed when poly(dA)-oligo(dT) or singly primed single-stranded circular bacteriophage M13 DNA at pH 6.0 and 1 mM magnesium chloride was used. These conditions do not correlate with conditions, pH 7.0 and 5 mM magnesium chloride, that support the maximum synthetic rate. Lowering the pH and magnesium concentration lowers the Km value of the reaction with respect to primer terminus concentration. Furthermore, under these same conditions, both polymerases become insensitive to dissociation from the template as a result of encountering the 5' ends of primers. Overall, these results suggest that the affinity of the polymerases for the primer termini is higher throughout the polymerization reaction of pH and magnesium concentrations are lowered from those favoring maximum synthetic rate. Experiments with short primer templates, however, indicate that this higher affinity does not cause the DNA polymerase to remain stably bound after synthesizing up to the end of the template.     

DNA repair synthesis during base excision repair in vitro is catalyzed by DNA polymerase epsilon and is influenced by DNA polymerases alpha and delta in Saccharomyces cerevisiae.

Base excision repair is an important mechanism for correcting DNA damage produced by many physical and chemical agents. We have examined the effects of the REV3 gene and the DNA polymerase genes POL1, POL2, and POL3 of Saccharomyces cerevisiae on DNA repair synthesis is nuclear extracts. Deletional inactivation of REV3 did not affect repair synthesis in the base excision repair pathway. Repair synthesis in nuclear extracts of pol1, pol2, and pol3 temperature-sensitive mutants was normal at permissive temperatures. However, repair synthesis in pol2 nuclear extracts was defective at the restrictive temperature of 37 degrees C and could be complemented by the addition of purified yeast DNA polymerase epsilon. Repair synthesis in pol1 nuclear extracts was proficient at the restrictive temperature unless DNA polymerase alpha was inactivated prior to the initiation of DNA repair. Thermal inactivation of DNA polymerase delta in pol3 nuclear extracts enhanced DNA repair synthesis approximately 2-fold, an effect which could be specifically reversed by the addition of purified yeast DNA polymerase delta to the extract. These results demonstrate that DNA repair synthesis in the yeast base excision repair pathway is catalyzed by DNA polymerase epsilon but is apparently modulated by the presence of DNA polymerases alpha and delta.     

Examining the potential role of DNA polymerases eta and zeta in triplet repeat instability in yeast

Triplet repeats undergo frequent mutations in human families afflicted with certain neurodegenerative diseases and also in model organisms. Although the molecular mechanisms of triplet repeat instability are still being identified, it is likely that aberrant DNA synthesis plays an important role. Many DNA polymerases stall at triplet repeat sequences, probably due to the adoption of unusual DNA secondary structures. One possible mechanism to explain triplet repeat contractions is that a triplet repeat hairpin on the template strand inhibits replicative polymerases and that one or more bypass polymerases are recruited for synthesis past the hairpin. If the translesion synthesis is mutagenic, contractions can be generated. To address this possibility, Saccharomyces cerevisiae strains lacking either pol zeta (rev7), pol eta (rad30), or both were tested for trinucleotide repeat (TNR) contractions using three separate, sensitive genetic assays. If these bypass polymerases are important for mutagenesis, then the mutants should show a reduction in the contraction rate. Two genetic tests for triplet repeat contractions showed no significant change for the mutants compared to wild type. A third assay showed a five-fold reduction in contraction rates due to pol eta ablation. Despite this modest decrease, the overall contraction rate was still high, indicating that many deletions still occur in the absence of both polymerases. Expansion rates were also unaffected in the mutant strains. These results indicate that, in yeast, pol eta and pol zeta most likely have little role in triplet repeat mutagenesis.