Structural relationships between two forms of DNA polymerase epsilon from calf thymus.

We previously reported purification of two forms of DNA polymerase epsilon from calf thymus (Crute, J. J., Wahl, A. F., and Bambara, R. A. (1986) Biochemistry 25, 26-36). We have now used the "polymerase trap" photolabeling method to identify the polypeptides containing the polymerase active site in each enzyme preparation. The molecular mass of these polypeptides are 210 and 145 kDa for the polymerases now designated epsilon and epsilon*, respectively. Renaturation of polymerase activity from denaturing gel electrophoresis corroborates the polymerase trap results. Photolabeling of polymerase fractions suggests that the smaller subunit is derived by proteolysis of the larger subunit during purification. Native sedimentation coefficient measurements of polymerase-containing column fractions further suggest a precursor/product relationship between the two polymerases. Response of polymerization activity to a battery of inhibitors normally used to distinguish mammalian nuclear DNA polymerases was found to be essentially identical for polymerases epsilon, epsilon*, and the epsilon* generated in fractions initially containing epsilon. These latter results demonstrate that the loss of the protease-sensitive domain of the active site subunit does not affect catalytic function as measured in a standard DNA polymerase assay. The sole apparent functional difference observed here between the epsilon and epsilon* forms is evidence that only the full-length epsilon form can be directly photocrosslinked to dATP, independent of DNA synthesis. Photolabeling of the post-microsomal supernatant fraction from thymus glands obtained from fetal calves reveals the presence of both the epsilon and epsilon* polypeptide.     

Synthesis of DNA by DNA polymerase epsilon in vitro.

The isolation of DNA polymerase (Pol) epsilon from extracts of HeLa cells is described. The final fractions contained two major subunits of 210 and 50 kDa which cosedimented with Pol epsilon activity, similar to those described previously (Syvaoja, J., and Linn, S. (1989) J. Biol. Chem. 264, 2489-2497). The properties of the human Pol epsilon and the yeast Pol epsilon were compared. Both enzymes elongated singly primed single-stranded circular DNA templates. Yeast Pol epsilon required the presence of a DNA binding protein (SSB) whereas human Pol epsilon required the addition of SSB, Activator 1 and proliferating cell nuclear antigen (PCNA) for maximal activity. Both enzymes were totally unable to elongate primed DNA templates in the presence of salt; however, activity could be restored by the addition of Activator 1 and PCNA. Like Pol delta, Pol epsilon formed complexes with SSB-coated primed DNA templates in the presence of Activator 1 and PCNA which could be isolated by filtration through Bio-Gel A-5m columns. Unlike Pol delta, Pol epsilon bound to SSB-coated primed DNA in the absence of the auxiliary factors. In the presence of salt, Pol epsilon complexes were less stable than they were in the absence of salt. In the in vitro simian virus 40 (SV40) T antigen-dependent synthesis of DNA containing the SV40 origin of replication, yeast Pol epsilon but not human Pol epsilon could substitute for yeast or human Pol delta in the generation of long DNA products. However, human Pol epsilon did increase slightly the length of DNA chains formed by the DNA polymerase alpha-primase complex in SV40 DNA synthesis. The bearing of this observation on the requirement for a PCNA-dependent DNA polymerase in the synthesis and maturation of Okazaki fragments is discussed. However, no unique role for human Pol epsilon in the in vitro SV40 DNA replication system was detected.     

Structural relationship between DNA polymerases epsilon and epsilon* and their occurrence in eukaryotic cells.

Monoclonal antibodies raised against the N-terminal half of human DNA polymerase epsilon bind both to a large > 200 kDa form of DNA polymerase epsilon from HeLa cells and to a small 140 kDa form (DNA polymerase epsilon*) from calf thymus, while antibody against the C-terminal half binds to DNA polymerase epsilon but does not bind to DNA polymerase epsilon*. These results indicate that the two enzymes have common structural motifs in their N-terminal halves, and that DNA polymerase epsilon* is very likely derived from DNA polymerase epsilon by removal of its C-terminal half. DNA polymerase epsilon as well as DNA polymerase epsilon* was detected in extracts from cells of numerous eukaryotic species from yeast to human. The results indicate that DNA polymerase epsilon and its tendency to occur in a smaller form, DNA polymerase epsilon*, are evolutionarily highly conserved and that DNA polymerase epsilon may occur universally in proliferating eukaryotic cells.     

Identification and tryptic cleavage of the catalytic core of HeLa and calf thymus DNA polymerase epsilon

DNA polymerase epsilon, formerly known as a proliferating cell nuclear antigen-independent form of DNA polymerase delta, has been shown elsewhere to be catalytically and structurally distinct from DNA polymerase delta. The catalytic activity of HeLa DNA polymerase epsilon, an enzyme consisting of greater than 200- and 55-kDa polypeptides, was assigned to the larger polypeptide by polymerase trap reaction. This catalytic polypeptide was cleaved by incubation with trypsin into two polypeptide fragments with molecular masses of 122 and 136 kDa, the former of which was relatively resistant to further proteolysis and possessed the polymerase activity. The cleavage increased the polymerase and exonuclease activities of the enzyme some 2-3-fold. DNA polymerase epsilon was also purified in a smaller 140-kDa form from calf thymus. The digestion of this form of the enzyme by trypsin also generated a 122-kDa polypeptide. These results suggest that the catalytic core of DNA polymerase epsilon is a 258-kDa polypeptide that is composed of two segments linked with a protease-sensitive area. One of the segments harbors both DNA polymerase and 3'----5' exonuclease activities. In spite of the different polypeptide structures, the catalytic properties of the HeLa enzyme, its trypsin-digested form, and the calf thymus enzyme remained essentially the same.     

Identification and cloning of two histone fold motif-containing subunits of HeLa DNA polymerase epsilon

HeLa DNA polymerase epsilon (pol epsilon), possibly involved in both DNA replication and DNA repair, was previously isolated as a complex of a 261-kDa catalytic subunit and a tightly bound 59-kDa accessory protein. Saccharomyces cerevisiae pol epsilon, however, consists of four subunits: a 256-kDa catalytic subunit with 39% identity to HeLa pol epsilon p261, a 80-kDa subunit (DPB2) with 26% identity to HeLa pol epsilon p59, a 23-kDa subunit (DPB3), and a 22-kDa subunit (DPB4). We report here the identification and the cloning of two additional subunits of HeLa pol epsilon, p17, and p12. Both proteins contain histone fold motifs which are present also in S. cerevisiae DPB4 and DPB3. The histone fold motifs of p17 and DPB4 are related to that of subunit A of the CCAAT binding factor, whereas the histone fold motifs found in p12 and DPB3 are homologous to that in subunit C of CCAAT binding factor. p17 together with p12, but not p17 or p12 alone, interact with both p261 and p59 subunits of HeLa pol epsilon. The genes for p17 and p12 can be assigned to chromosome locations 9q33 and 2p12, respectively.     

In vivo reconstitution of Saccharomyces cerevisiae DNA polymerase epsilon in insect cells. Purification and characterization.

DNA polymerase epsilon (pol epsilon) is a multiple subunit complex consisting of at least four proteins, including catalytic Pol2p, Dpb2p, Dpb3p, and Dpb4p. Pol epsilon has been shown to play essential roles in chromosomal DNA replication. Here, we report reconstitution of the yeast pol epsilon complex, which was expressed and purified from baculovirus-infected insect cells. During the purification, we were able to resolve the pol epsilon complex and truncated Pol2p (140 kDa), as was observed initially with the pol epsilon purified from yeast. Biochemical characterization of subunit stoichiometry, salt sensitivity, processivity, and stimulation by proliferating cell nuclear antigen indicates that the reconstituted pol epsilon is functionally identical to native pol epsilon purified from yeast and is therefore useful for biochemical characterization of the interactions of pol epsilon with other replication, recombination, and repair proteins. Identification and characterization of a proliferating cell nuclear antigen consensus interaction domain on Pol2p indicates that the motif is dispensable for DNA replication but is important for methyl methanesulfonate damage-induced DNA repair. Analysis of the putative zinc finger domain of Pol2p for zinc binding capacity demonstrates that it binds zinc. Mutations of the conserved cysteines in the putative zinc finger domain reduced zinc binding, indicating that cysteine ligands are directly involved in binding zinc.     

MDM2 interacts with the C-terminus of the catalytic subunit of DNA polymerase epsilon

MDM2 is induced by p53 in response to cellular insults such as DNA damage and can have effects upon the cell cycle that are independent or downstream of p53. We used a yeast two-hybrid screen to identify proteins that bind to MDM2 and which therefore might be involved in these effects. We found that MDM2 can bind to the C-terminus of the catalytic subunit of DNA polymerase (DNA pol ), to a region that is known to be essential in yeast. In an in vitro system we confirmed that MDM2 could bind to the homologous regions of both mouse and human DNA pol and to full-length human DNA pol . DNA pol co-immunoprecipitated with MDM2 from transfected H1299 cells and also from a HeLa cell nuclear extract. We show here that the DNA pol -interacting domain of MDM2 is located between amino acids 50 and 166. Our studies provide evidence that MDM2 interacts with a region of DNA pol that plays a critical role in the function of DNA pol .     

Structure of Saccharomyces cerevisiae DNA polymerase epsilon by cryo-electron microscopy

The structure of the multisubunit yeast DNA polymerase epsilon (Pol epsilon) was determined to 20-A resolution using cryo-EM and single-particle image analysis. A globular domain comprising the catalytic Pol2 subunit is flexibly connected to an extended structure formed by subunits Dpb2, Dpb3 and Dpb4. Consistent with the reported involvement of the latter in interaction with nucleic acids, the Dpb portion of the structure directly faces a single cleft in the Pol2 subunit that seems wide enough to accommodate double-stranded DNA. Primer-extension experiments reveal that Pol epsilon processivity requires a minimum length of primer-template duplex that corresponds to the dimensions of the extended Dpb structure. Together, these observations suggest a mechanism for interaction of Pol epsilon with DNA that might explain how the structure of the enzyme contributes to its intrinsic processivity.     

Characterization of human DNA polymerase delta and its immunochemical relationships with DNA polymerase alpha and epsilon.

DNA polymerase delta was purified from human placenta and its polymerase catalytic subunit identified as a 125-kDa polypeptide by activity staining. This 125-kDa form of DNA polymerase delta resembles that reported from calf thymus (Lee, M. Y. W. T., Tan, C.-K., Downey, K. M., and So, A. G. (1984) Biochemistry 23, 1906-1913) and differs in molecular properties from a previously described form isolated from human placenta (Lee, M. Y. W. T., and Toomey, N. L. (1987) Biochemistry 26, 1076-1085) and now referred to as DNA polymerase epsilon. The properties of DNA polymerase delta were further investigated to determine its relationships with DNA polymerase epsilon. The two enzymes differed in their response to proliferating cell nuclear antigen. Monoclonal antibodies against DNA polymerase delta were raised and used to examine its immunochemical relationships with DNA polymerase alpha and epsilon. These studies provided evidence that all three proteins are structurally distinct but share a common epitope(s). Immunofluorescence microscopy indicates that DNA polymerase delta and possibly also DNA polymerase epsilon are localized to the nucleus.     

DNA polymerase epsilon: the latest member in the family of mammalian DNA polymerases

DNA polymerase epsilon is a mammalian polymerase that has a tightly associated 3'----5' exonuclease activity. Because of this readily detectable exonuclease activity, the enzyme has been regarded as a form of DNA polymerase delta, an enzyme which, together with DNA polymerase alpha, is in all probability required for the replication of chromosomal DNA. Recently, it was discovered that DNA polymerase epsilon is both catalytically and structurally distinct from DNA polymerase delta. The most striking difference between the two DNA polymerases is that processive DNA synthesis by DNA polymerase delta is dependent on proliferating cell nuclear antigen (PCNA), a replication factor, while DNA polymerase epsilon is inherently processive. DNA polymerase epsilon is required at least for the repair synthesis of UV-damaged DNA. DNA polymerases are highly conserved in eukaryotic cells. Mammalian DNA polymerases alpha, delta and epsilon are counterparts of yeast DNA polymerases I, III and II, respectively. Like DNA polymerases I and III, DNA polymerase II is also essential for the viability of cells, which suggests that DNA polymerase II (and epsilon) may play a role in DNA replication.     

cDNA and structural organization of the gene Pole1 for the mouse DNA polymerase epsilon catalytic subunit.

The cDNA and the gene for the mouse DNA polymerase epsilon catalytic subunit were cloned. The deduced protein sequence shows remarkable evolutionary conservation in DNA polymerase epsilon family. However, several conserved elements involved in template-primer binding differ from those of other class B polymerases. This is likely to reflect a distinctive function of the enzyme. The gene that was assigned to chromosome 5 region E3-E5, consists of 49 exons and has a non-conforming splice site in the junction of exon and intron 13. A CpG island covers the promoter region which contains several putative consensus elements critical for S phase upregulated and serum responsive promoters.     

DNA polymerase epsilon: in search of a function.

The current model of eukaryotic DNA replication involves the two DNA polymerases delta and alpha as the leading and lagging strand enzymes, respectively. A DNA polymerase first discovered in yeast has now been found in all eukaryotic cells and is termed DNA polymerase epsilon. In yeast, the gene for DNA polymerase epsilon has recently been found to be essential for viability, raising new questions about its functions.     

DNA polymerase epsilon catalytic domains are dispensable for DNA replication, DNA repair, and cell viability.

DNA polymerase epsilon (Pol epsilon) is believed to play an essential catalytic role during eukaryotic DNA replication and is thought to participate in recombination and DNA repair. That Pol epsilon is essential for progression through S phase and for viability in budding and fission yeasts is a central element of support for that view. We show that the amino-terminal portion of budding yeast Pol epsilon (Pol2) containing all known DNA polymerase and exonuclease motifs is dispensable for DNA replication, DNA repair, and viability. However, the carboxy-terminal portion of Pol2 is both necessary and sufficient for viability. Finally, the viability of cells lacking Pol2 catalytic function does not require intact DNA replication or damage checkpoints.     

The theta subunit of Escherichia coli DNA polymerase III: a role in stabilizing the epsilon proofreading subunit

The function of the theta subunit of Escherichia coli DNA polymerase III holoenzyme is not well established. theta is a tightly bound component of the DNA polymerase III core, which contains the alpha subunit (polymerase), the epsilon subunit (3'-->5' exonuclease), and the theta subunit, in the linear order alpha-epsilon-theta. Previous studies have shown that the theta subunit is not essential, as strains carrying a deletion of the holE gene (which encodes theta) proved fully viable. No significant phenotypic effects of the holE deletion could be detected, as the strain displayed normal cell health, morphology, and mutation rates. On the other hand, in vitro experiments have indicated the efficiency of the 3'-exonuclease activity of epsilon to be modestly enhanced by the presence of theta. Here, we report a series of genetic experiments that suggest that theta has a stabilizing role for the epsilon proofreading subunit. The observations include (i) defined DeltaholE mutator effects in mismatch-repair-defective mutL backgrounds, (ii) strong DeltaholE mutator effects in certain proofreading-impaired dnaQ strains, and (iii) yeast two- and three-hybrid experiments demonstrating enhancement of alpha-epsilon interactions by the presence of theta. theta appears conserved among gram-negative organisms which have an exonuclease subunit that exists as a separate protein (i.e., not part of the polymerase polypeptide), and the presence of theta might be uniquely beneficial in those instances where the proofreading 3'-exonuclease is not part of the polymerase polypeptide.     

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.     

Saccharomyces cerevisiae DNA polymerase epsilon and polymerase sigma interact physically and functionally,suggesting a role for polymerase epsilon in sister chromatid cohesion

The large subunit of Saccharomyces cerevisiae DNA polymerase epsilon, Pol2, comprises two essential functions. The N terminus has essential DNA polymerase activity. The C terminus is also essential, but its function is unknown. We report here that the C-terminal domain of Pol2 interacts with polymerase sigma (Pol sigma), a recently identified, essential nuclear nucleotidyl transferase encoded by two redundant genes, TRF4 and TRF5. This interaction is functional, since Pol sigma stimulates the polymerase activity of the Pol epsilon holoenzyme significantly. Since Trf4 is required for sister chromatid cohesion as well as for completion of S phase and repair, the interaction suggested that Pol epsilon, like Pol sigma, might form a link between the replication apparatus and sister chromatid cohesion and/or repair machinery. We present evidence that pol2 mutants are defective in sister chromatid cohesion. In addition, Pol2 interacts with SMC1, a subunit of the cohesin complex, and with ECO1/CTF7, required for establishing sister chromatid cohesion; and pol2 mutations act synergistically with smc1 and scc1. We also show that trf5 Delta mutants, like trf4 Delta mutants, are defective in DNA repair and sister chromatid cohesion.     

The quaternary structure of DNA polymerase epsilon from Saccharomyces cerevisiae

DNA polymerase epsilon (Pol epsilon) from Saccharomyces cerevisiae consists of four subunits (Pol2, Dpb2, Dpb3, and Dpb4) and is essential for chromosomal DNA replication. Biochemical characterizations of Pol epsilon have been cumbersome due to protease sensitivity and the limited amounts of Pol epsilon in cells. We have developed a protocol for overexpression and purification of Pol epsilon from S. cerevisiae. The native four-subunit complex was purified to homogeneity by conventional chromatography. Pol epsilon was characterized biochemically by sedimentation velocity experiments and gel filtration experiments. The stoichiometry of the four subunits was estimated to be 1:1:1:1 from colloidal Coomassie-stained gels. Based on the sedimentation coefficient (11.9 S) and the Stokes radius (74.5 A), a molecular mass for Pol epsilon of 371 kDa was calculated, in good agreement with the calculated molecular mass of 379 kDa for a heterotetramer. Furthermore, analytical equilibrium ultracentrifugation experiments support the proposed heterotetrameric structure of Pol epsilon. Thus, both DNA polymerase delta and Pol epsilon are purified as monomeric complexes, in agreement with accumulating evidence that Pol delta and Pol epsilon are located on opposite strands of the eukaryotic replication fork.     

GINS is a DNA polymerase epsilon accessory factor during chromosomal DNA replication in budding yeast

GINS is a protein complex found in eukaryotic cells that is composed of Sld5p, Psf1p, Psf2p, and Psf3p. GINS polypeptides are highly conserved in eukaryotes, and the GINS complex is required for chromosomal DNA replication in yeasts and Xenopus egg. This study reports purification and biochemical characterization of GINS from Saccharomyces cerevisiae. The results presented here demonstrate that GINS forms a 1:1 complex with DNA polymerase epsilon (Pol epsilon) holoenzyme and greatly stimulates its catalytic activity in vitro. In the presence of GINS, Pol epsilon is more processive and dissociates more readily from replicated DNA, while under identical conditions, proliferating cell nuclear antigen slightly stimulates Pol epsilon in vitro. These results strongly suggest that GINS is a Pol epsilon accessory protein during chromosomal DNA replication in budding yeast. Based on these results, we propose a model for molecular dynamics at eukaryotic chromosomal replication fork.     

DNA primase isolated from the yeast DNA primase-DNA polymerase complex. Immunoaffinity purification and analysis of RNA primer synthesis

We have utilized immunoaffinity chromatography as a means of efficiently isolating a stable yeast DNA primase from the DNA primase-DNA polymerase complex, allowing identification of the polypeptides associated with this DNA primase activity and comparison of its enzymatic properties with those of the larger protein complex. A mouse monoclonal antibody specifically recognizing the DNA polymerase subunit was used to purify the complex. Stable DNA primase was subsequently separated from the complex in high yield. The highly purified protein fraction which bound to the DNA polymerase antibody column consisted of polypeptides with apparent molecular masses of 180, 86, 70, 58, 49, and 47 kDa. DNA primase activity eluted with a fraction containing only the 58-, 49-, and 47-kDa polypeptides. Partial chemical cleavage analysis of these three proteins demonstrated that the 49- and 47-kDa polypeptides are structurally related while the 58-kDa protein is unrelated to the other two. A DNA primase inhibitory monoclonal antibody was able to inhibit the activity of the purified DNA primase as well as the activity of the enzyme in the larger complex. In immunoprecipitation experiments, all three polypeptides were found in the immune complex. Thus, these three polypeptides are sufficient for DNA primase activity. In reactions using ribonucleotide substrates and natural as well as synthetic DNA templates, the purified DNA primase exhibited the same precise synthesis of unit length oligomers as did the larger protein complex and was able to extend these RNA oligomers by one additional unit length. An examination of the effects of deoxynucleotides on these DNA primase-catalyzed reactions revealed that the yeast DNA primase is an RNA-polymerizing enzyme and lacks significant DNA-polymerizing activity under the conditions tested.