Hydrolysis of the 5'-p-nitrophenyl ester of TMP by the proofreading exonuclease (epsilon) subunit of Escherichia coli DNA polymerase III

The core of DNA polymerase III, the replicative polymerase in Escherichia coli, consists of three subunits (alpha, epsilon, and theta). The epsilon subunit is the 3'-5' proofreading exonuclease that associates with the polymerase (alpha) through its C-terminal region and theta through a 185-residue N-terminal domain (epsilon 186). A spectrophotometric assay for measurement of epsilon activity is described. Proteins epsilon and epsilon 186 and the epsilon 186.theta complex catalyzed the hydrolysis of the 5'-p-nitrophenyl ester of TMP (pNP-TMP) with similar values of k(cat) and K(M), confirming that the N-terminal domain of epsilon bears the exonuclease active site, and showing that association with theta has little direct effect on the chemistry occurring at the active site of epsilon. On the other hand, formation of the complex with theta stabilized epsilon 186 by approximately 14 degrees C against thermal inactivation. For epsilon 186, k(cat) = 293 min(-)(1) and K(M) = 1.08 mM at pH 8.00 and 25 degrees C, with a Mn(2+) concentration of 1 mM. Hydrolysis of pNP-TMP by epsilon 186 depended absolutely on divalent metal ions, and was inhibited by the product TMP. Dependencies on Mn(2+) and Mg(2+) concentrations were examined, giving a K(Mn) of 0.31 mM and a k(cat) of 334 min(-1) for Mn(2+) and a K(Mg) of 6.9 mM and a k(cat) of 19.9 min(-1) for Mg(2+). Inhibition by TMP was formally competitive [K(i) = 4.3 microM (with a Mn(2+) concentration of 1 mM)]. The pH dependence of pNP-TMP hydrolysis by epsilon 186, in the pH range of 6.5-9.0, was found to be simple. K(M) was essentially invariant between pH 6.5 and 8.5, while k(cat) depended on titration of a single group with a pK(a) of 7.7, approaching limiting values of 50 min(-1) at pH <6.5 and 400 min(-1) at pH >9.0. These data are used in conjunction with crystal structures of the complex of epsilon 186 with TMP and two Mn(II) ions bound at the active site to develop insights into the mechanisms of pNP-TMP hydrolysis by epsilon at high and low pH values.     

Elucidation of the epsilon-theta subunit interface of Escherichia coli DNA polymerase III by NMR spectroscopy

The DNA polymerase III holoenzyme (HE) is the primary replicative polymerase of Escherichia coli. The epsilon (epsilon) subunit of HE provides the 3'-->5' exonucleolytic proofreading activity for this complex. Epsilon consists of two domains: an N-terminal domain containing the proofreading exonuclease activity (residues 1-186) and a C-terminal domain required for binding to the polymerase (alpha) subunit (residues 187-243). In addition to alpha, epsilon also binds the small (8 kDa) theta (theta) subunit. The function of theta is unknown, although it has been hypothesized to enhance the 3'-->5' exonucleolytic proofreading activity of epsilon. Using NMR analysis and molecular modeling, we have previously reported a structural model of epsilon186, the N-terminal catalytic domain of epsilon [DeRose et al. (2002) Biochemistry 41, 94]. Here, we have performed 3D triple resonance NMR experiments to assign the backbone and C(beta) resonances of [U-(2)H,(13)C,(15)N] methyl protonated epsilon186 in complex with unlabeled theta. A structural comparison of the epsilon186-theta complex with free epsilon186 revealed no major changes in secondary structure, implying that the overall structure is not significantly perturbed in the complex. Amide chemical shift comparisons between bound and unbound epsilon186 revealed a potential binding surface on epsilon for interaction with theta involving structural elements near the epsilon catalytic site. The most significant shifts observed for the epsilon186 amide resonances are localized to helix alpha1 and beta-strands 2 and 3 and to the region near the beginning of alpha-helix 7. Additionally, a small stretch of residues (K158-L161), which previously had not been assigned in uncomplexed epsilon186, is predicted to adopt beta-strand secondary structure in the epsilon186-theta complex and may be significant for interaction with theta. The amide shift pattern was confirmed by the shifts of aliphatic methyl protons, for which the larger shifts generally were concentrated in the same regions of the protein. These chemical shift mapping results also suggest an explanation for how the unstable dnaQ49 mutator phenotype of epsilon may be stabilized by binding theta.     

Two functional domains of the epsilon subunit of DNA polymerase III

The epsilon subunit is the 3'-->5' proofreading exonuclease that associates with the alpha and theta subunits in the E. coli DNA polymerase III. Two fragments of the epsilon protein were prepared, and binding of these epsilon fragments with alpha and theta was investigated using gel filtration chromatography and exonuclease stimulation assays. The N-terminal fragment of epsilon, containing amino acids 2-186 (epsilon186), is a relatively protease-resistant core domain of the exonuclease. The purified recombinant epsilon186 protein catalyzes the cleavage of 3' terminal nucleotides, demonstrating that the exonuclease domain of epsilon is present in the N-terminal region of the protein. The absence of the C-terminal 57 amino acids of epsilon in the epsilon186 protein reduces the binding affinity of epsilon186 for alpha by at least 400-fold relative to the binding affinity of epsilon for alpha. In addition, stimulation of the epsilon186 exonuclease by alpha using a partial duplex DNA is about 50-fold lower than stimulation of the epsilon exonuclease by alpha. These results indicate that the C-terminal region of epsilon is required in the epsilonalpha association. To directly demonstrate that the C-terminal region of epsilon contains the alpha-association domain fusion protein, constructs containing the maltose-binding protein (MBP) and fragments of the C-terminal region of epsilon were prepared. Gel filtration analysis demonstrates that the alpha-association domain of epsilon is contained within the C-terminal 40 amino acids of epsilon. Also, the epsilon186 protein forms a tight complex with theta, demonstrating that the association of theta with epsilon is localized to the N-terminal region of epsilon. Association of epsilon186 and theta is further supported by the stimulation of the epsilon186 exonuclease in the presence of theta. These data support the concept that epsilon contains a catalytic domain located within the N-terminal region and an alpha-association domain located within the C-terminal region of the protein.     

Application of electrospray ionization mass spectrometry to study the hydrophobic interaction between the epsilon and theta subunits of DNA polymerase III

The interactions between the N-terminal domain of the epsilon (epsilon186) and theta subunits of DNA polymerase III of Escherichia coli were investigated using electrospray ionization mass spectrometry. The epsilon186-theta complex was stable in 9 M ammonium actetate (pH 8), suggesting that hydrophobic interactions have a predominant contribution to the stability of the complex. Addition of primary alkanols to epsilon186-theta in 0.1 M ammonium acetate (pH 8), led to dissociation of the complex, as observed in the mass spectrometer. The concentrations of methanol, ethanol, and 1-propanol required to dissociate 50% of the complex were 8.9 M, 4.8 M, and 1.7 M, respectively. Closer scrutiny of the effect of alkanols on epsilon186, theta, and epsilon186-theta showed that epsilon186 formed soluble aggregates prior to precipitation, and that the association of epsilon186 with theta stabilized epsilon186. In-source collision-induced dissociation experiments and other results suggested that the epsilon186-theta complex dissociated in the mass spectrometer, and that the stability (with respect to dissociation) of the complex in vacuo was dependent on the solution from which it was sampled.     

Structure of the theta subunit of Escherichia coli DNA polymerase III in complex with the epsilon subunit

The catalytic core of Escherichia coli DNA polymerase III contains three tightly associated subunits, the alpha, epsilon, and theta subunits. The theta subunit is the smallest and least understood subunit. The three-dimensional structure of theta in a complex with the unlabeled N-terminal domain of the epsilon subunit, epsilon186, was determined by multidimensional nuclear magnetic resonance spectroscopy. The structure was refined using pseudocontact shifts that resulted from inserting a lanthanide ion (Dy3+, Er3+, or Ho3+) at the active site of epsilon186. The structure determination revealed a three-helix bundle fold that is similar to the solution structures of theta in a methanol-water buffer and of the bacteriophage P1 homolog, HOT, in aqueous buffer. Conserved nuclear Overhauser enhancement (NOE) patterns obtained for free and complexed theta show that most of the structure changes little upon complex formation. Discrepancies with respect to a previously published structure of free theta (Keniry et al., Protein Sci. 9:721-733, 2000) were attributed to errors in the latter structure. The present structure satisfies the pseudocontact shifts better than either the structure of theta in methanol-water buffer or the structure of HOT. satisfies these shifts. The epitope of epsilon186 on theta was mapped by NOE difference spectroscopy and was found to involve helix 1 and the C-terminal part of helix 3. The pseudocontact shifts indicated that the helices of theta are located about 15 A or farther from the lanthanide ion in the active site of epsilon186, in agreement with the extensive biochemical data for the theta-epsilon system.     

Model for the catalytic domain of the proofreading epsilon subunit of Escherichia coli DNA polymerase III based on NMR structural data.

The DNA polymerase III holoenzyme (HE) is the primary replicative polymerase of Escherichia coli. The epsilon subunit of the HE complex provides the 3'-exonucleolytic proofreading activity for this enzyme complex. epsilon consists of two domains: an N-terminal domain containing the proofreading exonuclease activity (residues 1-186) and a C-terminal domain required for binding to the polymerase (alpha) subunit (residues 187-243). Multidimensional NMR studies of (2)H-, (13)C-, and (15)N-labeled N-terminal domains (epsilon186) were performed to assign the backbone resonances and measure H(N)-H(N) nuclear Overhauser effects (NOEs). NMR studies were also performed on triple-lableled [U-(2)H,(13)C,(15)N]epsilon186 containing Val, Leu, and Ile residues with protonated methyl groups, which allowed for the assignment of H(N)-CH(3) and CH(3)-CH(3) NOEs. Analysis of the (13)C(alpha), (13)C(beta), and (13)CO shifts, using chemical shift indexing and the TALOS program, allowed for the identification of regions of the secondary structure. H(N)-H(N) NOEs provided information on the assembly of the extended strands into a beta-sheet structure and confirmed the assignment of the alpha helices. Measurement of H(N)-CH(3) and CH(3)-CH(3) NOEs confirmed the beta-sheet structure and assisted in the positioning of the alpha helices. The resulting preliminary characterization of the three-dimensional structure of the protein indicated that significant structural homology exists with the active site of the Klenow proofreading exonuclease domain, despite the extremely limited sequence homology. On the basis of this analogy, molecular modeling studies of epsilon186 were performed using as templates the crystal structures of the exonuclease domains of the Klenow fragment and the T4 DNA polymerase and the recently determined structure of the E. coli Exonuclease I. A multiple sequence alignment was constructed, with the initial alignment taken from the previously published hidden Markov model and NMR constraints. Because several of the published structures included complexed ssDNA, we were also able to incorporate an A-C-G trinucleotide into the epsilon186 structure. Nearly all of the residues which have been identified as mutators are located in the portion of the molecule which binds the DNA, with most of these playing either a catalytic or structural role.     

Saccharomyces cerevisiae replication factor C. II. Formation and activity of complexes with the proliferating cell nuclear antigen and with DNA polymerases delta and epsilon.

Lag times in DNA synthesis by DNA polymerase delta holoenzyme were due to ATP-mediated formation of an initiation complex on the primed DNA by the polymerase with the proliferating cell nuclear antigen (PCNA) and replication factor C (RF-C). Lag time analysis showed that high affinity binding of RF-C to the primer terminus required PCNA and that this complex was recognized by the polymerase. The formation of stable complexes was investigated through their isolation by Bio-Gel A-5m filtration. A stable complex of RF-C and PCNA on primed single-stranded mp18 DNA was isolated when these factors were preincubated with the DNA and with ATP, or, less efficiently with ATP gamma S. These and additional experiments suggest that ATP binding promotes the formation of a labile complex of RF-C with PCNA at the primer terminus, whereas its hydrolysis is required to form a stable complex. Subsequently, DNA polymerase delta binds to either complex in a replication competent fashion without further energy requirement. DNA polymerase epsilon did not associate stably with RF-C and PCNA onto the DNA, but its transient participation with these cofactors into a holoenzyme-like initiation complex was inferred from its kinetic properties and replication product analysis. The kinetics of the elongation phase at 30 degrees, 110 nucleotides/s by DNA polymerase delta holoenzyme and 50 nucleotides/s by DNA polymerase epsilon holoenzyme, are in agreement with in vivo rates of replication fork movement in yeast. A model for the eukaryotic replication fork involving both DNA polymerase delta and epsilon is proposed.     

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.     

The C-terminal domain of dnaQ contains the polymerase binding site

The Escherichia coli dnaQ gene encodes the 3'-->5' exonucleolytic proofreading (epsilon) subunit of DNA polymerase III (Pol III). Genetic analysis of dnaQ mutants has suggested that epsilon might consist of two domains, an N-terminal domain containing the exonuclease and a C-terminal domain essential for binding the polymerase (alpha) subunit. We have created truncated forms of dnaQ resulting in epsilon subunits that contain either the N-terminal or the C-terminal domain. Using the yeast two-hybrid system, we analyzed the interactions of the single-domain epsilon subunits with the alpha and theta subunits of the Pol III core. The DnaQ991 protein, consisting of the N-terminal 186 amino acids, was defective in binding to the alpha subunit while retaining normal binding to the theta subunit. In contrast, the NDelta186 protein, consisting of the C-terminal 57 amino acids, exhibited normal binding to the alpha subunit but was defective in binding to the theta subunit. A strain carrying the dnaQ991 allele exhibited a strong, recessive mutator phenotype, as expected from a defective alpha binding mutant. The data are consistent with the existence of two functional domains in epsilon, with the C-terminal domain responsible for polymerase binding.     

Constitution of the twin polymerase of DNA polymerase III holoenzyme

It is speculated that DNA polymerases which duplicate chromosomes are dimeric to provide concurrent replication of both leading and lagging strands. DNA polymerase III holoenzyme (holoenzyme), is the 10-subunit replicase of the Escherichia coli chromosome. A complex of the alpha (DNA polymerase) and epsilon (3'-5' exonuclease) subunits of the holoenzyme contains only one of each protein. Presumably, one of the eight other subunit(s) functions to dimerize the alpha epsilon polymerase within the holoenzyme. Based on dimeric subassemblies of the holoenzyme, two subunits have been elected as possible agents of polymerase dimerization, one of which is the tau subunit (McHenry, C. S. (1982) J. Biol. Chem. 257, 2657-2663). Here, we have used pure alpha, epsilon, and tau subunits in binding studies to determine whether tau can dimerize the polymerase. We find tau binds directly to alpha. Whereas alpha is monomeric, tau is a dimer in its native state and thereby serves as an efficient scaffold to dimerize the polymerase. The epsilon subunit does not associate directly with tau but becomes dimerized in the alpha epsilon tau complex by virtue of its interaction with alpha. We have analyzed the dimeric alpha epsilon tau complex by different physical methods to increase the confidence that this complex truly contains a dimeric polymerase. The tau subunit is comprised of the NH2-terminal two-thirds of tau but does not bind to alpha epsilon, identifying the COOH-terminal region of tau as essential to its polymerase dimerization function. The significance of these results with respect to the organization of subunits within the holoenzyme is discussed.     

Analysis of the cruciform binding activity of recombinant 14-3-3zeta-MBP fusion protein,its heterodimerization profile with endogenous 14-3-3 isoforms,and effect on mammalian DNA replication in vitro

The human cruciform binding protein (CBP), a member of the 14-3-3 protein family, has been recently identified as an origin of DNA replication binding protein and involved in DNA replication. Here, pure recombinant 14-3-3zeta tagged with maltose binding protein (r14-3-3zeta-MBP) at its N-terminus was tested for binding to cruciform DNA either in the absence or presence of F(TH), a CBP-enriched fraction, by electromobility shift assay (EMSA), followed by Western blot analysis of the electroeluted CBP-cruciform DNA complex. The r14-3-3zeta-MBP was found to have cruciform binding activity only after preincubation with F(TH). Anti-MBP antibody immunoprecipitation of F(TH) preincubated with r14-3-3zeta-MBP, followed by Western blot analysis with antibodies specific to the beta, gamma, epsilon, zeta, and sigma 14-3-3 isoforms showed that r14-3-3zeta-MBP heterodimerized with the endogenous beta, epsilon, and zeta isoforms present in the F(TH) but not with the gamma or sigma isoforms. Immunoprecipitation of endogenous 14-3-3zeta from nuclear extracts (NE) of HeLa cells that were either serum-starved (s-s) or blocked at the G(1)/S or G(2)/M phases of the cell cycle revealed that at G(1)/S and G(2)/M, the zeta isoform heterodimerized only with the beta and epsilon isoforms, while in s-s extracts, the 14-3-3zeta/epsilon heterodimer was never detected, and the 14-3-3zeta/beta heterodimer was seldom detected. Furthermore, addition of r14-3-3zeta-MBP to HeLa cell extracts used in a mammalian in vitro replication system increased the replication level of p186, a plasmid bearing the minimal 186-bp origin of the monkey origin of DNA replication ors8, by approximately 3.5-fold. The data suggest that specific dimeric combinations of the 14-3-3 isoforms have CBP activity and that upregulation of this activity leads to an increase in DNA replication.     

RADACK, a stochastic simulation of hydroxyl radical attack to DNA

RADACK was conceived to simulate the radiation-induced attack to different DNA forms and complexes. It allows to separately calculate the probability of attack to each reactive atom of the sugar and of the base and takes into account the sequence-dependent structure of DNA as known from crystallographic or NMR studies or resulting from molecular modelling. The calculations are aimed to assess sequence-, structure- and ligand-dependent modulation of damages of sugar and bases, leading to single strand breaks (frank strand breaks, FSB) and alkali-labile base modifications (alkali-revealed breaks, ARB), respectively. The modelling procedure and the results of simulations for some representative structures (B, Z and quadruplex forms) are here described and discussed. The calculated relative probabilities of OH* radical attack to all reaction sites are compared to experimental FSB and ARB values. By a fitting procedure, the relative efficiencies of conversion of the C4' and C5'-centred radicals into FSB, epsilon (C4'): epsilon (C5'), and the relative efficiencies of base radicals- to- ARB conversion, epsilon(T) : epsilon(A) : epsilon(C) : epsilon(G), are then deduced for each DNA form. The ability of the model to account for the distribution of damages in DNA-ligand complexes is proven by its successful application to two DNA-protein systems : the lac repressor-lac operator complex and the nuclcosome core.     

Investigation of binding between recA protein and single-stranded polynucleotides with the aid of a fluorescent deoxyribonucleic acid derivative

The availability of epsilon DNA, a fluorescent ssDNA derivative, has made it possible to examine quantitatively the interactions between recA protein and single-stranded polynucleotides. Fluorescence titrations of epsilon DNA with recA protein and vice versa establish that each recA protein monomer covers 5.5 epsilon DNA nucleotides and that the dissociation constant of the recA-epsilon DNA complex is 10 nM. Fluorescence titrations of recA protein-epsilon DNA mixtures with poly(dT) establish that each recA protein monomer covers 5.1 poly(dT) nucleotides and that the dissociation constant of the recA-poly(dT) complex is 0.03 nM. Observations on how the addition of ssDNA affects the fluorescence of recA protein-epsilon DNA mixtures establish that the dissociation constant of the recA-ssDNA complex exceeds 20 microM. Stopped-flow kinetics in which excess recA protein binds to epsilon DNA indicate that k2 = 6 X 10(6) M-1 s-1 for the process. A more approximate kinetic technique indicates that recA protein binds to epsilon DNA at least one-tenth as fast as to poly(dT); the rate constant for dissociation of recA-epsilon DNA exceeds that for recA-poly(dT) by at least 30-fold. epsilon DNA is proven to be a versatile reagent for studying single-stranded polynucleotide-protein interactions. Not only can its own complexes with protein be investigated but also, under suitable circumstances, it can be used as a fluorescent probe to explore complexes incorporating nonfluorescent polynucleotides.     

Syntheses and properties of fluorescent labeled oligonucleotides containing deoxyethenoadenosine at 5' end.

The fluorescent labeled oligodeoxyribonucleotides which contain deoxyethenoadenosione (d epsilon A) at their 5' end were prepared by treating CPG bound oligonucleotides with 5'-DMTr-deoxyethenoadenosine-3'-H-phosphonate. The hybrid formation of d epsilon A-oligonucleotide with its complementary DNA was studied by fluorescence spectroscopy. The fluorescence of d epsilon A in a single strand was largely quenched by stacking interaction with the base at 3' position. When d epsilon A-oligonucleotides hybridized with their complementary strands, relative fluorescence quantum yields (Qrel) against d epsilon A changed in specific manners. These results suggest that d epsilon A-oligonucleotides are applicable to study the local structure of DNA in solution.     

Total reconstitution of DNA polymerase III holoenzyme reveals dual accessory protein clamps

DNA polymerase III holoenzyme (holoenzyme) is the 10-subunit replicase of the Escherichia coli chromosome. In this report, pure preparations of delta, delta', and a gamma chi psi complex are resolved from the five protein gamma complex subassembly. Using these subunits and other holoenzyme subunits isolated from overproducing plasmid strains of E. coli, the rapid and highly processive holoenzyme has been reconstituted from only five pure single subunits: alpha, epsilon, gamma, delta, and beta. The preceding report showed that of the three subunits in the core polymerase, only a complex of alpha (DNA polymerase) and epsilon (3'-5' exonuclease) are required to assemble a processive holoenzyme on a template containing a preinitiation complex (Studwell, P.S., and O'Donnell, M. (1990) J. Biol. Chem. 265, 1171-1178). This report shows that of the five proteins in the gamma complex only a heterodimer of gamma and delta is required with the beta subunit to form the ATP-activated preinitiation complex with a primed template. Surprisingly, the delta' subunit does not form an active complex with gamma but forms a fully active heterodimer complex with the tau subunit (as does delta). Hence, the tau delta' and gamma delta heterodimers are fully active in the preinitiation complex reaction with beta and primed DNA. Holoenzymes reconstituted using the alpha epsilon complex, beta subunit, and either gamma delta or tau delta' are fully processive in DNA synthesis, and upon completing the template they rapidly cycle to a new primed template endowed with a preinitiation complex clamp. Since the holoenzyme molecule contains all of these accessory subunits (gamma, delta, tau, delta', and beta) in all likelihood it has the capacity to form two preinitiation complex clamps simultaneously at two primer termini. Two primer binding components within one holoenzyme may mediate its rapid cycling to multiple primers on the lagging strand and also provides functional evidence for the hypothesis of holoenzyme as a dimeric polymerase capable of simultaneous replication of both leading and lagging strands of a replication fork.     

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.     

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.     

Long terminal repeat-like elements flank a human immunoglobulin epsilon pseudogene that lacks introns

There are at least three immunoglobulin epsilon genes (C epsilon 1, C epsilon 2, and C epsilon 3) in the human genome. The nucleotide sequences of the expressed epsilon gene (C epsilon 1) and one (C epsilon 3) of the two epsilon pseudogenes were compared. The results show that the C epsilon 3 gene lacks the three intervening sequences entirely and has a 31-base A-rich sequence 16 bases 3' to the putative poly(A) addition signal, indicating that the C epsilon 3 gene is a processed gene. The C epsilon 3 gene sequence is homologous to the five separate DNA segments of the C epsilon 1 gene; namely, a segment in the 5'-flanking region (100 bases) and four exons, which are interrupted by a spacer region or intervening sequences. Long terminal repeat (LTR)-like sequences which contain TATAAA and AATAAA sequences as well as terminal inverted repeats are present in both 5'- and 3'-flanking regions. The 5' and 3' LTR-like sequences do not, however, constitute a direct repeat, unlike transposable elements of eukaryotes and retroviruses. The 3' LTR-like sequence is repetitive in the human genome, but is not homologous to the Alu family DNA. Models for the evolutionary origin of the processed gene flanked by the LTR-like sequences are discussed. The C epsilon 3 gene has a new open frame which codes potentially for an unknown protein of 292 amino acid residues.