Structure of DNA polymerase delta from Saccharomyces cerevisiae

DNA polymerase delta (Pol delta) from Saccharomyces cerevisiae consists of three subunits, Pol3 (125 kDa), Pol31 (55 kDa), and Pol32 (40 kDa), present at a 1:1:1 stoichiometry in purified preparations. Previously, based on gel filtration studies of Pol delta, we suggested that the enzyme may be a dimer of catalytic cores, with dimerization mediated by the Pol32 subunit (Burgers, P. M., and Gerik, K. J. (1998) J. Biol. Chem. 273, 19756-19762). We now report on extensive gel filtration, glycerol gradient sedimentation, and analytical equilibrium centrifugation studies of Pol delta and of several subassemblies of Pol delta. The hydrodynamic parameters of these assemblies indicate that (i) Pol32 is a rod-shaped protein with a frictional ratio f/f(0) = 2.22; (ii) any complex containing Pol32 also has an extremely asymmetric shape; (iii) the results of these studies are independent of concentration (varied between 0.1-20 microm); (iv) all complexes are monomeric under the conditions studied (up to 20 microm). Moreover, a two-hybrid analysis of the Pol32 subunit did not detect a Pol32-Pol32 interaction in vivo. Therefore, we conclude that the assembly structure of Pol delta is that of a monomer.

ATP utilization by yeast replication factor C. IV. RFC ATP-binding mutants show defects in DNA replication, DNA repair, and checkpoint regulation

Replication factor C is required to load proliferating cell nuclear antigen onto primer-template junctions, using the energy of ATP hydrolysis. Four of the five RFC genes have consensus ATP-binding motifs. To determine the relative importance of these sites for proper DNA metabolism in the cell, the conserved lysine in the Walker A motif of RFC1, RFC2, RFC3, or RFC4 was mutated to either arginine or glutamic acid. Arginine mutations in all RFC genes tested permitted cell growth, although poor growth was observed for rfc2-K71R. A glutamic acid substitution resulted in lethality in RFC2 and RFC3 but not in RFC1 or RFC4. Most double mutants combining mutations in two RFC genes were inviable. Except for the rfc1-K359R and rfc4-K55E mutants, which were phenotypically similar to wild type in every assay, the mutants were sensitive to DNA-damaging agents. The rfc2-K71R and rfc4-K55R mutants show checkpoint defects, most likely in the intra-S phase checkpoint. Regulation of the damage-inducible RNR3 promoter was impaired in these mutants, and phosphorylation of Rad53p in response to DNA damage was specifically defective when cells were in S phase. No dramatic defects in telomere length regulation were detected in the mutants. These data demonstrate that the ATP binding function of RFC2 is important for both DNA replication and checkpoint function and, for the first time, that RFC4 also plays a role in checkpoint regulation.

ATP utilization by yeast replication factor C. III. The ATP-binding domains of Rfc2, Rfc3, and Rfc4 are essential for DNA recognition and clamp loading

The conserved lysine in the Walker A motif of the ATP-binding domain encoded by the yeast RFC1, RFC2, RFC3, and RFC4 genes was mutated to glutamic acid. Complexes of replication factor C with a N-terminal truncation (Delta2-273) of the Rfc1 subunit (RFC) containing a single mutant subunit were overproduced in Escherichia coli for biochemical analysis. All of the mutant RFC complexes were capable of interacting with PCNA. Complexes containing a rfc1-K359E mutation were similar to wild type in replication activity and ATPase activity; however, the mutant complex showed increased susceptibility to proteolysis. In contrast, complexes containing either a rfc2-K71E mutation or a rfc3-K59E mutation were severely impaired in ATPase and clamp loading activity. In addition to their defects in ATP hydrolysis, these complexes were defective for DNA binding. A mutant complex containing the rfc4-K55E mutation performed as well as a wild type complex in clamp loading, but only at very high ATP concentrations. Mutant RFC complexes containing rfc2-K71R or rfc3-K59R, carrying a conservative lysine --> arginine mutation, had much milder clamp loading defects that could be partially (rfc2-K71R) or completely (rfc3-K59R) suppressed at high ATP concentrations.

ATP utilization by yeast replication factor C. II. Multiple stepwise ATP binding events are required to load proliferating cell nuclear antigen onto primed DNA

Binding of adenosine (3-thiotriphosphate) (ATPgammaS), a nonhydrolyzable analog of ATP, to replication factor C with a N-terminal truncation (Delta2-273) of the Rfc1 subunit (RFC) was studied by filter binding. RFC alone bound 1.8 ATPgammaS molecules. However, when either PCNA or primer-template DNA were also present 2.6 or 2.7 ATPgammaS molecules, respectively, were bound. When both PCNA and DNA were present 3.6 ATPgammaS molecules were bound per RFC. Order of addition experiments using surface plasmon resonance indicate that RFC forms an ATP-mediated binary complex with PCNA prior to formation of a ternary DNA.PCNA.RFC complex. An ATP-mediated complex between RFC and DNA was not competent for binding PCNA, and the RFC.DNA complex dissociated with hydrolysis of ATP. Based on these experiments a model is proposed in which: (i) RFC binds two ATPs (RFC.ATP(2)); (ii) this complex binds PCNA (PCNA.RFC.ATP(2)), which goes through a conformational change to reveal a binding site for one additional ATP (PCNA.RFC.ATP(3)); (iii) this complex can bind DNA to yield DNA.PCNA.RFC.ATP(3); (iv) a conformational change in the latter complex reveals a fourth binding site for ATP; and (v) the DNA.PCNA.RFC.ATP(4) complex is finally competent for completion of PCNA loading and release of RFC upon hydrolysis of ATP.

ATP utilization by yeast replication factor C. I. ATP-mediated interaction with DNA and with proliferating cell nuclear antigen

Eukaryotic replication factor C is the heteropentameric complex that loads the replication clamp proliferating cell nuclear antigen (PCNA) onto primed DNA. In this study we used a derivative, designated RFC, with a N-terminal truncation of the Rfc1 subunit removing a DNA-binding domain not required for clamp loading. Interactions of yeast RFC with PCNA and DNA were studied by surface plasmon resonance. Binding of RFC to PCNA was stimulated by either adenosine (3-thiotriphosphate) (ATPgammaS) or ATP. RFC bound only to primer-template DNA coated with the single-stranded DNA-binding protein RPA if ATPgammaS was also present. Binding occurred without dissociation of RPA. ATP did not stimulate binding of RFC to DNA, suggesting that hydrolysis of ATP dissociated DNA-bound RFC. However, when RFC and PCNA together were flowed across the DNA chip in the presence of ATP, a signal was observed suggesting loading of PCNA by RFC. With ATPgammaS present instead of ATP, long-lived response signals were observed indicative of loading complexes arrested on the DNA. A primer with a 3' single-stranded extension also allowed loading of PCNA; yet turnover of the reaction intermediates was dramatically slowed down. Filter binding experiments and analysis of proteins bound to DNA-magnetic beads confirmed the conclusions drawn from the surface plasmon resonance studies.

Interactions between the Werner syndrome helicase and DNA polymerase delta specifically facilitate copying of tetraplex and hairpin structures of the d(CGG)n trinucleotide repeat sequence

Werner syndrome (WS) is an inherited disorder characterized by premature aging and genomic instability. The protein encoded by the WS gene, WRN, possesses intrinsic 3' --> 5' DNA helicase and 3' --> 5' DNA exonuclease activities. WRN helicase resolves alternate DNA structures including tetraplex and triplex DNA, and Holliday junctions. Thus, one function of WRN may be to unwind secondary structures that impede cellular DNA transactions. We report here that hairpin and G'2 bimolecular tetraplex structures of the fragile X expanded sequence, d(CGG)(n), effectively impede synthesis by three eukaryotic replicative DNA polymerases (pol): pol alpha, pol delta, and pol epsilon. The constraints imposed on pol delta-catalyzed synthesis are relieved, however, by WRN; WRN facilitates pol delta to traverse these template secondary structures to synthesize full-length DNA products. The alleviatory effect of WRN is limited to pol delta; neither pol alpha nor pol epsilon can traverse template d(CGG)(n) hairpin and tetraplex structures in the presence of WRN. Alleviation of pausing by pol delta is observed with Escherichia coli RecQ but not with UvrD helicase, suggesting a concerted action of RecQ helicases and pol delta. Our findings suggest a possible role of WRN in rescuing pol delta-mediated replication at forks stalled by unusual DNA secondary structures.

The 3'-->5' exonuclease of DNA polymerase delta can substitute for the 5' flap endonuclease Rad27/Fen1 in processing Okazaki fragments and preventing genome instability

Many DNA polymerases (Pol) have an intrinsic 3'-->5' exonuclease (Exo) activity which corrects polymerase errors and prevents mutations. We describe a role of the 3'-->5' Exo of Pol delta as a supplement or backup for the Rad27/Fen1 5' flap endonuclease. A yeast rad27 null allele was lethal in combination with Pol delta mutations in Exo I, Exo II, and Exo III motifs that inactivate its exonuclease, but it was viable with mutations in other parts of Pol delta. The rad27-p allele, which has little phenotypic effect by itself, was also lethal in combination with mutations in the Pol delta Exo I and Exo II motifs. However, rad27-p Pol delta Exo III double mutants were viable. They exhibited strong synergistic increases in CAN1 duplication mutations, intrachromosomal and interchromosomal recombination, and required the wild-type double-strand break repair genes RAD50, RAD51, and RAD52 for viability. Observed effects were similar to those of the rad27-null mutant deficient in the removal of 5' flaps in the lagging strand. These results suggest that the 3'-->5' Exo activity of Pol delta is redundant with Rad27/Fen1 for creating ligatable nicks between adjacent Okazaki fragments, possibly by reducing the amount of strand-displacement in the lagging strand.

Roles of yeast DNA polymerases delta and zeta and of Rev1 in the bypass of abasic sites

Abasic (AP) sites are one of the most frequently formed lesions in DNA, and they present a strong block to continued synthesis by the replicative DNA machinery. Here we show efficient bypass of an AP site by the combined action of yeast DNA polymerases delta and zeta. In this reaction, Poldelta inserts an A nucleotide opposite the AP site, and Polzeta subsequently extends from the inserted nucleotide. Consistent with these observations, sequence analyses of mutations in the yeast CAN1s gene indicate that A is the nucleotide inserted most often opposite AP sites. The nucleotides C, G, and T are also incorporated, but much less frequently. Enzymes such as Rev1 and Poleta may contribute to the insertion of these other nucleotides; the predominant role of Rev1 in AP bypass, however, is likely to be structural. Steady-state kinetic analyses show that Polzeta is highly inefficient in incorporating nucleotides opposite the AP site, but it efficiently extends from nucleotides, particularly an A, inserted opposite this lesion. Thus, in eukaryotes, bypass of an AP site requires the sequential action of two DNA polymerases, wherein the extension step depends solely upon Polzeta, but the insertion step can be quite varied, involving not only the predominant action of the replicative DNA polymerase, Poldelta, but also the less prominent role of various translesion synthesis polymerases.

Two modes of FEN1 binding to PCNA regulated by DNA

The FEN1 nuclease functions during Okazaki fragment maturation in the eukaryotic cell. Like many other proliferating cell nuclear antigen (PCNA)-binding proteins, FEN1 interacts with the interdomain connector loop (IDCL) of PCNA, and PCNA greatly stimulates FEN1 activity. A yeast IDCL mutant pcna-79 (IL126,128AA) failed to interact with FEN-1, but, surprisingly, pcna-79 was still very active in stimulating FEN1 activity. In contrast, a C-terminal mutant pcna-90 (PK252,253AA) showed wild-type binding to FEN1 in solution, but poorly stimulated FEN1 activity. When PCNA was loaded onto a DNA substrate coupled to magnetic beads, it stabilized retention of FEN1 on the DNA. In this DNA-dependent binding assay, pcna-79 also stabilized retention of FEN1, but pcna-90 was inactive. Therefore, in the absence of DNA, FEN1 interacts with PCNA mainly through the IDCL. However, when PCNA encircles the DNA, the C-terminal domain of PCNA rather than its IDCL is important for binding FEN1. An FF-->GA mutation in the PCNA-interaction domain of FEN1 severely decreased both modes of interaction with PCNA and resulted in replication and repair defects in vivo.

Overproduction in Escherichia coli and characterization of yeast replication factor C lacking the ligase homology domain

Eukaryotic replication factor C (RF-C) is a heteropentameric complex that is required to load the replication clamp proliferating cell nuclear antigen onto primed DNA. Saccharomyces cerevisiae RF-C is encoded by the genes RFC1-RFC5. The RFC1 gene was cloned under control of the strong inducible bacteriophage T7 promoter, yet induction did not yield detectable Rfc1p. However, a truncated form of RFC1 deleted for the coding region for amino acids 3-273, rfc1-DeltaN, did allow overproduction. The other four RFC genes were cloned into the latter plasmid to yield a single plasmid that overproduced RF-C to moderate levels. Overproduction of the complex was further enhanced when the Escherichia coli argU gene encoding the rare arginine tRNA was also overproduced. The enzyme thus produced in E. coli was purified to homogeneity through three column steps, including a proliferating cell nuclear antigen affinity column. This enzyme, as well as the enzyme purified from yeast, is prone to aggregation and inactivation, and therefore, light scattering was used to determine conditions stabilizing the enzyme and preventing aggregation. Broad-range carrier ampholytes at about 0.05% were found to be most effective. In some assays, the Rfc1-DeltaN containing RF-C from E. coli showed an increased activity compared with the full-length enzyme from yeast, likely because the latter enzyme exhibits significant nonspecific binding to single-stranded DNA. Replacement of RFC1 by rfc1-DeltaN in yeast shows essentially no phenotype with regard to DNA replication, damage susceptibility, telomere length maintenance, and intrachromosomal recombination.

Functional interaction between the Werner Syndrome protein and DNA polymerase delta

Werner Syndrome (WS) is an inherited disease characterized by premature onset of aging, increased cancer incidence, and genomic instability. The WS gene encodes a 1,432-amino acid polypeptide (WRN) with a central domain homologous to the RecQ family of DNA helicases. Purified WRN unwinds DNA with 3'-->5' polarity, and also possesses 3'-->5' exonuclease activity. Elucidation of the physiologic function(s) of WRN may be aided by the identification of WRN-interacting proteins. We show here that WRN functionally interacts with DNA polymerase delta (pol delta), a eukaryotic polymerase required for DNA replication and DNA repair. WRN increases the rate of nucleotide incorporation by pol delta in the absence of proliferating cell nuclear antigen (PCNA) but does not stimulate the activity of eukaryotic DNA polymerases alpha or epsilon, or a variety of other DNA polymerases. Moreover, we show that functional interaction with WRN is mediated through the third subunit of pol delta: i.e., Pol32p of Saccharomyces cerevisae, corresponding to the recently identified p66 subunit of human pol delta. Absence of the third subunit abrogates stimulation by WRN, and stimulation is restored by reconstituting the three-subunit enzyme. Our findings suggest that WRN may facilitate pol delta-mediated DNA replication and/or DNA repair and that disruption of WRN-pol delta interaction in WS cells may contribute to the previously observed S-phase defects and/or the unusual sensitivity to a limited number of DNA damaging agents.

Overexpression of multisubunit replication factors in yeast

Facile genetic and biochemical manipulation coupled with rapid cell growth and low cost of growth media has established the yeast Saccharomyces cerevisiae as a versatile workhorse. This article describes the use of yeast expression systems for the overproduction of complex multipolypeptide replication factors. The regulated overexpression of these factors in yeast provides for a readily accessible and inexpensive source of these factors in large quantities. The methodology is illustrated with the five-subunit replication factor C. Whole-cell extracts are prepared by blending yeast cells with glass beads or frozen yeast with dry ice. Procedures are described that maximize the yield of these factors while minimizing proteolytic degradation.

Eukaryotic DNA polymerases in DNA replication and DNA repair

DNA polymerases carry out a large variety of synthetic transactions during DNA replication, DNA recombination and DNA repair. Substrates for DNA polymerases vary from single nucleotide gaps to kilobase size gaps and from relatively simple gapped structures to complex replication forks in which two strands need to be replicated simultaneously. Consequently, one would expect the cell to have developed a well-defined set of DNA polymerases with each one uniquely adapted for a specific pathway. And to some degree this turns out to be the case. However, in addition we seem to find a large degree of cross-functionality of DNA polymerases in these different pathways. DNA polymerase alpha is almost exclusively required for the initiation of DNA replication and the priming of Okazaki fragments during elongation. In most organisms no specific repair role beyond that of checkpoint control has been assigned to this enzyme. DNA polymerase delta functions as a dimer and, therefore, may be responsible for both leading and lagging strand DNA replication. In addition, this enzyme is required for mismatch repair and, together with DNA polymerase zeta, for mutagenesis. The function of DNA polymerase epsilon in DNA replication may be restricted to that of Okazaki fragment maturation. In contrast, either polymerase delta or epsilon suffices for the repair of UV-induced damage. The role of DNA polymerase beta in base-excision repair is well established for mammalian systems, but in yeast, DNA polymerase delta appears to fulfill that function.

Characterization of the two small subunits of Saccharomyces cerevisiae DNA polymerase delta

Yeast DNA polymerase delta (Poldelta) has three subunits of 125, 58, and 55 kDa. The gene for the 125-kDa catalytic subunit (POL3) has been known for several years. Here we describe the cloning of the genes for the 58- and 55-kDa subunits using peptide sequence analysis and searching of the yeast genome data base. The 58-kDa subunit, encoded by the POL31 gene, shows 23-28% sequence similarity to the 48-kDa subunit of human Poldelta and to S. pombe Cdc1. POL31 is allelic to HYS2 and SDP5. The 55-kDa subunit is encoded by the POL32 gene (ORF YJR043c in the yeast data base). Very limited sequence similarity was observed between Pol32p and Schizosaccharomyces pombe Cdc27, the functionally analogous subunit in S. pombe Poldelta. The POL32 gene is not essential, but a deletion mutant shows cold sensitivity for growth and is sensitive to hydroxyurea and DNA damaging agents. In addition, lethality was observed when the POL32 deletion mutation was combined with conditional mutations in either the POL3 or POL31 gene. Pol32Delta strains are weak antimutators and are defective for damage-induced mutagenesis. The POL32 gene product binds proliferating cell nuclear antigen. A gel filtration analysis showed that Pol32p is a dimer in solution. When POL31 and POL32 were co-expressed in Escherichia coli, a tetrameric (Pol31p.Pol32p)2 species was detected by gel filtration, indicating that the two subunits form a complex.

Structure and processivity of two forms of Saccharomyces cerevisiae DNA polymerase delta

Yeast DNA polymerase delta (Poldelta) consists of three subunits encoded by the POL3, POL31, and POL32 genes. Each of these genes was cloned under control of the galactose-inducible GAL1-10 promoter and overexpressed in various combinations. Overexpression of all three genes resulted in a 30-fold overproduction of Poldelta, which was identical in enzymatic properties to Poldelta isolated from a wild-type yeast strain. Whereas overproduction of POL3 together with POL32 did not lead to an identifiable Pol3p.Pol32p complex, a chromatographically distinct and novel complex was identified upon overproduction of POL3 and POL31. This two-subunit complex, designated Poldelta*, is structurally and functionally analogous to mammalian Poldelta. The properties of Poldelta* and Poldelta were compared. A gel filtration analysis showed that Poldelta* is a heterodimer (Pol3p.Pol31p) and Poldelta a dimer of a heterotrimer, (Pol3p.Pol31p.Pol32p)2. In the absence of proliferating cell nuclear antigen (PCNA), Poldelta* showed a processivity of 2-3 on poly(dA). oligo(dT) compared with 5-10 for Poldelta. In the presence of PCNA, both enzymes were fully processive on this template. DNA replication by Poldelta* on a natural DNA template was dependent on PCNA and on replication factor C. However, Poldelta*-mediated DNA synthesis proceeded inefficiently and was characterized by frequent pause sites. Reconstitution of Poldelta was achieved upon addition of Pol32p to Poldelta*.

Bypass of a site-specific cis-Syn thymine dimer in an SV40 vector during in vitro replication by HeLa and XPV cell-free extracts

The key step in skin cancer induction by UV light is thought to be the mutagenic DNA synthesis past a DNA photoproduct in a proto-oncogene or tumor suppressor gene. To investigate this critical step, we have constructed an SV40 vector containing a cis-syn thymine dimer, the major DNA photoproduct induced by UVB light, within an AseI site at a location that would initially be replicated by leading strand synthesis. When the dimer-containing SV40 vector was incubated with cell-free HeLa extracts in the presence of TAg, and then digested with AseI, a 2325 bp fragment corresponding to inhibition of cleavage at the dimer site was observed, suggesting that the dimer had terminated synthesis and/or had been bypassed. When the reaction was limited to one round of replication and the products of restriction enzyme digestion were examined by denaturing gel electrophoresis, bands corresponding to both termination and bypass were observed in roughly a one-to-one ratio. Whereas increasing the dNTP concentration from 10 microM to 1 mM increased the ratio of bypass to termination from 0.6 to 2.6, it had no effect on the site of termination, which occurred exclusively one nucleotide before the dimer. Experiments in which dGTP was held constant at 25 microM and various combinations of the remaining nucleotides were raised from 25 microM to 1 mM showed substantial increases in the bypass-to-termination ratio, with the greatest effect seen for raising all three nucleotides to 1 mM. Replication by primary fibroblast XPV extracts was also investigated and found to be greatly stimulated by rhRPA, whereas the stimulatory effect for HeLa cell extracts was variable. In the presence of rhRPA, the XPV extracts were also found to bypass the cis-syn dimer, which contrasts with a recent report that could not detect dimer bypass in SV40 transformed XPV extracts in the absence of added replication factors [Cordeiro-Stone, M., et al. (1997) J. Biol. Chem. 272, 13945-13954].

Destabilized PCNA trimers suppress defective Rfc1 proteins in vivo and in vitro

Replication factor C (RFC) and the proliferating cell nuclear antigen (PCNA) are two essential DNA polymerase accessory proteins that are required for numerous aspects of DNA metabolism including DNA replication, DNA repair, and telomere metabolism. PCNA is a homotrimeric ring-shaped sliding DNA clamp that can facilitate DNA replication by tethering DNA polymerase delta or DNA polymerase epsilon to the DNA template. RFC is the 5-subunit multiprotein complex that loads PCNA onto DNA at primer-template junctions in an ATP-dependent reaction. All five of the RFC subunits share a set of related sequences (RFC boxes) that include nucleotide-binding consensus sequences. We report here that a mutation in the gene encoding the large subunit of yeast RFC gives rise to DNA metabolism defects that can be observed in vivo and in vitro. The rfc1-1 substitution (D513N) lies within the widely conserved RFC box VIII consensus sequence and results in phenotypes including DNA replication defects, increased sensitivity to DNA damaging agents, and elongated telomeres. Mutant Rfc1-1 complexes exhibit in vitro DNA replication defects that are sensitive to ATP concentrations, and these defects can be suppressed by mutant PCNA proteins which contain substitutions that destabilize the homotrimeric sliding DNA clamp.

Mutations in yeast proliferating cell nuclear antigen define distinct sites for interaction with DNA polymerase delta and DNA polymerase epsilon

The importance of the interdomain connector loop and of the carboxy-terminal domain of Saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA) for functional interaction with DNA polymerases delta (Poldelta) and epsilon (Pol epsilon) was investigated by site-directed mutagenesis. Two alleles, pol30-79 (IL126,128AA) in the interdomain connector loop and pol30-90 (PK252,253AA) near the carboxy terminus, caused growth defects and elevated sensitivity to DNA-damaging agents. These two mutants also had elevated rates of spontaneous mutations. The mutator phenotype of pol30-90 was due to partially defective mismatch repair in the mutant. In vitro, the mutant PCNAs showed defects in DNA synthesis. Interestingly, the pol30-79 mutant PCNA (pcna-79) was most defective in replication with Poldelta, whereas pcna-90 was defective in replication with Pol epsilon. Protein-protein interaction studies showed that pcna-79 and pcna-90 failed to interact with Pol delta and Pol epsilon, respectively. In addition, pcna-90 was defective in interaction with the FEN-1 endo-exonuclease (RTH1 product). A loss of interaction between pcna-79 and the smallest subunit of Poldelta, the POL32 gene product, implicates this interaction in the observed defect with the polymerase. Neither PCNA mutant showed a defect in the interaction with replication factor C or in loading by this complex. Processivity of DNA synthesis by the mutant holoenzyme containing pcna-79 was unaffected on poly(dA) x oligo(dT) but was dramatically reduced on a natural template with secondary structure. A stem-loop structure with a 20-bp stem formed a virtually complete block for the holoenzyme containing pcna-79 but posed only a minor pause site for wild-type holoenzyme, indicating a function of the POL32 gene product in allowing replication past structural blocks.

The influence of the proliferating cell nuclear antigen-interacting domain of p21(CIP1) on DNA synthesis catalyzed by the human and Saccharomyces cerevisiae polymerase delta holoenzymes

In eukaryotes, processive DNA synthesis catalyzed by DNA polymerases delta and epsilon (pol delta and epsilon) requires the proliferating cell nuclear antigen (PCNA). It has recently been shown that in humans (h), the PCNA function, required for both DNA replication and nucleotide excision repair, can be inactivated by p21(CIP1) due to a specific interaction between hPCNA and the carboxyl terminus of p21(CIP1). In this report, we show that Saccharomyces cerevisiae (S. cerevisiae) PCNA-dependent pol delta-catalyzed DNA synthesis was inhibited less efficiently than the human system by the intact p21(CIP1) protein and was unaffected by the p21(CIP1) carboxyl-terminal peptide (codons 139-160). This species-specific response of PCNA to p21(CIP1)-mediated inhibition of DNA synthesis results from a marked difference in the ability of h and S. cerevisiae PCNA to interact with p21(CIP1). As shown by binding studies using the surface plasmon resonance technique, hPCNA binds both full-length p21(CIP1) and the p21(CIP1) peptide-(139-160) stoichiometrically with a similar affinity (KD approximately 2.5 nM) while S. cerevisiae PCNA binds p21(CIP1) with approximately 10-fold less affinity and does not interact with the p21(CIP1) peptide-(139-160).

Overproduction and affinity purification of Saccharomyces cerevisiae replication factor C

Yeast replication factor C (RF-C) is a heteropentamer encoded by the RFC1-5 genes. RF-C activity in yeast extracts was overproduced about 80-fold after induction of a strain containing all five genes on a single plasmid, with expression of each gene placed under control of the galactose-inducible GAL1-10 promoter. This strongly indicates that overexpression of the five known RFC genes is sufficient for overproduction of RF-C. Overexpression of all five genes was also necessary to achieve overproduction of RF-C as omission of any single gene from the plasmid gave uninduced, i.e. normal cellular levels of RF-C. The interaction between RF-C and proliferating cell nuclear antigen (PCNA) was studied with PCNA-agarose beads. Binding of RF-C to PCNA-agarose beads is negligible in buffers containing 0.3 M NaCl. However, addition of Mg-ATP to the binding buffer caused strong binding of RF-C to the beads even at 0.8 M NaCl. Binding of ATP, but not its hydrolysis, was required for the strong binding mode as nonhydrolyzable analogs were also effective. The existence of two distinct binding modes between PCNA and RF-C was used as the key step in a greatly improved procedure for the purification of RF-C. RF-C from the overproduction strain purified by this procedure was essentially homogeneous and had a severalfold higher specific activity than RF-C preparations that had previously been purified through multicolumn procedures.

Requirement of proliferating cell nuclear antigen in RAD6-dependent postreplicational DNA repair

The proliferating cell nuclear antigen (PCNA) acts as a processivity factor for replicative DNA polymerases and is essential for DNA replication. In vitro studies have suggested a role for PCNA-in the repair synthesis step of nucleotide excision repair, and PCNA interacts with the cyclin-dependent kinase inhibitor p21. However, because of the lack of genetic evidence, it is not clear which of the DNA repair processes are in fact affected by PCNA in vivo. Here, we describe a PCNA mutation, pol30-46, that confers ultraviolet (UV) sensitivity but has no effect on growth or cell cycle progression, and the mutant pcna interacts normally with DNA polymerase delta and epsilon. Genetic studies indicate that the pol30-46 mutation is specifically defective in RAD6-dependent postreplicational repair of UV damaged DNA, and this mutation impairs the error-free mode of bypass repair. These results implicate a role for PCNA as an intermediary between DNA replication and postreplicational DNA repair.

Processing of branched DNA intermediates by a complex of human FEN-1 and PCNA

In eukaryotic cells, a 5' flap DNA endonuclease activity and a ds DNA 5'-exonuclease activity exist within a single enzyme called FEN-1 [flap endo-nuclease and 5(five)'-exo-nuclease]. This 42 kDa endo-/exonuclease, FEN-1, is highly homologous to human XP-G, Saccharomyces cerevisiae RAD2 and S.cerevisiae RTH1. These structure-specific nucleases recognize and cleave a branched DNA structure called a DNA flap, and its derivative called a pseudo Y-structure. FEN-1 is essential for lagging strand DNA synthesis in Okazaki fragment joining. FEN-1 also appears to be important in mismatch repair. Here we find that human PCNA, the processivity factor for eukaryotic polymerases, physically associates with human FEN-1 and stimulates its endonucleolytic activity at branched DNA structures and its exonucleolytic activity at nick and gap structures. Structural requirements for FEN-1 and PCNA loading provide an interesting picture of this stimulation. PCNA loads on to substrates at double-stranded DNA ends. In contrast, FEN-1 requires a free single-stranded 5' terminus and appears to load by tracking along the single-stranded DNA branch. These physical constraints define the range of DNA replication, recombination and repair processes in which this family of structure-specific nucleases participate. A model explaining the exonucleolytic activity of FEN-1 in terms of its endonucleolytic activity is proposed based on these observations.

Lagging strand DNA synthesis at the eukaryotic replication fork involves binding and stimulation of FEN-1 by proliferating cell nuclear antigen

The 5'-->3'-exonuclease domain of Escherichia coli DNA polymerase I is required for the completion of lagging strand DNA synthesis, and yet this domain is not present in any of the eukaryotic DNA polymerases. Recently, the gene encoding the functional and evolutionary equivalent of this 5'-->3'-exonuclease domain has been identified. It is called FEN-1 in mouse and human cells and RTH1 in Saccharomyces cerevisiae. This 42-kDa enzyme is required for Okazaki fragment processing. Here we report that FEN-1 physically interacts with proliferating cell nuclear antigen (PCNA), the processivity factor for DNA polymerases delta and epsilon. Through protein-protein interactions, PCNA focuses FEN-1 on branched DNA substrates (flap structures) and on nicked DNA substrates, thereby stimulating its activity 10-50-fold but only if PCNA can functionally assemble as a toroidal trimer around the DNA. This interaction is important in the physical orchestration of lagging strand synthesis and may have implications for how PCNA stimulates other members of the FEN-1 nuclease family in a broad range of DNA metabolic transactions.

A mutational analysis of the yeast proliferating cell nuclear antigen indicates distinct roles in DNA replication and DNA repair

The saccharomyces cerevisiae proliferating cell nuclear antigen (PCNA), encoded by the POL30 gene, is essential for DNA replication and DNA repair processes. Twenty-one site-directed mutations were constructed in the POL30 gene, each mutation changing two adjacently located charged amino acids to alanines. Although none of the mutant strains containing these double-alanine mutations as the sole source of PCNA were temperature sensitive or cold sensitive for growth, about a third of the mutants showed sensitivity to UV light. Some of those UV-sensitive mutants had elevated spontaneous mutation rates. In addition, several mutants suppressed a cold-sensitive mutation in the CDC44 gene, which encodes the large subunit of replication factor C. A cold-sensitive mutant, which was isolated by random mutagenesis, showed a terminal phenotype at the restrictive temperature consistent with a defect in DNA replication. Several mutant PCNAs were expressed and purified from Escherichia coli, and their in vitro properties were determined. The cold-sensitive mutant (pol30-52, S115P) was a monomer, rather than a trimer, in solution. This mutant was deficient for DNA synthesis in vitro. Partial restoration of DNA polymerase delta holoenzyme activity was achieved at 37 degrees C but not at 14 degrees C by inclusion of the macromolecular crowding agent polyethylene glycol in the assay. The only other mutant (pol30-6, DD41,42AA) that showed a growth defect was partially defective for interaction with replication factor C and DNA polymerase delta but completely defective for interaction with DNA polymerase epsilon. Two other mutants sensitive to DNA damage showed no defect in vitro. These results indicate that the latter mutants are specifically impaired in one or more DNA repair processes whereas pol30-6 and pol30-52 mutants show their primary defects in the basic DNA replication machinery with probable associated defects in DNA repair. Therefore, DNA repair requires interactions between repair-specific protein(s) and PCNA, which are distinct from those required for DNA replication.

Crystal structure of the eukaryotic DNA polymerase processivity factor PCNA

The crystal structure of the processivity factor required by eukaryotic DNA polymerase delta, proliferating cell nuclear antigen (PCNA) from S. cerevisiae, has been determined at 2.3 A resolution. Three PCNA molecules, each containing two topologically identical domains, are tightly associated to form a closed ring. The dimensions and electrostatic properties of the ring suggest that PCNA encircles duplex DNA, providing a DNA-bound platform for the attachment of the polymerase. The trimeric PCNA ring is strikingly similar to the dimeric ring formed by the beta subunit (processivity factor) of E. coli DNA polymerase III holoenzyme, with which it shares no significant sequence identity. This structural correspondence further substantiates the mechanistic connection between eukaryotic and prokaryotic DNA replication that has been suggested on biochemical grounds.

Cloning and characterization of the essential Saccharomyces cerevisiae RFC4 gene encoding the 37-kDa subunit of replication factor C

The RFC4 gene encoding the 37-kDa subunit of Saccharomyces cerevisiae replication factor C (RF-C) has been cloned and sequenced. The RFC4 gene encodes a 323-amino acid polypeptide with a molecular weight of 36,126. The deduced amino acid sequence of the RFC4 gene shows high sequence similarity to the other two small subunits of yeast RF-C and the three small subunits of human RF-C (35-60% identity, 55-78% similarity). The similarity is greatest with the 40-kDa subunit of human RF-C (also called Activator 1). Despite the presence of a MluI cell cycle box in the regulatory region of the RFC4 gene, the steady state levels of its mRNA do not change significantly during the yeast mitotic cell cycle. The RFC4 gene is essential for yeast viability and is located on the left arm of chromosome XV, between the SUF1 and ADH1 genes. The essential role of this as well as the other small subunits of RF-C indicates a unique function for each of these subunits, despite their apparent structural redundancy. Rfc4p was overexpressed in Escherichia coli. Despite the presence of consensus ATPase motifs in the primary amino acid sequence, no discernible biochemical function could be ascribed to the purified protein. However, Rfc4p formed a tight complex with the product of the RFC3 gene which encodes the ATPase of RF-C.

Molecular cloning and expression of the Saccharomyces cerevisiae RFC3 gene, an essential component of replication factor C

Yeast replication factor C (RF-C) is a multi-polypeptide complex required for processive DNA replication by DNA polymerases delta and epsilon. The gene encoding the 40-kDa subunit of the Saccharomyces cerevisiae RF-C (RFC3) has been cloned. The RFC3 gene is required for yeast cell growth and has been mapped to the left arm of chromosome XIV. The deduced amino acid sequence of the RFC3 gene shows a high homology to the 36-, 37-, and 40-kDa subunits of human RF-C (also called activator 1), with the highest homology to the 36-kDa subunit. Among the conserved regions are the A motif of ATP binding proteins; the "DEAD box," common to DNA helicases and other ATPases; and the "RFC box," an approximately 15-amino acid domain virtually identical in the yeast and human RF-C subunits. Limited homology to the functional homologs of the Escherichia coli replication apparatus was also observed. The steady-state mRNA levels of RFC3 do not change significantly during the mitotic cell cycle of yeast. The intact form of the RFC3 gene product (Rfc3p) has been overproduced in E. coli and purified to homogeneity. Purified Rfc3p has an ATPase activity that is markedly stimulated by single-stranded DNA but not by double-stranded DNA or RNA.

ATP-independent loading of the proliferating cell nuclear antigen requires DNA ends

The proliferating cell nuclear antigen (PCNA) is a processivity subunit for eukaryotic DNA polymerase delta. We present biochemical evidence that yeast PCNA likely adopts a toroidal structure containing an inside cavity through which double-stranded DNA slides. A comparative study of DNA replication reactions on circular versus linear model substrates shows that PCNA can only interact productively with DNA polymerase delta if the substrate is linear. This combined with the observation that a large molar excess of PCNA is required for maximal stimulatory activity is consistent with a model in which PCNA slips onto the end of the DNA in an ATP-independent manner.

A Saccharomyces cerevisiae DNA helicase associated with replication factor C

A novel DNA helicase has been isolated from Saccharomyces cerevisiae. This DNA helicase co-purified with replication factor C (RF-C) during chromatography on S-Sepharose, DEAE-silica gel high performance liquid chromatography (HPLC), Affi-Gel Blue-agarose, heparin-agarose, single-stranded DNA-cellulose, fast protein liquid chromatography MonoS, and hydroxyapatite HPLC. Surprisingly, the helicase could be separated from RF-C by sedimentation on a glycerol gradient in the presence of 200 mM NaCl. The helicase is probably a homodimer of a 60-kDa polypeptide, which by UV cross-linking has been shown to bind ATP. It has a single-stranded DNA-dependent ATPase activity, with a Km for ATP of 60 microM. The DNA helicase activity depends on the hydrolysis of NTP (dNTP), with ATP and dATP the most efficient cofactors, followed by CTP and dCTP. The DNA helicase has a 5' to 3' directionality and is only marginally stimulated by coating the single-stranded DNA with the yeast single-stranded DNA-binding protein RF-A.

PCNA-induced DNA synthesis past cis-syn and trans-syn-I thymine dimers by calf thymus DNA polymerase delta in vitro

Calf thymus proliferating cell nuclear antigen (PCNA) promoted DNA synthesis past cis-syn and trans-syn-I cyclobutane thymine dimers by calf thymus DNA polymerase delta (Pol delta) in vitro. Templates containing site-specific cis-syn and trans-syn-I thymine dimers were prepared via a combination of solid phase synthesis with photoproduct building blocks and DNA ligation. Extension of a 15-mer primer on the UV dimer-containing templates by Pol delta produced termination and bypass products in a dNTP and PCNA dependent manner. In the absence of PCNA and at dNTP concentrations varying between 1 and 100 microM, Pol delta could not bypass the cis-syn dimer and terminated elongation one nucleotide prior to the 3'-T of the dimer. DNA synthesis past the trans-syn-I dimer was even less efficient. In the presence of PCNA, termination occurred primarily one nucleotide prior to the 3'-T of both dimers at 1 microM dNTPs but opposite the 5'-T of the dimers at 100 microM dNTPs. In addition, under the latter conditions, bypass of the dimers was observed, to the extent of about 30% of the products for the cis-syn dimer and about 15% for the trans-syn-I dimer.

Three new DNA helicases from Saccharomyces cerevisiae

At least six DNA helicases have been identified during fractionation of extracts from the yeast Saccharomyces cerevisiae. Three of those, DNA helicases B, C, and D, have been further purified and characterized. DNA helicases B and C co-purified with DNA polymerase delta through several chromatographic steps, but were separated from the polymerase by hydrophobic chromatography. DNA helicase D co-purified with Replication Factor C over seven chromatographic steps, and was only separated from it by glycerol gradient centrifugation in the presence of 0.2 M NaCl. All three helicases are DNA dependent ATPases with Km values for ATP of 190 microM, 325 microM, and 60 microM for DNA helicases B, C, and D, respectively. Their DNA helicase activities are comparable. They are 5'-3' helicases and have pH optima of 6.5-7 and Mg2+ optima of 1-2 mM. However, they differ in the nucleotide requirement for helicase action. Whereas all three helicases preferred ATP, dATP, UTP, CTP, and dCTP as cofactors, DNA helicase C also used GTP, but not dTTP. On the other hand, DNA helicase D used dTTP, but not GTP, and DNA helicase B used neither nucleotide as cofactor. These studies allowed us to conclude that DNA helicases B, C, and D are not only distinct enzymes, but also different from two previously identified yeast DNA helicases, the RAD3 protein and ATPase III.

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.

Saccharomyces cerevisiae replication factor C. I. Purification and characterization of its ATPase activity

Saccharomyces cerevisiae replication factor C (RF-C) was purified 25,000-fold from a protease-deficient strain of yeast. RF-C is a complex of 6 subunits of 130, 86, 41, 40, 37, and 27 kDa. None of the subunits are related through proteolysis or differential phosphorylation. The assay for RF-C used as a substrate single-stranded DNA binding protein-coated singly primed single-stranded mp 18 DNA. This DNA was poorly replicated by yeast DNA polymerase delta with or without its cofactor proliferating cell nuclear antigen (PCNA). In the presence of RF-C, however, replication of the template proceeded efficiently when both ATP and PCNA were present as well. Formation of this replication-proficient complex of DNA polymerase delta required an input of one to two molecules of PCNA per replicated DNA molecule. DNA polymerase epsilon also formed an ATP-dependent complex with PCNA and RF-C. RF-C has a DNA-dependent ATPase activity, equally active on single-stranded and primed single-stranded mp18 DNA. Addition of PCNA stimulated the ATPase of RF-C on primed but not on unprimed DNA, indicating that the increase in ATPase was due to PCNA-enhanced binding of RF-C to the primer terminus. Calf thymus PCNA also stimulated the ATPase activity of yeast RF-C and participated in holoenzyme formation with DNA polymerase delta. These results attest to the structural and functional homology between yeast and mammalian cells for these components of the replication machinery.

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.

The spectrum of spontaneous mutations in a Saccharomyces cerevisiae uracil-DNA-glycosylase mutant limits the function of this enzyme to cytosine deamination repair

Uracil-DNA-glycosylase has been proposed to function as the first enzyme in strand-directed mismatch repair in eukaryotic organisms, through removal of uracil from dUMP residues periodically inserted into the DNA during DNA replication (Aprelikova, O. N., V. M. Golubovskaya, T. A. Kusmin, and N. V. Tomilin, Mutat. Res. 213:135-140, 1989). This hypothesis was investigated with Saccharomyces cerevisiae. Mutation frequencies and spectra were determined for an ung1 deletion strain in the target SUP4-o tRNA gene by using a forward selection scheme. Mutation frequencies in the SUP4-o gene increased about 20-fold relative to an isogenic wild-type S. cerevisiae strain, and the mutator effect was completely suppressed in the ung1 deletion strain carrying the wild-type UNG1 gene on a multicopy plasmid. Sixty-nine independently derived mutations in the SUP4-o gene were sequenced. All but five of these were due to GC----AT transitions. From this analysis, we conclude that the mutator phenotype of the ung1 deletion strain is the result of a failure to repair spontaneous cytosine deamination events occurring frequently in S. cerevisiae and that the UNG1 gene is not required for strand-specific mismatch repair in S. cerevisiae.

Molecular cloning, structure and expression of the yeast proliferating cell nuclear antigen gene

The budding yeast Saccharomyces cerevisiae is proving to be an useful and accurate model for eukaryotic DNA replication. It contains both DNA polymerase alpha (I) and delta (III). Recently, proliferating cell nuclear antigen (PCNA), which in mammalian cells is an auxiliary subunit of DNA polymerase delta and is essential for in vitro leading strand SV40 DNA replication, was purified from yeast. We have now cloned the gene for yeast PCNA (POL30). The gene codes for an essential protein of 29 kDa, which shows 35% homology with human PCNA. Cell cycle expression studies, using synchronized cells, show that expression of both the PCNA (POL30) and the DNA polymerase delta (POL3, or CDC2) genes of yeast are regulated in an identical fashion to that of the DNA polymerase alpha (POL1) gene. Thus, steady state mRNA levels increase 10-100-fold in late G1 phase, peak in early S-phase, and decrease to low levels in late S-phase. In addition, in meiosis mRNA levels increase prior to initiation of premeiotic DNA synthesis.

Structure and function of the Saccharomyces cerevisiae CDC2 gene encoding the large subunit of DNA polymerase III

Saccharomyces cerevisiae cdc2 mutants arrest in the S-phase of the cell cycle when grown at the non-permissive temperature, implicating this gene product as essential for DNA synthesis. The CDC2 gene has been cloned from a yeast genomic library in vector YEp13 by complementation of a cdc2 mutation. An open reading frame coding for a 1093 amino acid long protein with a calculated mol. wt of 124,518 was determined from the sequence. This putative protein shows significant homology with a class of eukaryotic DNA polymerases exemplified by human DNA polymerase alpha and herpes simplex virus DNA polymerase. Fractionation of extracts from cdc2 strains showed that these mutants lacked both the polymerase and proofreading 3'-5' exonuclease activity of DNA polymerase III, the yeast analog of mammalian DNA polymerase delta. These studies indicate that DNA polymerase III is an essential component of the DNA replication machinery.

Molecular cloning and primary structure of the uracil-DNA-glycosylase gene from Saccharomyces cerevisiae

The structural gene for the Saccharomyces cerevisiae repair enzyme uracil-DNA-glycosylase (UNG1) was selected from a yeast genomic library in the multicopy vector YEp24 by complementation of the ung1-1 mutant in in vitro enzyme assays. The sequenced gene has an open reading frame which codes for a protein with molecular weight of 40,471. The measured size of the mRNA of 1.25 kb is in agreement with the predicted molecular weight of the protein. The gene product was overproduced about 100-fold in strains carrying an UNG1 gene containing plasmid at 100-200 copies/cell. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of cleared lysates from such an overproducing strain, followed by renaturation of enzyme activity from individual gel slices showed the presence of two enzymatic activities in comparable quantities with Mr values of 39,500 and 33,000, indicating that the full size protein is either readily degraded in vivo or is very sensitive to proteolytic digestion in vitro. The carboxyl-terminal two-thirds of the yeast uracil-DNA-glycosylase is highly homologous to the entire Escherichia coli enzyme (50% amino acid identity). Genetic mapping experiments have localized the UNG1 gene on the left arm of chromosome XIII at 17 cM from the GAL80 locus proximal to the centromer. Deletions of the UNG1 gene are viable.

Protein-protein interactions of yeast DNA polymerase III with mammalian and yeast proliferating cell nuclear antigen (PCNA)/cyclin

We have previously reported the purification of yeast analogs to mammalian DNA polymerase delta and proliferating-cell nuclear antigen (PCNA)/cyclin: DNA polymerase III and yeast PCNA, respectively. Through the use of gel-filtration chromatography, we have studied the interaction of the model template-primer system poly(dA).(dT)16 (40:1) with yeast DNA polymerase III and with PCNAs. Yeast DNA polymerase III binds to the DNA in the absence of yeast PCNA/cyclin, but comigration of either yeast or calf thymus PCNA/cyclin with the DNA requires the additional presence of yeast DNA polymerase III. We could also isolate a DNA-calf thymus DNA polymerase delta-calf thymus PCNA/cyclin complex. From these data, we propose that PCNA/cyclin is involved not in the binding step of the polymerase to the template-primer, but in the elongation step. The 3'----5' exonuclease associated with yeast DNA polymerase III acts in a distributive manner on poly(dA).(pT)16, and dissociates from the DNA when addition of dTTP allows switching from the exonuclease to the polymerase mode. Addition of PCNA/cyclin had no effect on these activities.

The yeast analog of mammalian cyclin/proliferating-cell nuclear antigen interacts with mammalian DNA polymerase delta

DNA polymerase III from Saccharomyces cerevisiae is analogous to the mammalian DNA polymerase delta by several criteria, including an increased synthetic activity on poly(dA).oligo(dT) (40:1 nucleotide ratio) in the presence of calf thymus proliferating-cell nuclear antigen (PCNA), or cyclin. This stimulation assay has been used to purify the yeast analog of PCNA/cyclin (yPCNA) to homogeneity. yPCNA is a trimer or tetramer (Mr approximately 82,000) of identical subunits with a denatured Mr of 26,000. On a molar basis yPCNA and calf thymus PCNA/cyclin are equally active in stimulating DNA synthesis by DNA polymerase III. About 10 times more yPCNA than calf thymus PCNA/cyclin is needed, however, to stimulate calf thymus DNA polymerase delta, and the degree of stimulation obtained at saturating levels of yPCNA is a factor of 2-3 less than with calf thymus PCNA/cyclin. Both stimulatory proteins exert their effect in an identical fashion, i.e., by increasing the processivity of the DNA polymerase. Yeast DNA polymerases I and II and calf thymus DNA polymerase alpha are not stimulated by yPCNA. Treatment of logarithmic-phase cells with hydroxyurea blocks them in the S phase and produces a 4- to 5-fold increase in yPCNA.

Mammalian cyclin/PCNA (DNA polymerase delta auxiliary protein) stimulates processive DNA synthesis by yeast DNA polymerase III

Human cyclin/PCNA (proliferating cell nuclear antigen) is structurally, functionally, and immunologically homologous to the calf thymus auxiliary protein for DNA polymerase delta. This auxiliary protein has been investigated as a stimulatory factor for the nuclear DNA polymerases from S. cerevisiae. Calf cyclin/PCNA enhances by more than ten-fold the ability of DNA polymerase III to replicate templates with high template/primer ratios, e.g. poly(dA).oligo(dT) (40:1). The degree of stimulation increases with the template/primer ratio. At a high template/primer ratio, i.e. low primer density, cyclin/PCNA greatly increases processive DNA synthesis by DNA polymerase III. At low template/primer ratios (e.g. poly(dA).oligo(dT) (2.5:1), where addition of cyclin/PCNA only minimally increases the processivity of DNA polymerase III, a several-fold stimulation of total DNA synthesis is still observed. This indicates that cyclin/PCNA may also increase productive binding of DNA polymerase III to the template-primer and stabilize the template-primer-polymerase complex. The activity of yeast DNA polymerases I and II is not affected by addition of cyclin/PCNA. These results strengthen the hypothesis that yeast DNA polymerase III is functionally analogous to the mammalian DNA polymerase delta.

Exonuclease V from Saccharomyces cerevisiae. A 5'----3'-deoxyribonuclease that produces dinucleotides in a sequential fashion

A novel deoxyribonuclease, exonuclease V, has been purified approximately 30,000-fold from Saccharomyces cerevisiae. Exonuclease V is localized in the nucleus. The nuclease degrades single-stranded, but not double-stranded, DNA from the 5'-end. The products of exonuclease action are dinucleotides, except the 3'-terminal tri- and tetranucleotides which are not degraded. Studies with synthetic oligo- and polynucleotides with specified sequence elements showed that exonuclease V cleaves off dinucleotides as primary digestion products. Thus, the polymers (pT)9pA(pT)n and (pT)10pA(pT)n yielded pTpA and pApT as digestion products, respectively. Removal of the 5'-terminal phosphate from the DNA substrate results in reduced binding of the enzyme to the substrate. In addition, the initial hydrolytic cut by exonuclease V on the dephosphorylated substrate produces a mixture of dinucleoside monophosphates and trinucleoside diphosphates. The enzyme is processive in action.

DNA polymerase III from Saccharomyces cerevisiae. II. Inhibitor studies and comparison with DNA polymerases I and II

The newly identified yeast DNA polymerase III was compared to DNA polymerases I and II and the mitochondrial DNA polymerase. Inhibition by aphidicolin (I50) of DNA polymerases I, II, and III was 4, 6, and 0.6 micrograms/ml, respectively. The mitochondrial enzyme was insensitive to the drug. N2-(p-n-butylphenyl)-2'-deoxyguanosine 5'-triphosphate strongly inhibited DNA polymerase I (I50 = 0.3 microM), whereas DNA polymerase III was less sensitive (I50 = 80 microM). Conditions that allowed proteolysis to proceed during the preparation of extracts converted DNA polymerase II from a sensitive form (I50 = 2.4 microM) to a resistant form (I50 = 2 mM). The mitochondrial DNA polymerase is insensitive (I50 greater than 5 mM). With most other inhibitors tested (N-ethylmaleimide, heparin, salt) only small differences were observed between the three nuclear DNA polymerases. Polyclonal antibodies to DNA polymerase III did not inhibit DNA polymerases I and II, nor were those polymerases recognized by Western blotting. Monoclonal antibodies to DNA polymerase I did not crossreact with DNA polymerases II and III. The results show that DNA polymerase III is distinct from DNA polymerase I and II.

DNA polymerase III from Saccharomyces cerevisiae. I. Purification and characterization

Yeast cells from a wild type or protease-deficient strain were lysed in the absence or presence of protease inhibitors and the extracts analyzed by analytical high pressure liquid chromatography on diethylaminoethyl silica gel. Conditions that inhibited protease action caused elution of a novel DNA polymerase activity at a position in the gradient distinct from the elution positions of both DNA polymerase I and II. In large scale purifications, this DNA polymerase, called DNA polymerase III, copurified with a single-stranded DNA dependent 3'-5' exonuclease activity, exonuclease III, to near homogeneity. Glycerol gradient centrifugation partially dissociated the complex to yield two peaks of exonuclease III activity, one at 7.7 S together with the DNA polymerase, and one at 4.0 S without polymerase activity. Gel filtration indicated that the complex has a molecular mass greater than 400 kDa. Polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate indicated that the complex consists of several subunits: 140, 62, 55, and 53 kilodaltons, some of which may be proteolysis products. The exonuclease component of the complex can excise single nucleotide mismatches providing a base-paired primer-template which can be elongated by the DNA polymerase. Under replication conditions, the complex exhibits a measurable turnover rate of dTTP to dTMP and it contains no primase activity. The enzymatic activities of the 3'-5' exonuclease are consistent with a proofreading function during in vivo DNA replication. A second exonuclease activity, exonuclease IV, separated from the complex late in the purification scheme. It degrades both single-stranded and double-stranded DNA in the 5'----3' direction.