A novel processive mechanism for DNA synthesis revealed by structure, modeling and mutagenesis of the accessory subunit of human mitochondrial DNA polymerase

Mitochondrial DNA polymerase (pol gamma) is the sole DNA polymerase responsible for replication and repair of animal mitochondrial DNA. Here, we address the molecular mechanism by which the human holoenzyme achieves high processivity in nucleotide polymerization. We have determined the crystal structure of human pol gamma-beta, the accessory subunit that binds with high affinity to the catalytic core, pol gamma-alpha, to stimulate its activity and enhance holoenzyme processivity. We find that human pol gamma-beta shares a high level of structural similarity to class IIa aminoacyl tRNA synthetases, and forms a dimer in the crystal. A human pol gamma/DNA complex model was developed using the structures of the pol gamma-beta dimer and the bacteriophage T7 DNA polymerase ternary complex, which suggests multiple regions of subunit interaction between pol gamma-beta and the human catalytic core that allow it to encircle the newly synthesized double-stranded DNA, and thereby enhance DNA binding affinity and holoenzyme processivity. Biochemical properties of a novel set of human pol gamma-beta mutants are explained by and test the model, and elucidate the role of the accessory subunit as a novel type of processivity factor in stimulating pol gamma activity and in enhancing processivity.     

Functional interaction between Epstein-Barr virus DNA polymerase catalytic subunit and its accessory subunit in vitro.

The Epstein-Barr virus (EBV) DNA polymerase catalytic subunit (BALF5 protein) and its accessory subunit (BMRF1 protein) have been independently overexpressed and purified (T. Tsurumi, A. Kobayashi, K. Tamai, T. Daikoku, R. Kurachi, and Y. Nishiyama, J. Virol. 67:4651-4658, 1993; T. Tsurumi, J. Virol. 67:1681-1687, 1993). In an investigation of the molecular basis of protein-protein interactions between the subunits of the EBV DNA polymerase holoenzyme, we compared the DNA polymerase activity catalyzed by the BALF5 protein in the presence or absence of the BMRF1 polymerase accessory subunit in vitro. The DNA polymerase activity of the BALF5 polymerase catalytic subunit alone was sensitive to high ionic strength on an activated DNA template (80% inhibition at 100 mM ammonium sulfate). Addition of the polymerase accessory subunit to the reaction greatly enhanced DNA polymerase activity in the presence of high concentrations of ammonium sulfate (10-fold stimulation at 100 mM ammonium sulfate). Optimal stimulation was obtained when the molar ratio of BMRF1 protein to BALF5 protein was 2 or more. The DNA polymerase activity of the BALF5 protein along with the BMRF1 protein was neutralized by a monoclonal antibody to the BMRF1 protein, whereas that of the BALF5 protein alone was not, suggesting a specific interaction between the BALF5 protein and the BMRF1 protein in the reaction. The processivity of nucleotide polymerization of the BALF5 polymerase catalytic subunit on singly primed M13 single-stranded DNA circles was low (approximately 50 nucleotides). Addition of the BMRF1 polymerase accessory subunit resulted in a strikingly high processive mode of deoxynucleotide polymerization (> 7,200 nucleotides). These findings strongly suggest that the BMRF1 polymerase accessory subunit stabilizes interaction between the EBV DNA polymerase and primer template and functions as a sliding clamp at the growing 3'-OH end of the primer terminus to increase the processivity of polymerization.     

Linear diffusion on DNA despite high-affinity binding by a DNA polymerase processivity factor.

The oligomeric "sliding clamp" processivity factors, such as PCNA, are thought to rely on a loose, topological association with DNA to slide freely along dsDNA. Unlike PCNA, the processivity subunit of the herpes simplex virus DNA polymerase, UL42, is a monomer and has an intrinsic affinity for dsDNA that is remarkably high for a sequence-independent DNA binding protein. Using a DNase footprinting assay, we demonstrate that UL42 translocates with the catalytic subunit of the polymerase during chain elongation. In addition, footprinting and electrophoretic mobility shift assays show that, despite its tight DNA binding, UL42 is capable of linear diffusion on DNA at a rate of between 17 and 47 bp/s. Our results thus suggest that, despite profound biochemical differences with the sliding clamps, UL42 can freely slide downstream with the catalytic subunit during DNA replication.     

Mutations that specifically impair the DNA binding activity of the herpes simplex virus protein UL42.

The herpes simplex virus DNA polymerase is a heterodimer consisting of a catalytic subunit and the protein UL42, which functions as a processivity factor. It has been hypothesized that UL42 tethers the catalytic subunit to the DNA template by virtue of DNA binding activity (J. Gottlieb, A. I. Marcy, D. M. Coen, and M. D. Challberg, J. Virol. 64:5976-5987, 1990). Relevant to this hypothesis, we identified two linker insertion mutants of UL42 that were unable to bind to a double-stranded-DNA-cellulose column but retained their ability to bind the catalytic subunit. These mutants were severely impaired in the stimulation of long-chain-DNA synthesis by the catalytic subunit in vitro. In transfected cells, the expressed mutant proteins localized to the nucleus but were nonetheless deficient in complementing the growth of a UL42 null virus. Thus, unlike many other processivity factors, UL42 appears to require an intrinsic DNA binding activity for its function both in vitro and in infected cells. Possible mechanisms for the activity of UL42 and its potential as a drug target are discussed.     

Human mitochondrial DNA polymerase holoenzyme: reconstitution and characterization

We have reconstituted the holoenzyme of the human mitochondrial DNA polymerase from cloned and overexpressed catalytic and accessory subunits. We have examined the polymerization activity of the catalytic subunit alone and of the holoenzyme to establish the function of the accessory subunit in this two subunit enzyme. The accessory subunit associates with the catalytic subunit with a dissociation constant of 35 +/- 16 nM as measured by the concentration dependence of its effect in stimulating maximal DNA binding and polymerization. At saturating concentrations, the accessory subunit contributes to every kinetic parameter examined to facilitate tighter binding of DNA and nucleotide and faster replication. The accessory protein makes the DNA binding 3.5-fold tighter (K(d) of 9.9 +/- 2.1 nM compared to 39 +/- 10 nM for the catalytic subunit alone) without significantly affecting the DNA dissociation rate (0.02 +/- 0.001 compared to 0.03 +/- 0.001 s(-)(1)). The ground-state nucleotide binding is improved from 4.7 +/- 2.0 to 0.78 +/- 0.065 microM, and the maximum DNA polymerization rate is increased from 8.7 +/- 1.1 to 45 +/- 1 s(-)(1) by the addition of the accessory protein. This leads to an increase in processivity from an estimated 290 +/- 46 to 2250 +/- 162. Although the accessory protein has been described as a "processivity factor" because of its effect on the ratio of rate constants defining processivity, this terminology falls short of adequately describing the profound effects of the small subunit on nucleotide-binding and incorporation catalyzed by the large subunit. By using the complete holoenzyme, we can now proceed with a comprehensive analysis of the structural and mechanistic determinants of enzyme specificity that govern toxicity of nucleoside analogues used in the treatment of viral infections such as AIDS.     

C-terminal extension of the yeast mitochondrial DNA polymerase determines the balance between synthesis and degradation

Saccharomyces cerevisiae mitochondrial DNA polymerase (Mip1) contains a C-terminal extension (CTE) of 279 amino acid residues. The CTE is required for mitochondrial DNA maintenance in yeast but is absent in higher eukaryotes. Here we use recombinant Mip1 C-terminal deletion mutants to investigate functional importance of the CTE. We show that partial removal of the CTE in Mip1Δ216 results in strong preference for exonucleolytic degradation rather than DNA polymerization. This disbalance in exonuclease and polymerase activities is prominent at suboptimal dNTP concentrations and in the absence of correctly pairing nucleotide. Mip1Δ216 also displays reduced ability to synthesize DNA through double-stranded regions. Full removal of the CTE in Mip1Δ279 results in complete loss of Mip1 polymerase activity, however the mutant retains its exonuclease activity. These results allow us to propose that CTE functions as a part of Mip1 polymerase domain that stabilizes the substrate primer end at the polymerase active site, and is therefore required for efficient mitochondrial DNA replication in vivo.     

Protein sequences conserved in prokaryotic aminoacyl-tRNA synthetases are important for the activity of the processivity factor of human mitochondrial DNA polymerase

Previous studies have shown that the small subunit of Xenopus DNA polymerase gamma (pol gammaB) acts as a processivity factor to stimulate the 140 kDa catalytic subunit of human DNA polymerase gamma. A putative human pol gammaB initially identified by analysis of DNA sequence had not been shown to be functional, and appeared to be an incomplete clone. In this paper, we report the cloning of full-length human and mouse pol gammaB. Both human and mouse pol gammaB proteins were expressed in their mature forms, without their apparent mitochondrial localization signals, and shown to stimulate processivity of the recombinant catalytic subunit of human pol gammaA. Deletion analysis of human pol gammaB indicated that blocks of sequence conserved with prokaryotic class II aminoacyl-tRNA synthetases are necessary for activity and inter-action with human pol gammaA. Purification of DNA pol gamma from HeLa cells indicated that both proteins are associated in vivo.     

Vaccinia virus uracil DNA glycosylase interacts with the A20 protein to form a heterodimeric processivity factor for the viral DNA polymerase

The vaccinia virus E9 protein, the catalytic subunit of the DNA polymerase holoenzyme, is inherently distributive under physiological conditions, although infected cells contain a highly processive form of the enzyme. The viral A20 protein was previously characterized as a stoichiometric component of the processivity factor, and an interaction between A20 and E9 was documented in vivo. A20 has been shown to interact with D4, the virally encoded uracil DNA glycosylase (UDG), by yeast-two hybrid and in vitro analysis. Here we confirm that UDG and A20 interact in vivo and show that temperature-sensitive viruses with lesions in the D4R gene show a profound defect in DNA synthesis at the non-permissive temperature. Moreover, cytoplasmic extracts prepared from these infections lack processive polymerase activity in vitro, implicating D4 in the assembly or activity of the processive polymerase. Upon overexpression of 3xFLAG-UDG, A20, and E9 in various combinations, we purified dimeric and trimeric UDG-A20 and UDG-A20-polymerase complexes, respectively. These complexes are stable in 750 mm NaCl and can be further purified by Mono Q chromatography. Notably, the trimeric complex displays robust processive polymerase activity, and the dimeric complex can confer processivity on purified E9. Consistent with previous reports that the catalytic activity of UDG is dispensable for virus replication in tissue culture, we find that the role of UDG role in the polymerase complex is not diminished by mutations targeting residues involved in uracil recognition or excision. Our cumulative data support the conclusion that A20 and UDG form a heterodimeric processivity factor that associates with E9 to comprise the processive polymerase holoenzyme.     

The small subunit is required for functional interaction of DNA polymerase delta with the proliferating cell nuclear antigen.

DNA polymerase delta is usually isolated as a heterodimer composed of a 125 kDa catalytic subunit and a 50 kDa small subunit of unknown function. The enzyme is distributive by itself and requires an accessory protein, the proliferating cell nuclear antigen (PCNA), for highly processive DNA synthesis. We have recently demonstrated that the catalytic subunit of human DNA polymerase delta (p125) expressed in baculovirus-infected insect cells, in contrast to the native heterodimeric calf thymus DNA polymerase delta, is not responsive to stimulation by PCNA. To determine whether the lack of response to PCNA of the recombinant catalytic subunit is due to the absence of the small subunit or to differences in post-translational modification in insect cells versus mammalian cells, we have co-expressed the two subunits of human DNA polymerase delta in insect cells. We have demonstrated that co-expression of the catalytic and small subunits of human DNA polymerase delta results in formation of a stable, fully functional heterodimer, that the recombinant heterodimer, similar to native heterodimer, is markedly stimulated (40- to 50-fold) by PCNA and that the increase in activity seen in the presence of PCNA is the result of an increase in processivity. These data establish that the 50 kDa subunit is essential for functional interaction of DNA polymerase delta with PCNA and for highly processive DNA synthesis.     

A p.R369G POLG2 mutation associated with adPEO and multiple mtDNA deletions causes decreased affinity between polymerase γ subunits

Human mitochondrial DNA (mtDNA) polymerase γ (pol γ) is the sole enzyme required to replicate and maintain the integrity of the mitochondrial genome. It comprises two subunits, a catalytic p140 subunit and a smaller p55 accessory subunit encoded by the POLG2 gene. We describe the molecular characterization of a potential dominant POLG2 mutation (p.R369G) in a patient with adPEO and multiple mtDNA deletions. Biochemical studies of the recombinant mutant p55 protein showed a reduced affinity to the pol γ p140 subunit, leading to impaired processivity of the holoenzyme complex but did not show sensitivity to N-ethylmalaimide (NEM) inhibition, inferring a novel disease mechanism.     

单纯疱疹病毒1型DNA聚合酶辅助亚基UL42的研究进展

单纯疱疹病毒1型(Herpes simplex virus type 1, HSV-1) UL42作为病毒编码的DNA聚合酶辅助亚基之一，是一种多功能蛋白，其在催化和调节病毒在细胞核内的有效复制发挥了重要的作用。已知UL42能提高DNA聚合酶催化亚基UL30的持续合成能力，激活病毒DNA聚合酶活性；介导DNA聚合酶的入核；与DNA模板链结合，提高病毒复制的保真度，以及含有抑制DNA聚合酶活性的肽段，提示其在病毒复制过程中也可能具有负调控作用。近期亦有报道显示，UL42能够阻断肿瘤坏死因子α(tumor necrosis factor-α， TNF-α)激活的核转录因子(nuclear factor kappa-B，NF-κB)信号通路以及干扰素调控因子3(interferon regulatory factor 3, IRF-3)的功能，提示其在病毒逃逸宿主天然免疫反应中发挥了一定的功能，但具体的作用机制尚不明确。本文对目前国内外HSV-1 UL42的结构特点、主要功能、作用机制及其在抗病毒药物研发中的研究进展进行综述，为后续揭示病毒致病机制和抗病毒药物的研发提供参考。     

Crystal Structure of Epstein-Barr Virus DNA Polymerase Processivity Factor BMRF1

The DNA polymerase processivity factor of the Epstein-Barr virus, BMRF1, associates with the polymerase catalytic subunit, BALF5, to enhance the polymerase processivity and exonuclease activities of the holoenzyme. In this study, the crystal structure of C-terminally truncated BMRF1 (BMRF1-ΔC) was solved in an oligomeric state. The molecular structure of BMRF1-ΔC shares structural similarity with other processivity factors, such as herpes simplex virus UL42, cytomegalovirus UL44, and human proliferating cell nuclear antigen. However, the oligomerization architectures of these proteins range from a monomer to a trimer. PAGE and mutational analyses indicated that BMRF1-ΔC, like UL44, forms a C-shaped head-to-head dimer. DNA binding assays suggested that basic amino acid residues on the concave surface of the C-shaped dimer play an important role in interactions with DNA. The C95E mutant, which disrupts dimer formation, lacked DNA binding activity, indicating that dimer formation is required for DNA binding. These characteristics are similar to those of another dimeric viral processivity factor, UL44. Although the R87E and H141F mutants of BMRF1-ΔC exhibited dramatically reduced polymerase processivity, they were still able to bind DNA and to dimerize. These amino acid residues are located near the dimer interface, suggesting that BMRF1-ΔC associates with the catalytic subunit BALF5 around the dimer interface. Consequently, the monomeric form of BMRF1-ΔC probably binds to BALF5, because the steric consequences would prevent the maintenance of the dimeric form. A distinctive feature of BMRF1-ΔC is that the dimeric and monomeric forms might be utilized for the DNA binding and replication processes, respectively.     

Purification and characterization of DNA polymerase II from the yeast Saccharomyces cerevisiae. Identification of the catalytic core and a possible holoenzyme form of the enzyme

We have purified yeast DNA polymerase II to near homogeneity as a 145-kDa polypeptide. During the course of this purification we have detected and purified a novel form of DNA polymerase II that we designate as DNA polymerase II. The most highly purified preparations of DNA polymerase II are composed of polypeptides with molecular masses of 200, 80, 34, 30, and 29 kDa. Immunological analysis and peptide mapping of DNA polymerase II and the 200-kDa subunit of DNA polymerase II indicate that the 145-kDa DNA polymerase II polypeptide is derived from the 200-kDa polypeptide of DNA polymerase II. Activity gel analysis shows that the 145- and the 200-kDa polypeptides have catalytic function. The polypeptides present in the DNA polymerase II preparation copurify with the polymerase activity with a constant relative stoichiometry during chromatography over five columns and co-sediment with the activity during glycerol gradient centrifugation, suggesting that this complex may be a holoenzyme form of DNA polymerase II. Both forms of DNA polymerase II possess a 3'-5' exonuclease activity that remains tightly associated with the polymerase activity during purification. DNA polymerase II is similar to the proliferating cell nuclear antigen (PCNA)-independent form of mammalian DNA polymerase delta in its resistance to butylpheny-dGTP, template specificity, stimulation of polymerase and exonuclease activity by KCl, and high processivity. Although calf thymus PCNA does not stimulate the activity of DNA polymerase II on poly(dA):oligo(dT), possibly due to the limited length of the template, the high processivity of yeast DNA polymerase II on this template can be further increased by the addition of PCNA, suggesting that conditions may exist for interactions between PCNA and yeast DNA polymerase II.     

Effects of substitutions of arginine residues on the basic surface of herpes simplex virus UL42 support a role for DNA binding in processive DNA synthesis

The way that UL42, the processivity subunit of the herpes simplex virus DNA polymerase, interacts with DNA and promotes processivity remains unclear. A positively charged face of UL42 has been proposed to participate in electrostatic interactions with DNA that would tether the polymerase to a template without preventing its translocation via DNA sliding. An alternative model proposes that DNA binding by UL42 is not important for processivity. To investigate these issues, we substituted alanine for each of four conserved arginine residues on the positively charged surface. Each single substitution decreased the DNA binding affinity of UL42, with 14- to 30-fold increases in apparent dissociation constants. The mutant proteins exhibited no meaningful change in affinity for binding to the C terminus of the catalytic subunit of the polymerase, indicating that the substitutions exert a specific effect on DNA binding. The substitutions decreased UL42-mediated long-chain DNA synthesis by the polymerase in the same rank order in which they affected DNA binding, consistent with a role for DNA binding in polymerase processivity. Combining these substitutions decreased DNA binding further and impaired the complementation of a UL42 null virus in transfected cells. Additionally, using a revised mathematical model to analyze rates of dissociation of UL42 from DNAs of various lengths, we found that dissociation from internal sites, which would be the most important for tethering the polymerase, was relatively slow, even at ionic strengths that permit processive DNA synthesis by the holoenzyme. These data provide evidence that the basic surface of UL42 interacts with DNA and support a model in which DNA binding by UL42 is important for processive DNA synthesis.     

Antimutator alleles of yeast DNA polymerase gamma modulate the balance between DNA synthesis and excision

Mutations in mitochondrial DNA (mtDNA) are an important cause of disease and perhaps aging in human. DNA polymerase gamma (pol γ), the unique replicase inside mitochondria, plays a key role in the fidelity of mtDNA replication through selection of the correct nucleotide and 3'-5' exonuclease proofreading. For the first time, we have isolated and characterized antimutator alleles in the yeast pol γ (Mip1). These mip1 mutations, localised in the 3'-5' exonuclease and polymerase domains, elicit a 2-15 fold decrease in the frequency of mtDNA point mutations in an msh1-1 strain which is partially deficient in mtDNA mismatch-repair. In vitro experiments show that in all mutants the balance between DNA synthesis and exonucleolysis is shifted towards excision when compared to wild-type, suggesting that in vivo more opportunity is given to the editing function for removing the replicative errors. This results in partial compensation for the mismatch-repair defects and a decrease in mtDNA point mutation rate. However, in all mutants but one the antimutator trait is lost in the wild-type MSH1 background. Accordingly, the polymerases of selected mutants show reduced oligonucleotide primed M13 ssDNA synthesis and to a lesser extent DNA binding affinity, suggesting that in mismatch-repair proficient cells efficient DNA synthesis is required to reach optimal accuracy. In contrast, the Mip1-A256T polymerase, which displays wild-type like DNA synthesis activity, increases mtDNA replication fidelity in both MSH1 and msh1-1 backgrounds. Altogether, our data show that accuracy of wild-type Mip1 is probably not optimal and can be improved by specific (often conservative) amino acid substitutions that define a pol γ area including a loop of the palm subdomain, two residues near the ExoII motif and an exonuclease helix-coil-helix module in close vicinity to the polymerase domain. These elements modulate in a subtle manner the balance between DNA polymerization and excision.     

3' to 5' exonuclease activity of herpes simplex virus type 1 DNA polymerase modulates its strand displacement activity

Using a minicircle DNA primer-template, the wild-type catalytic subunit of herpes simplex virus type 1 (HSV-1) DNA polymerase (pol) was shown to lack significant strand displacement activity with or without its processivity factor, UL42. However, an exonuclease-deficient (exo(-)) pol (D368A) was capable of slow strand displacement. Although UL42 increased the rate (2/s) and processivity of strand displacement by exo(-) pol, the rate was slower than that for gap-filling synthesis. High inherent excision rates on matched primer-templates and rapid idling-turnover (successive rounds of excision and polymerization) of exo-proficient polymerases correlated with poor strand displacement activity. The results suggest that the exo activity of HSV-1 pol modulates its ability to engage in strand displacement, a function that may be important to the viability and genome stability of the virus.     

Mutations in the spacer region of Drosophila mitochondrial DNA polymerase affect DNA binding, processivity, and the balance between Pol and Exo function

The catalytic subunit (alpha) of mitochondrial DNA polymerase (pol gamma) shares conserved DNA polymerase and 3'-5' exonuclease active site motifs with Escherichia coli DNA polymerase I and bacteriophage T7 DNA polymerase. A major difference between the prokaryotic and mitochondrial proteins is the size and sequence of the region between the exonuclease and DNA polymerase domains, referred to as the spacer in pol gamma-alpha. Four gamma-specific conserved sequence elements are located within the spacer region of the catalytic subunit in eukaryotic species from yeast to humans. To elucidate the functional roles of the spacer region, we pursued deletion and site-directed mutagenesis of Drosophila pol gamma. Mutant proteins were expressed from baculovirus constructs in insect cells, purified to near homogeneity, and analyzed biochemically. We find that mutations in three of the four conserved sequence elements within the spacer alter enzyme activity, processivity, and/or DNA binding affinity. In addition, several mutations affect differentially DNA polymerase and exonuclease activity and/or functional interactions with mitochondrial single-stranded DNA-binding protein. Based on these results and crystallographic evidence showing that the template-primer binds in a cleft between the exonuclease and DNA polymerase domains in family A DNA polymerases, we propose that conserved sequences within the spacer of pol gamma may position the substrate with respect to the enzyme catalytic domains.     

A novel strategy to engineer DNA polymerases for enhanced processivity and improved performance in vitro

Mechanisms that allow replicative DNA polymerases to attain high processivity are often specific to a given polymerase and cannot be generalized to others. Here we report a protein engineering-based approach to significantly improve the processivity of DNA polymerases by covalently linking the polymerase domain to a sequence non-specific dsDNA binding protein. Using Sso7d from Sulfolobus solfataricus as the DNA binding protein, we demonstrate that the processivity of both family A and family B polymerases can be significantly enhanced. By introducing point mutations in Sso7d, we show that the dsDNA binding property of Sso7d is essential for the enhancement. We present evidence supporting two novel conclusions. First, the fusion of a heterologous dsDNA binding protein to a polymerase can increase processivity without compromising catalytic activity and enzyme stability. Second, polymerase processivity is limiting for the efficiency of PCR, such that the fusion enzymes exhibit profound advantages over unmodified enzymes in PCR applications. This technology has the potential to broadly improve the performance of nucleic acid modifying enzymes.     

Purification and characterization of the 180- and 86-kilodalton subunits of the Saccharomyces cerevisiae DNA primase-DNA polymerase protein complex. The 180-kilodalton subunit has both DNA polymerase and 3'----5'-exonuclease activities.

The yeast Saccharomyces cerevisiae catalytic DNA polymerase I 180-kDa subunit and the tightly associated 86-kDa polypeptide have been purified using immunoaffinity chromatography, permitting further characterization of the DNA polymerase activity of the DNA primase-DNA polymerase protein complex. The subunits were purified to apparent homogeneity from separate overproducing yeast strains using monoclonal antibodies specifically recognizing each subunit. When the individual subunits were recombined in vitro a p86p180 physical complex formed spontaneously, as judged by immunoprecipitation of 180-kDa polypeptide and DNA polymerase activity with the anti-86-kDa monoclonal antibody. The 86-kDa subunit stabilized the DNA polymerase activity of the 180-kDa catalytic subunit at 30 degrees C, the physiological temperature. The apparent DNA polymerase processivity of 50-60 nucleotides on poly(dA).oligo(dT)12 or poly(dT).oligo(A)8-12 template-primer was not affected by the presence of the 86-kDa subunit but was reduced by increased Mg2+ concentration. The Km of the catalytic 180-kDa subunit for dATP or DNA primer terminus was unaffected by the presence of the 86-kDa subunit. The isolated 180-kDa polypeptide was sufficient to catalyze all the DNA synthesis that had been observed previously in the DNA primase-DNA polymerase protein complex. The 180-kDa subunit possessed a 3'----5'-exonuclease activity that catalyzed degradation of polynucleotides, but degradation of oligonucleotide substrates of chain lengths up to 50 was not detected. This exonuclease activity was unaffected by the presence of the 86-kDa subunit. Despite the striking physical similarity of the DNA primase-DNA polymerase protein complex in all eukaryotes examined, the data presented here indicate differences in the enzymatic properties detected in preparations of the DNA polymerase subunits isolated from S. cerevisiae as compared with the properties of preparations from Drosophila cells. In particular, the 3'----5'-exonuclease activity associated with the yeast catalytic DNA polymerase subunit was not masked by the 86-kDa subunit.