ATP activation of DNA polymerase III holoenzyme from Escherichia coli. II. Initiation complex: stoichiometry and reactivity

DNA polymerase III holoenzyme (holenzyme) has an ATPase activity elicited only by a primed DNA template. Reaction of preformed ATP.holoenzyme complex with a primed template results in hydrolysis of the ATP bound to the holoenzyme, release of ADP and Pi, and formation of an initiation complex between holoenzyme and the primed template. Approximately two ATP molecules are hydrolyzed for each initiation complex formed, a value in keeping with the number bound in the ATP.holoenzyme complex. The possibility that the latter and the initiation complex contain two holoenzyme molecules is supported by the presence of two beta monomers in the initiation complex. Holoenzyme action in the absence of ATP resembles that of pol III (the holoenzyme core) or DNA polymerase III (holoenzyme lacking the beta subunit), with or without ATP, in sensitivity to salt and in processivity of elongation. The initiation complex formed by ATP-activated holoenzyme resists a level of KCl (150 mM) that completely inhibits nonactivated holoenzyme and the incomplete forms of the holoenzyme, and displays a processivity at least 20 times greater. Upon completing replication of available template, holoenzyme can dissociate and form an initiation complex with another primed template, provided ATP is available to reactivate the holoenzyme. By inference, no essential subunits are lost in the cycle of initiation, elongation and dissociation.     

Analysis of the ATPase subassembly which initiates processive DNA synthesis by DNA polymerase III holoenzyme.

The gamma complex (gamma delta delta' chi psi) subassembly of DNA polymerase III holoenzyme transfers the beta subunit onto primed DNA in a reaction which requires ATP hydrolysis. Once on DNA, beta is a "sliding clamp" which tethers the polymerase to DNA for highly processive synthesis. We have examined beta and the gamma complex to identify which subunit(s) hydrolyzes ATP. We find the gamma complex is a DNA dependent ATPase. The beta subunit, which lacks ATPase activity, enhances the gamma complex ATPase when primed DNA is used as an effector. Hence, the gamma complex recognizes DNA and couples ATP hydrolysis to clamp beta onto primed DNA. Study of gamma complex subunits showed no single subunit contained significant ATPase activity. However, the heterodimers, gamma delta and gamma delta', were both DNA-dependent ATPases. Only the gamma delta ATPase was stimulated by beta and was functional in transferring the beta from solution to primed DNA. Similarity in ATPase activity of DNA polymerase III holoenzyme accessory proteins to accessory proteins of phage T4 DNA polymerase and mammalian DNA polymerase delta suggests the basic strategy of chromosome duplication has been conserved throughout evolution.     

The T4 DNA polymerase accessory proteins form an ATP-dependent complex on a primer-template junction

The DNA polymerase holoenzyme of bacteriophage T4 contains, besides the DNA polymerase itself (the gene 43 protein), a complex of the protein products of T4 genes 44 and 62 (a DNA-dependent ATPase) and of gene 45. Together, the 44/62 and 45 proteins form an ATP-dependent "sliding clamp" that holds a moving DNA polymerase molecule at the 3' terminus of a growing DNA chain. We have used a unique DNA fragment that forms a short hairpin helix with a single-stranded 5' tail (a "primer-template junction") to map the binding sites for these polymerase accessory proteins by DNA footprinting techniques. In the absence of the DNA polymerase, the accessory proteins protect from DNase I cleavage 19-20 nucleotides just behind the 3' end of the primer strand and 27-28 nucleotides on the complementary portion of the template strand. Detection of this DNA-protein complex requires the 44/62 and 45 proteins plus the nonhydrolyzable ATP analogue adenosine 5'-O-(thiotriphosphate). The complex is not detected in the presence of ATP. We suggest that ATP hydrolysis by the 44/62 protein normally activates the accessory proteins at a primer-template junction, permitting the DNA polymerase to bind and thus form the complete holoenzyme. However, when the polymerase is missing, as in these experiments, ATP hydrolysis is instead followed by a release (or loosening) of the accessory protein complex.     

Processive DNA synthesis by DNA polymerase II mediated by DNA polymerase III accessory proteins.

An interesting property of the Escherichia coli DNA polymerase II is the stimulation in DNA synthesis mediated by the DNA polymerase III accessory proteins beta,gamma complex. In this paper we have studied the basis for the stimulation in pol II activity and have concluded that these accessory proteins stimulate pol II activity by increasing the processivity of the enzyme between 150- and 600-fold. As is the case with pol III, processive synthesis by pol II requires both beta,gamma complex and SSB protein. Whereas the intrinsic velocity of synthesis by pol II is 20-30 nucleotides per s with or without the accessory proteins, the processivity of pol II is increased from approximately five nucleotides to greater than 1600 nucleotides incorporated per template binding event. The effect of the accessory proteins on the rate of replication is far greater on pol III than on pol II; pol III holoenzyme is able to complete replication of circular single-stranded M13 DNA in less than 20 s, whereas pol II in the presence of the gamma complex and beta requires approximately 5 min. We have investigated the effect of beta,gamma complex proteins on bypass of a site-specific abasic lesion by E. coli DNA polymerases I, II, and III. All three polymerases are extremely inefficient at bypass of the abasic lesion. We find limited bypass by pol I with no change upon addition of accessory proteins. pol II also shows limited bypass of the abasic site, dependent on the presence of beta,gamma complex and SSB. pol III shows no significant bypass of the abasic site with or without beta,gamma complex.     

Processive proofreading is intrinsic to T4 DNA polymerase.

DNA replication occurs in vivo with very high processivity, meaning that the replication complex assembles at the origin(s) of replication and then performs template-directed synthesis of DNA over virtually the entire genome without dissociation. Such processivity also characterizes reconstituted replication holoenzyme complexes in vitro. However, the isolated DNA polymerases are much less processive, especially under physiological conditions. In this paper we monitor the degree of processivity displayed by the bacteriophage T4-coded DNA polymerase while in its proofreading mode by asking whether an isolated polymerase can "edit-out" the 3'-terminal nucleotide from the primer (using the 3'----5'-exonuclease activity of the polymerase) and then switch into the synthesis mode without dissociating from the DNA template. This "switch experiment" is accomplished by using mismatched primer/template substrates as an experimental tool to mimic the situation that T4 DNA polymerase encounters after a misincorporation event has occurred. By performing experiments under single-turnover conditions (obtained using a heparin trap), we demonstrate that T4 DNA polymerase, upon encountering a misincorporated base, neither synthesizes the next base nor dissociates into solution. Instead, with a greater than 80% probability, it removes the misincorporated base and then continues synthesis in a fully processive manner. We also show that the removal of a doubly mispaired sequence from the 3'-terminus of the primer, followed by synthesis, is comparably processive. In contrast, the apparent processivity of removing a triply mispaired terminus is much reduced. Taken together, these observations are consistent with the notion that the "editing active site" of the T4 enzyme optimally accommodates only two unpaired nucleotide residues. Our results do not support the idea that the exonuclease activity of T4 DNA polymerase is highly selective for mismatched termini; they suggest instead that the dwell time at a misincorporated base determines overall editing efficiency. The integrated results of this study provide additional insight into the structure of the T4 DNA polymerase, as well as into the interactions between the polymerase and the polymerase accessory proteins that are required to provide the holoenzyme complex with full processivity.     

Enhanced processivity of nuclear matrix bound DNA polymerase alpha from regenerating rat liver

Translocation of DNA during in vitro DNA synthesis on nuclear matrix bound replicational assemblies from regenerating rat liver was determined by measuring the processivity (average number of nucleotides added following one productive binding event of the polymerase to the DNA template) of nuclear matrix bound DNA polymerase alpha with poly(dT).oligo(A)10 as template primer. The matrix-bound polymerase had an average processivity (28.4 nucleotides) that was severalfold higher than the bulk nuclear DNA polymerase alpha activity extracted during nuclear matrix preparation (8.9 nucleotides). ATP at 1 mM markedly enhanced the activity and processivity of the matrix-bound polymerase but not the corresponding salt-soluble enzyme. The majority of the ATP-dependent activity and processivity enhancement was completed by 100 microM ATP and included products ranging up to full template length (1000-1200 nucleotides). Average processivity of the net ATP-stimulated polymerase activity exceeded 80 nucleotides with virtually all the DNA products greater than 50 nucleotides. Release of nuclear matrix bound DNA polymerase alpha by sonication resulted in a loss of ATP stimulation of activity and a corresponding decrease in processivity to a level similar to that of the salt-soluble polymerase (6.8 nucleotides). All nucleoside di- and triphosphates were as effective as ATP. Stimulation of both activity and processivity by the nonhydrolyzable ATP analogues adenosine 5'-O-(3-thiotriphosphate), 5'-adenylyl imidodiphosphate, and adenosine 5'-O-(1-thiotriphosphate) further suggested that the hydrolysis of ATP is not required for enhancement to occur.(ABSTRACT TRUNCATED AT 250 WORDS)     

Protein-DNA cross-linking demonstrates stepwise ATP-dependent assembly of T4 DNA polymerase and its accessory proteins on the primer-template.

T4 DNA polymerase, the 44/62 and 45 polymerase accessory proteins, and 32 single-stranded DNA-binding protein catalyze ATP-dependent DNA synthesis. Using DNA primers with cross-linkable residues at specific positions, we obtained structural data that reveal how these proteins assemble on the primer-template. With the nonhydrolyzable ATP analog ATP gamma S, assembly of the 44/62 and 45 proteins on the primer requires 32 protein but not polymerase. ATP hydrolysis changes the position and intensity of cross-linking to each of the accessory proteins and allows cross-linking of polymerase. Our data indicate that the initial binding of the three accessory proteins and ATP to a 32 protein-covered primer-template is followed by ATP hydrolysis, binding of polymerase, and movement of the accessory proteins to yield a complex capable of processive DNA synthesis.     

Processivity of the DNA polymerase alpha-primase complex from calf thymus

The processivity of the DNA polymerase alpha-primase complex from calf thymus was analyzed under various conditions. When multi-RNA-primed M13 DNA was used as the substrate, the DNA polymerase alpha-primase complex was found to incorporate 19 +/- 3 nucleotides per primer binding event. This result was confirmed by product analysis on sequencing gels following DNA synthesis on poly(dT) X (rA)10. The processivity depends strongly on the assay conditions but does not correlate with enzymic activity. Lowering the concentration of Mg2+ ions to less than 2 mM increases the processivity to 60. Replacing Mg2+ by 0.2 mM Mn2+ results in 90 nucleotides being incorporated per primer binding event. Neither the presence of ATP nor the addition of noncognate deoxynucleotide triphosphates affects the processivity of the DNA polymerase alpha-primase complex. Lower processivity was induced by lowering the reaction temperature, by adding spermine, spermidine, or putrescine, in the presence of the antibiotics novobiocin and ciprofloxacin, by adding Escherichia coli single-stranded DNA binding protein, or by adding calf thymus topoisomerase II and RNase H. Three single-stranded DNA binding proteins from calf thymus, including unwinding protein 1, do not affect processivity to any significant extent. Freshly prepared DNA polymerase alpha-primase complex exhibits in addition to its processivity of 20 further discrete processivities of about 55, 90, and 105. This result suggest that further subunits of the polymerase alpha-primase complex are necessary to reconstitute the holoenzyme form of the eukaryotic replicase.     

Persistence of DNA synthesis arrest sites in the presence of T4 DNA polymerase and T4 gene 32, 44, 45 and 62 DNA polymerase accessory proteins.

DNA synthesis by phage T4 DNA polymerase is arrested at specific sequences in single-stranded DNA templates. To determine whether or not T4 DNA polymerase accessory proteins 32, 44, 45 and 62 eliminated recognition of these arrest sites, unique primer-templates were constructed in which DNA synthesis began at a DNA primer located at different distances from palindromic and nonpalindromic arrest sites. Nucleotide positions that caused polymerase to pause or leave the template were identified by sequence analysis of 5'-end labeled nascent DNA chains. Stable hairpin structures at palindromic sequences were confirmed by acetylation of single-stranded sequences with bromoacetaldehyde. Our results confirmed that these T4 DNA polymerase accessory proteins stimulated T4 DNA polymerase activity and processivity on natural as well as homopolymer primer-templates. However, they did not alter recognition of DNA synthesis arrest sites by T4 DNA polymerase. Extensive DNA synthesis resulted from an increased rate of translocation and/or processivity to the same extent over all DNA sequences.     

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.     

Further characterization of the interaction between the Epstein-Barr virus DNA polymerase catalytic subunit and its accessory subunit with regard to the 3'-to-5' exonucleolytic activity and stability of initiation complex at primer terminus.

The Epstein-Barr virus (EBV) DNA polymerase catalytic subunit, BALF5 gene product, possesses an intrinsic 3'-to 5' proofreading exonuclease activity in addition to 5'-to-3' DNA polymerase activity (T. Tsurumi, A. Kobayashi, K. Tamai, T. Daikoku, R. Kurachi, and Y. Nishiyama, J. Virol. 67:4651-4658, 1993). The exonuclease hydrolyzed both double-and single-stranded DNA substrates with 3'-to-5' directionality, releasing deoxyribonucleoside 5'-monophosphates. The double-strand exonucleolytic activity catalyzed by the BALF5 polymerase catalytic subunit was very sensitive to high ionic strength, whereas the single-strand exonucleolytic activity was moderately resistant. The addition of the BMRF1 polymerase accessory subunit to the reaction enhanced the double-strand exonucleolytic activity in the presence of high concentrations of ammonium sulfate (fourfold stimulation at 75 mM ammonium sulfate). Optimal stimulation was obtained when the molar ratio of BMRF1 protein to BALF5 protein was 2 and higher, identical to the values required for reconstituting the optimum DNA polymerizing activity (T. Tsurumi, T. Daikoku, R. Kurachi, and Y. Nishiyama, J. Virol. 67:7648-7653, 1993). Furthermore, product size analyses revealed that the polymerase catalytic subunit alone excised a few nucleotides from the 3' termini of the primer hybridized to template DNA and that the addition of the BMFR1 polymerase accessory subunit stimulated the nucleotide excision several times. In contrast, the hydrolysis of single-stranded DNA by the BALF5 protein was not affected by the addition of the BMRF1 polymerase accessory subunit at all. These observations suggest that the BMRF1 polymerase accessory subunit forms a complex with the BALF5 polymerase catalytic subunit to stabilize the interaction of the holoenzyme complex with the 3'-OH end of the primer on the template DNA during exonucleolysis. On the other hand, challenger DNA experiments revealed that the BALF5 polymerase catalytic subunit alone stably binds to the primer terminus in a stationary state, whereas the reconstituted polymerase holoenzyme is unstable. The instability of the initiation complex of the EBV DNA polymerase would allow the rapid removal of the EBV DNA polymerase holoenzyme from the lagging strand after it has replicated up to the previous Okazaki fragment. This feature of the EBV DNA polymerase holoenzyme in a stationary state is in marked contrast to the moving holoenzyme complex tightly bound to the primer end during polymerization and exonucleolysis.     

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.     

Evaluation of the role of the vaccinia virus uracil DNA glycosylase and A20 proteins as intrinsic components of the DNA polymerase holoenzyme

The vaccinia virus DNA polymerase is inherently distributive but acquires processivity by associating with a heterodimeric processivity factor comprised of the viral A20 and D4 proteins. D4 is also an enzymatically active uracil DNA glycosylase (UDG). The presence of an active repair protein as an essential component of the polymerase holoenzyme is a unique feature of the replication machinery. We have shown previously that the A20-UDG complex has a stoichiometry of ～1:1, and our data suggest that A20 serves as a bridge between polymerase and UDG. Here we show that conserved hydrophobic residues in the N' terminus of A20 are important for its binding to UDG. Our data argue against the assembly of D4 into higher order multimers, suggesting that the processivity factor does not form a toroidal ring around the DNA. Instead, we hypothesize that the intrinsic, processive DNA scanning activity of UDG tethers the holoenzyme to the DNA template. The inclusion of UDG as an essential holoenzyme component suggests that replication and base excision repair may be coupled. Here we show that the DNA polymerase can utilize dUTP as a substrate in vitro. Moreover, uracil moieties incorporated into the nascent strand during holoenzyme-mediated DNA synthesis can be excised by the viral UDG present within this holoenzyme, leaving abasic sites. Finally, we show that the polymerase stalls upon encountering an abasic site in the template strand, indicating that, like many replicative polymerases, the poxviral holoenzyme cannot perform translesion synthesis across an abasic site.     

Escherichia coli thioredoxin confers processivity on the DNA polymerase activity of the gene 5 protein of bacteriophage T7

Bacteriophage T7 gene 5 protein has been purified to apparent homogeneity from cells overexpressing its gene several hundred-fold. Gene 5 protein is a DNA polymerase with low processivity; it dissociates from the primer-template after catalyzing the incorporation of 1-50 nucleotides, depending on the salt concentration. Escherichia coli thioredoxin, a host protein that is tightly associated with the gene 5 protein in phage-infected cells, is not required for this activity. Thioredoxin acts as an accessory protein to bestow processivity on the polymerizing reaction; DNA synthesis catalyzed by the gene 5 protein-thioredoxin complex on a single-stranded DNA template can polymerize thousands of nucleotides without dissociation. Conditions that increase the stability of secondary structures in the template (i.e., low temperature or high ionic strength) decrease the processivity. E. coli single-stranded DNA-binding protein stimulates both the rate of elongation and the processivity of the gene 5 protein-thioredoxin complex.     

DNA polymerase III holoenzyme from Thermus thermophilus identification, expression, purification of components, and use to reconstitute a processive replicase

DNA replication in bacteria is performed by a specialized multicomponent replicase, the DNA polymerase III holoenzyme, that consist of three essential components: a polymerase, the beta sliding clamp processivity factor, and the DnaX complex clamp-loader. We report here the assembly of the minimal functional holoenzyme from Thermus thermophilus (Tth), an extreme thermophile. The minimal holoenzyme consists of alpha (pol III catalytic subunit), beta (sliding clamp processivity factor), and the essential DnaX (tau/gamma), delta and delta' components of the DnaX complex. We show with purified recombinant proteins that these five components are required for rapid and processive DNA synthesis on long single-stranded DNA templates. Subunit interactions known to occur in DNA polymerase III holoenzyme from mesophilic bacteria including delta-delta' interaction, deltadelta'-tau/gamma complex formation, and alpha-tau interaction, also occur within the Tth enzyme. As in mesophilic holoenzymes, in the presence of a primed DNA template, these subunits assemble into a stable initiation complex in an ATP-dependent manner. However, in contrast to replicative polymerases from mesophilic bacteria, Tth holoenzyme is efficient only at temperatures above 50 degrees C, both with regard to initiation complex formation and processive DNA synthesis. The minimal Tth DNA polymerase III holoenzyme displays an elongation rate of 350 bp/s at 72 degrees C and a processivity of greater than 8.6 kilobases, the length of the template that is fully replicated after a single association event.     

DNA footprinting studies of the complex formed by the T4 DNA polymerase holoenzyme at a primer-template junction

We have used DNA footprinting techniques to analyze the interactions of five DNA replication proteins at a primer-template junction: the bacteriophage T4 DNA polymerase (the gene 43 protein), its three accessory proteins (the gene 44/62 and 45 proteins), and the gene 32 protein, which is the T4 helix-destabilizing (or single-stranded DNA-binding) protein. The 177-nucleotide-long DNA substrate consisted of a perfect 52-base pair hairpin helix with a protruding single-stranded 5' tail. As expected, the DNA polymerase binds near the 3' end of this molecule (at the primer-template junction) and protects the adjacent double-stranded region from cleavage. When the gene 32 protein binds to the single-stranded tail, it reduces the concentration of the DNA polymerase required to observe the polymerase footprint by 10-30-fold. Periodic ATP hydrolysis by the 44/62 protein is required to maintain the activity of the DNA polymerase holoenzyme (a complex of the 43, 44/62, and 45 proteins). Footprinting experiments demonstrate the formation of a weak complex between the DNA polymerase and the gene 45 protein, but there is no effect of the 44/62 protein or ATP on this enlarged footprint. We propose a model for holoenzyme function in which the complex of the three accessory proteins uses ATP hydrolysis to keep a moving polymerase tightly bound to the growing 3' end, providing a "clock" to measure polymerase stalling.     

The beta subunit of the Escherichia coli DNA polymerase III holoenzyme interacts functionally with the catalytic core in the absence of other subunits

We have previously demonstrated that the addition of a stoichiometric excess of the beta subunit of Escherichia coli DNA polymerase III holoenzyme to DNA polymerase III or holoenzyme itself can lead to an ATP-independent increase in the processivity of these enzyme forms (Crute, J. J., LaDuca, R. J., Johanson, K. O., McHenry, C. S., and Bambara, R. A. (1983) J. Biol. Chem. 258, 11344-11349). Here, we show that the beta subunit can interact directly with the catalytic core of the holoenzyme, DNA polymerase III, generating a new form of the enzyme with enhanced catalytic and processive capabilities. The addition of saturating levels of the beta subunit to the core DNA polymerase III enzyme results in as much as a 7-fold stimulation of synthetic activity. Two populations of DNA products were generated by the DNA polymerase III X beta enzyme complex. Short products resulting from the addition of 5-10 nucleotides/primer fragment were generated by DNA polymerase III in the presence and absence of added beta subunit. A second population of much longer products was generated only in beta-supplemented DNA polymerase III reactions. The DNA polymerase III-beta reaction was inhibited by single-stranded DNA binding protein and was unaffected by ATP, distinguishing it from the holoenzyme-catalyzed reaction. Complex formation of the DNA polymerase III core enzyme with beta increased the residence time of the enzyme on synthetic DNA templates. Our results demonstrate that the beta stimulation of DNA polymerase III can be attributed to a more efficient and highly processive elongation capability of the DNA polymerase III X beta complex. They also prove that at least part of beta's normal contribution to the DNA polymerase III holoenzyme reaction takes place through interaction with DNA polymerase III core enzyme components to produce the essential complex necessary for efficient elongation in vivo.