Complete replication of templates by Escherichia coli DNA polymerase III holoenzyme

DNA polymerase III holoenzyme (holoenzyme) processively and rapidly replicates a primed single-stranded DNA circle to produce a duplex with an interruption in the synthetic strand. The precise nature of this discontinuity in the replicative form (RF II) and the influence of the 5' termini of the DNA and RNA primers were analyzed in this study. Virtually all (90%) of the RF II products primed by DNA were nicked structures sealable by Escherichia coli DNA ligase; in 10% of the products, replication proceeded one nucleotide beyond the 5' DNA terminus displacing (but not removing) the 5' terminal nucleotide. With RNA primers, replication generally went beyond the available single-stranded template. The 5' RNA terminus was displaced by 1-5 nucleotides in 85% of the products; a minority of products was nicked (9%) or had short gaps (6%). Termination of synthesis on a linear DNA template was usually (85%) one base shy of completion. Thus, replication by holoenzyme utilizes all, or nearly all, of the available template and shows no significant 5'----3' exonuclease action as observed in primer removal by the "nick-translation" activity of DNA polymerase I.     

Constitution of the twin polymerase of DNA polymerase III holoenzyme

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

Escherichia coli DNA polymerase II is stimulated by DNA polymerase III holoenzyme auxiliary subunits

DNA polymerase III of Escherichia coli requires multiple auxiliary factors to enable it to serve as a replicative complex. We demonstrate that auxiliary components of the DNA polymerase III holoenzyme, the gamma delta complex and beta subunit, markedly stimulate DNA polymerase II on long single-stranded templates. DNA polymerase II activity is enhanced by single-stranded DNA binding protein, but the stimulation by gamma delta and beta can be observed either in the absence or presence of single-stranded DNA binding protein. In contrast with DNA polymerase III, the requirement of DNA polymerase II for gamma delta cannot be bypassed by large excesses of the beta subunit at low ionic strength in the absence of the single-stranded DNA binding protein. The product of the DNA polymerase II-gamma delta-beta reaction on a uniquely primed single-stranded circle is of full template length; the reconstituted enzyme apparently is incapable of strand displacement synthesis. The possible biological implications of these observations are discussed.     

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.     

Analysis of translesion replication across an abasic site by DNA polymerase IV of Escherichia coli

Unrepaired replication-blocking DNA lesions are bypassed by specialized DNA polymerases, members of the Y super-family. In Escherichia coli the major lesion bypass DNA polymerase is pol V, whereas the function of its homologue, pol IV, is not fully understood. In vivo analysis showed that pol V has a major role in bypass across an abasic site analog, with little or no involvement of pol IV. This can result from the inability of pol IV to bypass the abasic site, or from in vivo regulation of its activity. In vitro analysis revealed that purified pol IV, in the presence of the beta subunit DNA sliding clamp, and the gamma complex clamp loader, bypassed a synthetic abasic site with very high efficiency, reaching 73% in 2 min. Bypass was observed also in the absence of the processivity proteins, albeit at a 10- to 20-fold lower rate. DNA sequence analysis revealed that pol IV skips over the abasic site, producing primarily small deletions. The RecA protein inhibited bypass by pol IV, but this inhibition was alleviated by single-strand binding protein (SSB). The fact that the in vitro bypass ability of pol IV is not manifested under in vivo conditions suggests the presence of a regulatory factor, which might be involved in controlling the access of the bypass polymerases to the damaged site in DNA.     

RecA protein inhibits in vitro replication of single-stranded DNA with DNA polymerase III holoenzyme of Escherichia coli

Purified RecA protein from Escherichia coli inhibited 5-10-fold the rate of in vitro replication of both unirradiated and UV-irradiated single-stranded DNA (ssDNA) with DNA polymerase III holoenzyme. Maximal inhibition occurred at a ratio of 1 molecule of RecA per 2-4 nucleotides of DNA, and it affected primarily the initiation of elongation on primed ssDNA. Adding single-strand DNA-binding protein (SSB) caused a relief of inhibition. Under conditions when there was enough SSB to cover the ssDNA completely, RecA protein had no effect on initiation, elongation or dissociation steps of replication. These observations together with data from in vivo studies suggest a role for RecA protein in the arrest of DNA replication observed in cells exposed to UV-radiation and a variety of chemical carcinogens.     

Dynamics of DNA polymerase III holoenzyme of Escherichia coli in replication of a multiprimed template

Movements of DNA polymerase III holoenzyme (holoenzyme) in replicating a template multiprimed with synthetic pentadecadeoxynucleotides (15-mers) annealed at known positions on a single-stranded circular or linear DNA have been analyzed. After extension of one 15-mer on a multiprimed template, holoenzyme moves downstream in the direction of chain elongation to the next primer. Holoenzyme readily traverses a duplex, even 400 base pairs long, to exploit its 3'-hydroxyl end as the next available primer. This downstream polarity likely results from an inability to diffuse upstream along single-stranded DNA. These holoenzyme movements, unlike formation of the initial complex with a primer, do not require ATP. Time elapsed between completion of a chain and initiation on the next downstream primer is rapid (1 s or less); dissociation of holoenzyme to form a complex with another primed template is slow (1-2 min). Thus, holoenzyme diffuses rapidly only on duplex DNA, probably in both directions, and forms an initiation complex with the first primer encountered. Based on these findings, schemes can be considered for holoenzyme action at the replication fork of a duplex chromosome.     

Mechanism of replication of ultraviolet-irradiated single-stranded DNA by DNA polymerase III holoenzyme of Escherichia coli. Implications for SOS mutagenesis

Replication of UV-irradiated oligodeoxynucleotide-primed single-stranded phi X174 DNA with Escherichia coli DNA polymerase III holoenzyme in the presence of single-stranded DNA-binding protein was investigated. The extent of initiation of replication on the primed single-stranded DNA was not altered by the presence of UV-induced lesions in the DNA. The elongation step exhibited similar kinetics when either unirradiated or UV-irradiated templates were used. Inhibition of the 3'----5' proofreading exonucleolytic activity of the polymerase by dGMP or by a mutD mutation did not increase bypass of pyrimidine photodimers, and neither did purified RecA protein influence the extent of photodimer bypass as judged by the fraction of full length DNA synthesized. Single-stranded DNA-binding protein stimulated bypass since in its absence the fraction of full length DNA decreased 5-fold. Termination of replication at putative pyrimidine dimers involved dissociation of the polymerase from the DNA, which could then reinitiate replication at other available primer templates. Based on these observations a model for SOS-induced UV mutagenesis is proposed.     

The fidelity of base selection by the polymerase subunit of DNA polymerase III holoenzyme.

In common with other DNA polymerases, DNA polymerase III holoenzyme of E. coli selects the biologically correct base pair with remarkable accuracy. DNA polymerase III is particularly useful for mechanistic studies because the polymerase and editing activities reside on separate subunits. To investigate the biochemical mechanism for base insertion fidelity, we have used a gel electrophoresis assay to measure kinetic parameters for the incorporation of correct and incorrect nucleotides by the polymerase (alpha) subunit of DNA polymerase III. As judged by this assay, base selection contributes a factor of roughly 10(4)-10(5) to the overall fidelity of genome duplication. The accuracy of base selection is determined mainly by the differential KM of the enzyme for correct vs. incorrect deoxynucleoside triphosphate. The misinsertion of G opposite template A is relatively efficient, comparable to that found for G opposite T. Based on a variety of other work, the G:A pair may require a special correction mechanism, possibly because of a syn-anti pairing approximating Watson-Crick geometry. We suggest that precise recognition of the equivalent geometry of the Watson-Crick base pairs may be the most critical feature for base selection.     

Glutamate overcomes the salt inhibition of DNA polymerase III holoenzyme

Even though Escherichia coli can grow in media containing up to 1 M NaCl, one-fifth that amount of NaCl will completely inhibit the in vitro activity of DNA polymerase III holoenzyme. It has been established that the major intracellular ionic osmolytes are potassium and glutamate (Richey, B., Cayley, D. S., Mossing, M. C., Kolka, C., Anderson, C. F., Farrar, T. C., and Record, M. T., Jr. (1987) J. Biol. Chem. 262, 7157-7164). We have found that holoenzyme catalyzes replication efficiently in vitro in up to 1 M potassium glutamate. Two salt effects on the replication of single-stranded DNA were observed. At low salt replicative activity was enhanced and at high salt there was anion-specific inhibition. We have found that DNA polymerase III holoenzyme tolerated 10-fold higher concentrations of glutamate than chloride. The ability of various anions to extend the useful range of salt concentrations followed the order: phosphate less than chloride less than N-Ac-glutamate less than acetate less than glycine less than aspartate less than glutamate. With the exception of phosphate, this order followed the Hofmeister series indicating that the anion-specific effects were due to anions interacting at the protein-water interface at weak anion binding sites. Glutamate did not reverse the inhibition by chloride. The low salt enhancement and high salt inhibition effects were additive for the two anions indicating that they competed for common anion binding sites. The major salt-sensitive step was holoenzyme binding to template rather than the subsequent elongation reaction.     

Dynamics of termination during in vitro replication of ultraviolet-irradiated DNA with DNA polymerase III holoenzyme of Escherichia coli

During in vitro replication of UV-irradiated single-stranded DNA with Escherichia coli DNA polymerase III holoenzyme termination frequently occurs at pyrimidine photodimers. The termination stage is dynamic and characterized by at least three different events: repeated dissociation-reinitiation cycles of the polymerase at the blocked termini; extensive hydrolysis of ATP to ADP and inorganic phosphate; turnover of dNTPs into dNMP. The reinitiation events are nonproductive and are not followed by further elongation. The turnover of dNTPs into dNMPs is likely to result from repeated cycles of insertion of dNMP residues opposite the blocking lesions followed by their excision by the 3'----5' exonucleolytic activity of the polymerase. Although all dNTPs are turned over, there is a preference for dATP, indicating that DNA polymerase III holoenzyme has a preference for inserting a dAMP residue opposite blocking pyrimidine photodimers. We suggest that the inability of the polymerase to bypass photodimers during termination is due to the formation of defective initiation-like complexes with reduced stability at the blocked termini.     

DNA polymerase iota-dependent translesion replication of uracil containing cyclobutane pyrimidine dimers

Analysis of the spectrum of UV-induced mutations generated in synchronized wild-type S-phase cells reveals that only approximately 25% of mutations occur at thymine (T), whilst 75% are targeted to cytosine (C). The mutational spectra changes dramatically in XP-V cells, devoid of poleta, where approximately 45% of mutations occur at Ts and approximately 55% at Cs. At the present time, it is unclear whether the C-->T mutations actually represent true misincorporations opposite C, or perhaps occur as the result of the correct incorporation of adenine (A) opposite a C in a UV-photoproduct that had undergone deamination to uracil (U). In order to assess the role that human poliota might play, if any, in the replicative bypass of such UV-photoproducts, we have analyzed the efficiency and fidelity of pol iota-dependent bypass of a T-U cyclobutane pyrimidine dimer (CPD) in vitro. Interestingly, pol iota-dependent bypass of a T-U CPD occurs more efficiently than that of a corresponding T-T CPD. Guanine (G) was misincorporated opposite the 3'U of the T-U CPD only two-fold less frequently than the correct Watson-Crick base, A. While pol iota generally extended the G:3'U-CPD mispairs less efficiently than the correctly paired primer, pol iota-dependent extension was equal to, or greater than that observed with human pols eta and kappa and S. cerevisiae pol zeta under the same assay conditions. Thus, we hypothesize that the ability of pol iota to bypass T-U CPDs through the frequent misincorporation of G opposite the 3'U of the CPD, may provide a mechanism whereby human cells can decrease the mutagenic potential of these lesions.     

Site-directed mutagenesis with Escherichia coli DNA polymerase III holoenzyme

Escherichia coli DNA polymerase III holoenzyme was used to synthesize double-stranded DNA from M13 single-stranded DNA hybridized to a phosphorylated synthetic oligodeoxynucleotide containing a nucleotide substitution. The resulting DNA was transfected into E. coli JM101 without further treatment. Sequence analysis of randomly chosen phage clones revealed that the efficiency of mutagenesis was nearly 50%, which is the theoretical maximum. Treatment with DNA ligase after DNA synthesis was not necessary to obtain high efficiency of mutagenesis. Thus, use of DNA polymerase III holoenzyme provides a simple and efficient procedure for site-directed mutagenesis.     

Efficient translesion replication past oxaliplatin and cisplatin GpG adducts by human DNA polymerase eta

Platinum anticancer agents form bulky DNA adducts which are thought to exert their cytotoxic effect by blocking DNA replication. Translesion synthesis, one of the pathways of postreplication repair, is thought to account for some resistance to DNA damage and much of the mutagenicity of bulky DNA adducts in dividing cells. Oxaliplatin has been shown to be effective in cisplatin-resistant cell lines and less mutagenic than cisplatin in the Ames assay. We have shown that the eukaryotic DNA polymerases yeast pol zeta, human pol beta, and human pol gamma bypass oxaliplatin-GG adducts more efficiently than cisplatin-GG adducts. Human pol eta, a product of the XPV gene, has been shown to catalyze efficient translesion synthesis past cis, syn-cyclobutane pyrimidine dimers. In the present study we compared translesion synthesis past different Pt-GG adducts by human pol eta. Our data show that, similar to other eukaryotic DNA polymerases, pol eta bypasses oxaliplatin-GG adducts more efficiently than cisplatin-GG adducts. However, pol eta-catalyzed translesion replication past Pt-DNA adducts was more efficient and less accurate than that seen for previously tested polymerases. We show that the efficiency and fidelity of translesion replication past Pt-DNA adducts appear to be determined by both the structure of the adduct and the DNA polymerase active site.     

Carboxyl-terminal domain III of the delta' subunit of the DNA polymerase III holoenzyme binds delta

The delta and delta' subunits are essential components of the DNA polymerase III holoenzyme, required for assembly and function of the DnaX-complex clamp loader (tau2gammadeltadelta'chipsi). The x-ray crystal structure of delta' contains three structural domains (Guenther, B., Onrust, R., Sali, A., O'Donnell, M., and Kuriyan, J. (1997) Cell 91, 335-345). In this study, we localize the delta-binding domain of delta' to a carboxyl-terminal domain III by quantifying the interaction of delta with a series of delta' fusion proteins lacking specific domains. Purification and immobilization of the fusion proteins were facilitated by the inclusion of a tag containing hexahistidine and a short biotinylation sequence. Both NH2- and COOH-terminal-tagged full-length delta' were soluble and had specific activities comparable with that of native delta'. delta and delta' form a 1:1 heterodimer with a dissociation constant (K(D)) of 5 x 10(-7) m determined by equilibrium sedimentation. The K(D) determined by surface plasmon resonance was comparable. Domain III alone bound delta at an affinity comparable to that of wild type delta', whereas proteins lacking domain III did not bind delta. Using a panel of domain-specific anti-delta' monoclonal antibodies, we found that two of the domain III-specific monoclonal antibodies interfered with delta-delta' interaction and abolished the replication activity of DNA polymerase-III holoenzyme.     

Inhibition of translesion DNA polymerase by archaeal reverse gyrase

Reverse gyrase is a unique DNA topoisomerase endowed with ATP-dependent positive supercoiling activity. It is typical of microorganisms living at high temperature and might play a role in maintenance of genome stability and repair. We have identified the translesion DNA polymerase SsoPolY/Dpo4 as one partner of reverse gyrase in the hyperthermophilic archaeon Sulfolobus solfataricus. We show here that in cell extracts, PolY and reverse gyrase co-immunoprecipitate with each other and with the single strand binding protein, SSB. The interaction is confirmed in vitro by far-western and Surface Plasmon Resonance. In functional assays, reverse gyrase inhibits PolY, but not the S. solfataricus B-family DNA polymerase PolB1. Mutational analysis shows that inhibition of PolY activity depends on both ATPase and topoisomerase activities of reverse gyrase, suggesting that the intact positive supercoiling activity is required for PolY inhibition. In vivo, reverse gyrase and PolY are degraded after induction of DNA damage. Inhibition by reverse gyrase and degradation might act as a double mechanism to control PolY and prevent its potentially mutagenic activity when undesired. Inhibition of a translesion polymerase by topoisomerase-induced modification of DNA structure may represent a previously unconsidered mechanism of regulation of these two-faced enzymes.     

Evaluating the effects of enhanced processivity and metal ions on translesion DNA replication catalyzed by the bacteriophage T4 DNA polymerase

The fidelity of DNA replication is achieved in a multiplicative process encompassing nucleobase selection and insertion, removal of misinserted nucleotides by exonuclease activity, and enzyme dissociation from primer/templates that are misaligned due to mispairing. In this study, we have evaluated the effect of altering these kinetic processes on the dynamics of translesion DNA replication using the bacteriophage T4 replication apparatus as a model system. The effect of enhancing the processivity of the T4 DNA polymerase, gp43, on translesion DNA replication was evaluated using a defined in vitro assay system. While the T4 replicase (gp43 in complex with gp45) can perform efficient, processive replication using unmodified DNA, the T4 replicase cannot extend beyond an abasic site. This indicates that enhancing the processivity of gp43 does not increase unambiguously its ability to perform translesion DNA replication. Surprisingly, the replicase composed of an exonuclease-deficient mutant of gp43 was unable to extend beyond the abasic DNA lesion, thus indicating that molecular processes involved in DNA polymerization activity play the predominant role in preventing extension beyond the non-coding DNA lesion. Although neither T4 replicase complex could extend beyond the lesion, there were measurable differences in the stability of each complex at the DNA lesion. Specifically, the exonuclease-deficient replicase dissociates at a rate constant, k(off), of 1.1s(-1) while the wild-type replicase remains more stably associated at the site of DNA damage by virtue of a slower measured rate constant (k(off) 0.009s(-1)). The increased lifetime of the wild-type replicase suggests that idle turnover, the partitioning of the replicase from its polymerase to its exonuclease active site, may play an important role in maintaining fidelity. Further attempts to perturb the fidelity of the T4 replicase by substituting Mn(2+) for Mg(2+) did not significantly enhance DNA synthesis beyond the abasic DNA lesion. The results of these studies are interpreted with respect to current structural information of gp43 alone and complexed with gp45.