tau couples the leading- and lagging-strand polymerases at the Escherichia coli DNA replication fork

A peptide switch regulates DNA polymerase processivity

Chromosomal DNA polymerases are tethered to DNA by a circular sliding clamp for high processivity. However, lagging strand synthesis requires the polymerase to rapidly dissociate on finishing each Okazaki fragment. The Escherichia coli replicase contains a subunit (tau) that promotes separation of polymerase from its clamp on finishing DNA segments. This report reveals the mechanism of this process. We find that tau binds the C-terminal residues of the DNA polymerase. Surprisingly, this same C-terminal "tail" of the polymerase interacts with the beta clamp, and tau competes with beta for this sequence. Moreover, tau acts as a DNA sensor. On binding primed DNA, tau releases the polymerase tail, allowing polymerase to bind beta for processive synthesis. But on sensing the DNA is complete (duplex), tau sequesters the polymerase tail from beta, disengaging polymerase from DNA. Therefore, DNA sensing by tau switches the polymerase peptide tail on and off the clamp and coordinates the dynamic turnover of polymerase during lagging strand synthesis.

Mechanism of the delta wrench in opening the beta sliding clamp

The beta sliding clamp encircles DNA and tethers DNA polymerase III holoenzyme to the template for high processivity. The clamp loader, gamma complex (gamma 3 delta delta'chi psi), assembles beta around DNA in an ATP-fueled reaction. The delta subunit of the clamp loader opens the beta ring and is referred to as the wrench; ATP modulates contact between beta and delta among other functions. Crystal structures of delta.beta and the gamma 3 delta delta' minimal clamp loader make predictions of the clamp loader mechanism, which are tested in this report by mutagenesis. The delta wrench contacts beta at two sites. One site is at the beta dimer interface, where delta appears to distort the interface by via a steric clash between a helix on delta and a loop near the beta interface. The energy for this steric clash is thought to derive from the other site of interaction, in which delta binds to a hydrophobic pocket in beta. The current study demonstrates that rather than a simple steric clash with beta, delta specifically contacts beta at this site, but not through amino acid side chains, and thus is presumably mediated by peptide backbone atoms. The results also imply that the interaction of delta at the hydrophobic site on beta contributes to destabilization of the beta dimer interface rather than acting solely as a grip of delta on beta. Within the gamma complex, delta' is proposed to prevent delta from binding to beta in the absence of ATP. This report demonstrates that one or more gamma subunits also contribute to this role. The results also indicate that delta' acts as a backboard upon which the gamma subunits push to attain the ATP induced change needed for the delta wrench to bind and open the beta ring.

The application of a minicircle substrate in the study of the coordinated T4 DNA replication

A reconstituted in vitro bacteriophage T4 DNA replication system was studied on a synthetic 70-mer minicircle substrate. This substrate was designed so that dGMP and dCMP were exclusively incorporated into the leading and the lagging strand, respectively. This design allows the simultaneous and independent measurement of the leading and lagging strand synthesis. In this paper, we report our results on the characterization of the 70-mer minicircle substrate. We show here that the minicircle substrate supports coordinated leading and lagging strand synthesis under the experimental conditions employed. The rate of the leading strand fork movement was at an average of approximately 150 nucleotides/s. This rate decreased to less than 30 nucleotides/s when the helicase was omitted from the reaction. These results suggest that both the holoenzyme and the primosome can be simultaneously assembled onto the minicircle substrate. The lagging strand synthesized on this substrate is of an average of 1.5 kb, and the length of the Okazaki fragments increased with decreasing [rNTPs]. The proper response of the Okazaki fragment size toward the change of the priming signal further indicates a functional replisome assembled on the minicircle template. The effects of various protein components on the leading and lagging strand synthesis were also studied. The collective results indicate that coordinated strand synthesis only takes place within certain protein concentration ranges. The optimal protein levels of the proteins that constitute the T4 replisome generally bracket the concentrations of the same proteins in vivo. Omission of the primase has little effect on the rate of dNMP incorporation or the rate of the fork movement on the leading strand within the first 30 s of the reaction. This inhibition only becomes significant at later times of the reaction and may be associated with the accumulation of single-stranded DNA leading to the collapse of active replisomes.

Chromosomal replicases as asymmetric dimers: studies of subunit arrangement and functional consequences

Studies of the DNA polymerase III holoenzyme of Escherichia coli support a model in which both the leading and lagging strand polymerases are held together in a complex with the replicative helicase and priming activities, allowing two identical alpha catalytic subunits to assume different functions on the two strands of the replication fork. Creation of distinct functions for each of the two polymerases within the holoenzyme depends on the asymmetric character of the entire complex. The asymmetry of the holoenzyme is created by the DnaX complex, a heptamer that includes tau and gamma products of the dnaX gene. tau and gamma perform unique functions in the DnaX complex, and the interaction between alpha and tau appears to dictate the catalytic subunit's role in the replicative reaction. This review considers the properties of the DnaX complex including both tau and gamma, with the goal of understanding the properties of the replicase and its function in vivo. Recent studies in eukaryotic and other prokaryotic systems suggest that an asymmetric dimeric replicase may be universal. The leading and lagging strand polymerases may be distinct in some systems. For example, Pol e and Pol delta may function as distinct leading and lagging strand polymerases in eukaryotes, and PolC and DnaE may function as distinct leading and lagging strand polymerases in low GC content Gram-positive bacteria.

Suppression of temperature-sensitive chromosome replication of an Escherichia coli dnaX(Ts) mutant by reduction of initiation efficiency

Temperature sensitivity of DNA polymerization and growth of a dnaX(Ts) mutant is suppressible at 39 to 40 degrees C by mutations in the initiator gene, dnaA. These suppressor mutations concomitantly cause initiation inhibition at 20 degrees C and have been designated Cs,Sx to indicate both phenotypic characteristics of cold-sensitive initiation and suppression of dnaX(Ts). One dnaA(Cs,Sx) mutant, A213D, has reduced affinity for ATP, and two mutants, R432L and T435K, have eliminated detectable DnaA box binding in vitro. Two models have explained dnaA(Cs,Sx) suppression of dnaX, which codes for both the tau and gamma subunits of DNA polymerase III. The initiation deficiency model assumes that reducing initiation efficiency allows survival of the dnaX(Ts) mutant at the somewhat intermediate temperature of 39 to 40 degrees C by reducing chromosome content per cell, thus allowing partially active DNA polymerase III to complete replication of enough chromosomes for the organism to survive. The stabilization model is based on the idea that DnaA interacts, directly or indirectly, with polymerization factors during replication. We present five lines of evidence consistent with the initiation deficiency model. First, a dnaA(Cs,Sx) mutation reduced initiation frequency and chromosome content (measured by flow cytometry) and origin/terminus ratios (measured by real-time PCR) in both wild-type and dnaX(Ts) strains growing at 39 and 34 degrees C. These effects were shown to result specifically from the Cs,Sx mutations, because the dnaX(Ts) mutant is not defective in initiation. Second, reduction of the number of origins and chromosome content per cell was common to all three known suppressor mutations. Third, growing the dnaA(Cs,Sx) dnaX(Ts) strain on glycerol-containing medium reduced its chromosome content to one per cell and eliminated suppression at 39 degrees C, as would be expected if the combination of poor carbon source, the Cs,Sx mutation, the Ts mutation, and the 39 degrees C incubation reduced replication to the point that growth (and, therefore, suppression) was not possible. However, suppression was possible on glycerol medium at 38 degrees C. Fourth, the dnaX(Ts) mutation can be suppressed also by introduction of oriC mutations, which reduced initiation efficiency and chromosome number per cell, and the degree of suppression was proportional to the level of initiation defect. Fifth, introducing a dnaA(Cos) allele, which causes overinitiation, into the dnaX(Ts) mutant exacerbated its temperature sensitivity.

GINS, a novel multiprotein complex required for chromosomal DNA replication in budding yeast

Eukaryotic chromosomal DNA replication requires a two-step assembly of replication proteins on origins; formation of the prereplicative complex (pre-RC) in late M and G1 phases of the cell cycle, and assembly of other replication proteins in S phase to load DNA polymerases to initiate DNA synthesis. In budding yeast, assembly of Dpb11 and the Sld3–Cdc45 complex on the pre-RC at origins is required for loading DNA polymerases. Here we describe a novel replication complex, GINS (Go, Ichi, Nii, and San; five, one, two, and three in Japanese), in budding yeast, consisting of Sld5, Psf1 (partner of Sld five 1), Psf2, and Psf3 proteins, all of which are highly conserved in eukaryotic cells. Since the conditional mutations of Sld5 and Psf1 confer defect of DNA replication under nonpermissive conditions, GINS is suggested to function for chromosomal DNA replication. Consistently, in S phase, GINS associates first with replication origins and then with neighboring sequences. Without GINS, neither Dpb11 nor Cdc45 associates properly with chromatin DNA. Conversely, without Dpb11 or Sld3, GINS does not associate with origins. Moreover, genetic and two-hybrid interactions suggest that GINS interacts with Sld3 and Dpb11. Therefore, Dpb11, Sld3, Cdc45, and GINS assemble in a mutually dependent manner on replication origins to initiate DNA synthesis.

Reconstitution of the Mcm2-7p heterohexamer, subunit arrangement, and ATP site architecture

The Mcm2-7p heterohexamer is the presumed replicative helicase in eukaryotic cells. Each of the six subunits is required for replication. We have purified the six Saccharomyces cerevisiae MCM proteins as recombinant proteins in Escherichia coli and have reconstituted the Mcm2-7p complex from individual subunits. Study of MCM ATPase activity demonstrates that no MCM protein hydrolyzes ATP efficiently. ATP hydrolysis requires a combination of two MCM proteins. The fifteen possible pairwise mixtures of MCM proteins yield only three pairs of MCM proteins that produce ATPase activity. Study of the Mcm3/7p ATPase shows that an essential arginine in Mcm3p is required for hydrolysis of the ATP bound to Mcm7p. Study of the pairwise interactions between MCM proteins connects the remaining MCM proteins to the Mcm3/7p pair. The data predict which subunits in the ATPase pairs bind the ATP that is hydrolyzed and indicate the arrangement of subunits in the Mcm2-7p heterohexamer.

Reductive genome evolution in Buchnera aphidicola

We have sequenced the genome of the intracellular symbiont Buchnera aphidicola from the aphid Baizongia pistacea. This strain diverged 80-150 million years ago from the common ancestor of two previously sequenced Buchnera strains. Here, a field-collected, nonclonal sample of insects was used as source material for laboratory procedures. As a consequence, the genome assembly unveiled intrapopulational variation, consisting of approximately 1,200 polymorphic sites. Comparison of the 618-kb (kbp) genome with the two other Buchnera genomes revealed a nearly perfect gene-order conservation, indicating that the onset of genomic stasis coincided closely with establishment of the symbiosis with aphids, approximately 200 million years ago. Extensive genome reduction also predates the synchronous diversification of Buchnera and its host; but, at a slower rate, gene loss continues among the extant lineages. A computational study of protein folding predicts that proteins in Buchnera, as well as proteins of other intracellular bacteria, are generally characterized by smaller folding efficiency compared with proteins of free living bacteria. These and other degenerative genomic features are discussed in light of compensatory processes and theoretical predictions on the long-term evolutionary fate of symbionts like Buchnera.

Motors and switches: AAA+ machines within the replisome

Clamp loaders are required to load the ring-shaped clamps that tether replicative DNA polymerases onto DNA. Recently solved crystal structures, along with a series of biochemical studies, have provided a detailed understanding of the clamp loading reaction. In particular, studies of the Escherichia coli clamp loader--an AAA+ machine--have provided insights into the architecture of clamp loaders from eukaryotes, bacteriophage T4 and archaea. Other AAA+ proteins are also involved in the initiation of DNA replication, and studies of the E. coli clamp loader indicate mechanisms by which these proteins might function.

Characterization of DNA synthesis catalyzed by bacteriophage T4 replication complexes reconstituted on synthetic circular substrates

Replication complexes were reconstituted using the eight purified bacteriophage T4 replication proteins and synthetic circular 70-, 120- or 240-nt DNA substrates annealed to a leading-strand primer. To differentiate leading strands from lagging strands, the circular parts of the substrates lacked dCMP; thus, no dCTP was required for leading-strand synthesis and no dGTP for lagging-strand synthesis. The size of the substrates was crucial, the longer substrates supporting much more DNA synthesis. Leading and lagging strands were synthesized in a coupled manner. Specifically targeting leading-strand synthesis by decreasing the concentration of dGTP decreased the rate of extension of leading strands. However, blocking lagging-strand synthesis by lowering the dCTP concentration, by omitting dCTP altogether, by adding ddCTP, or with a single abasic site had no immediate effect on the rate of extension of leading strands.

Homogenous assays for Escherichia coli DnaB-stimulated DnaG primase and DnaB helicase and their use in screening for chemical inhibitors

Escherichia coli DnaG primase is a single-stranded DNA-dependent RNA polymerase. Primase catalyzes the synthesis of a short RNA primer to initiate DNA replication at the origin and to initiate Okazaki fragment synthesis for synthesis of the lagging strand. Primase activity is greatly stimulated through its interaction with DnaB helicase. Here we report a 96-well homogeneous scintillation proximity assay (SPA) for the study of DnaB-stimulated E. coli primase activity and the identification of E. coli primase inhibitors. The assay uses an adaptation of the general priming reaction by employing DnaG primase, DnaB helicase, and ribonucleotidetriphosphates (incorporation of [(3)H]CTP) for in vitro primer synthesis on single-stranded oligonucleotide and M13mp18 DNA templates. The primase product is captured by polyvinyl toluene-polyethyleneimine-coated SPA beads and quantified by counting by beta-scintography. In the absence of helicase as a cofactor, primer synthesis is reduced by 85%. The primase assay was used for screening libraries of compounds previously identified as possessing antimicrobial activities. Primase inhibitory compounds were then classified as direct primase inhibitors or mixed primase/helicase inhibitors by further evaluation in a specific assay for DnaB helicase activity. By this approach, specific primase inhibitors could be identified.

SpSld3 is required for loading and maintenance of SpCdc45 on chromatin in DNA replication in fission yeast

Initiation of DNA replication in eukaryotic cells is regulated through the ordered assembly of replication complexes at origins of replication. Association of Cdc45 with the origins is a crucial step in assembly of the replication machinery, hence can be considered a target for the regulation of origin activation. To examine the process required for SpCdc45 loading, we isolated fission yeast SpSld3, a counterpart of budding yeast Sld3 that interacts with Cdc45. SpSld3 associates with the replication origin during G1-S phases and this association depends on Dbf4-dependent (DDK) kinase activity. In the corresponding period, SpSld3 interacts with minichromosome maintenance (MCM) proteins and then with SpCdc45. A temperature-sensitive sld3-10 mutation suppressed by the multicopy of the sna41+ encoding SpCdc45 impairs loading of SpCdc45 onto chromatin. In addition, this mutation leads to dissociation of preloaded Cdc45 from chromatin in the hydroxyurea-arrested S phase, and DNA replication upon removal of hydroxyurea is retarded. Thus, we conclude that SpSld3 is required for stable association of Cdc45 with chromatin both in initiation and elongation of DNA replication. The DDK-dependent origin association suggests that SpSld3 is involved in temporal regulation of origin firing.

A three-domain structure for the delta subunit of the DNA polymerase III holoenzyme delta domain III binds delta' and assembles into the DnaX complex

Using psi-BLAST, we have developed a method for identifying the poorly conserved delta subunit of the DNA polymerase III holoenzyme from all sequenced bacteria. This approach, starting with Escherichia coli delta, leads not only to the identification of delta but also to the DnaX and delta' subunits of the DnaX complex and other AAA(+)-class ATPases. This suggests that, although not an ATPase, delta is related structurally to the other subunits of the DnaX complex that loads the beta sliding clamp processivity factor onto DNA. To test this prediction, we aligned delta sequences with those of delta' and, using the start of delta' Domain III established from its x-ray crystal structure, predicted the juncture between Domains II and III of delta. This putative delta Domain III could be expressed to high levels, consistent with the prediction that it folds independently. delta Domain III, like Domain III of DnaX and delta', assembles by itself into a complex with the other DnaX complex components. Cross-linking studies indicated a contact of delta with the DnaX subunits. These observations are consistent with a model where two tau subunits and one each of the gamma, delta', and delta subunits mutually interact to form a pentameric functional core for the DnaX complex.

Replisome-mediated DNA replication

The elaborate process of genomic replication requires a large collection of proteins properly assembled at a DNA replication fork. Several decades of research on the bacterium Escherichia coli and its bacteriophages T4 and T7 have defined the roles of many proteins central to DNA replication. These three different prokaryotic replication systems use the same fundamental components for synthesis at a moving DNA replication fork even though the number and nature of some individual proteins are different and many lack extensive sequence homology. The components of the replication complex can be grouped into functional categories as follows: DNA polymerase, helix destabilizing protein, polymerase accessory factors, and primosome (DNA helicase and DNA primase activities). The replication of DNA derives from a multistep enzymatic pathway that features the assembly of accessory factors and polymerases into a functional holoenzyme; the separation of the double-stranded template DNA by helicase activity and its coupling to the primase synthesis of RNA primers to initiate Okazaki fragment synthesis; and the continuous and discontinuous synthesis of the leading and lagging daughter strands by the polymerases. This review summarizes and compares and contrasts for these three systems the types, timing, and mechanism of reactions and of protein-protein interactions required to initiate, control, and coordinate the synthesis of the leading and lagging strands at a DNA replication fork and comments on their generality.

tau binds and organizes Escherichia coli replication proteins through distinct domains: domain III, shared by gamma and tau, oligomerizes DnaX

The tau and gamma proteins of the DNA polymerase III holoenzyme DnaX complex are products of the dnaX gene with gamma being a truncated version of tau arising from ribosomal frameshifting. tau is comprised of five structural domains, the first three of which are shared by gamma (Gao, D., and McHenry, C. (2001) J. Biol. Chem. 276, 4433-4453). In the absence of the other holoenzyme subunits, DnaX exists as a tetramer. Association of delta, delta', chi, and psi with domain III of DnaX(4) results in a DnaX complex with a stoichiometry of DnaX(3)deltadelta'chipsi. To identify which domain facilitates DnaX self-association, we examined the properties of purified biotin-tagged DnaX fusion proteins containing domains I-II or III-V. Unlike domain I-II, treatment of domain III-V, gamma, and tau with the chemical cross-linking reagent BS3 resulted in the appearance of high molecular weight intramolecular cross-linked protein. Gel filtration of domains I-II and III-V demonstrated that domain I-II was monomeric, and domain III-V was an oligomer. Biotin-tagged domain III-V, and not domain I-II, was able to form a mixed DnaX complex by recruiting tau, delta, delta', chi, and psi onto streptavidin-agarose beads. Thus, domain III not only contains the delta, delta', chi, and psi binding interface, but also the region that enables DnaX to oligomerize.

Assembly of DNA polymerase III holoenzyme: co-assembly of gamma and tau is inhibited by DnaX complex accessory proteins but stimulated by DNA polymerase III core

Although the two alternative Escherichia coli dnaX gene products, tau and gamma, are found co-assembled in purified DNA polymerase III holoenzyme, the pathway of assembly is not well understood. When the 10 subunits of holoenzyme are simultaneously mixed, they rapidly form a nine-subunit assembly containing tau but not gamma. We developed a new assay based on the binding of complexes containing biotin-tagged tau to streptavidin-coated agarose beads to investigate the effects of various DNA polymerase III holoenzyme subunits on the kinetics of co-assembly of gamma and tau into the same complex. Auxiliary proteins in combination with delta' almost completely blocked co-assembly, whereas chipsi or delta' alone slowed the association only moderately compared with the interaction of tau with gamma alone. In contrast, DNA polymerase III core, in the absence of deltadelta' and chipsi, accelerated the co-assembly of tau and gamma, suggesting a role for DNA polymerase III' [tau(2)(pol III core)(2)] in the assembly pathway of holoenzyme.

Crystal structure of the processivity clamp loader gamma (gamma) complex of E. coli DNA polymerase III

The gamma complex, an AAA+ ATPase, is the bacterial homolog of eukaryotic replication factor C (RFC) that loads the sliding clamp (beta, homologous to PCNA) onto DNA. The 2.7/3.0 A crystal structure of gamma complex reveals a pentameric arrangement of subunits, with stoichiometry delta':gamma(3):delta. The C-terminal domains of the subunits form a circular collar that supports an asymmetric arrangement of the N-terminal ATP binding domains of the gamma motor and the structurally related domains of the delta' stator and the delta wrench. The structure suggests a mechanism by which the gamma complex switches between a closed state, in which the beta-interacting element of delta is hidden by delta', and an open form similar to the crystal structure, in which delta is free to bind to beta.

Conditional coupling of leading-strand and lagging-strand DNA synthesis at bacteriophage T4 replication forks

Eight proteins encoded by bacteriophage T4 are required for the replicative synthesis of the leading and lagging strands of T4 DNA. We show here that active T4 replication forks, which catalyze the coordinated synthesis of leading and lagging strands, remain stable in the face of dilution provided that the gp44/62 clamp loader, the gp45 sliding clamp, and the gp32 ssDNA-binding protein are present at sufficient levels after dilution. If any of these accessory proteins is omitted from the dilution mixture, uncoordinated DNA synthesis occurs, and/or large Okazaki fragments are formed. Thus, the accessory proteins must be recruited from solution for each round of initiation of lagging-strand synthesis. A modified bacteriophage T7 DNA polymerase (Sequenase) can replace the T4 DNA polymerase for leading-strand synthesis but not for well coordinated lagging-strand synthesis. Although T4 DNA polymerase has been reported to self-associate, gel-exclusion chromatography displays it as a monomer in solution in the absence of DNA. It forms no stable holoenzyme complex in solution with the accessory proteins or with the gp41-gp61 helicase-primase. Instead, template DNA is required for the assembly of the T4 replication complex, which then catalyzes coordinated synthesis of leading and lagging strands in a conditionally coupled manner.

The DNA polymerase III holoenzyme: an asymmetric dimeric replicative complex with leading and lagging strand polymerases

The DNA Polymerase III holoenzyme forms initiation complexes on primed DNA in an ATP-dependent reaction. We demonstrate that the nonhydrolyzable ATP analog, ATP gamma S, supports the formation of an isolable leading strand complex that loads and replicates the lagging strand only in the presence of ATP, beta, and the single-stranded DNA binding protein. The single endogenous DnaX complex within DNA polymerase III holoenzyme assembles beta onto both the leading and lagging strand polymerases by an ordered mechanism. The dimeric replication complex disassembles in the opposite order from which it assembled. Upon ATP gamma S-induced dissociation, the leading strand polymerase is refractory to disassembly allowing cycling to occur exclusively on the lagging strand. These results establish holoenzyme as an intrinsic asymmetric dimer with distinguishable leading and lagging strand polymerases.

An analysis of the factory model for chromosome replication and segregation in bacteria

Recent advances in microscopy have given us important clues as to the nature of chromosome segregation in bacteria. Most current observations favour the view that the process is co-replicational: DNA replication forks are anchored at the cell centre, and the newly replicated DNA is moved towards the cell poles. This scheme can account for orderly segregation even at high growth rates where multiple replication cycles overlap. We argue that there are five distinct activities directly involved in co-replicational segregation dynamics. These we refer to as Push, Direct, Condense, Hold and Clear. We attempt to assign one of these roles to each protein implicated in chromosome segregation. The proposed process is very different from mitosis in eukaryotic cells and perhaps more closely resembles the formation of separate sister chromatids during DNA replication.

tau binds and organizes Escherichia coli replication through distinct domains. Partial proteolysis of terminally tagged tau to determine candidate domains and to assign domain V as the alpha binding domain

The tau subunit dimerizes Escherichia coli DNA polymerase III core through interactions with the alpha subunit. In addition to playing critical roles in the structural organization of the holoenzyme, tau mediates intersubunit communications required for efficient replication fork function. We identified potential structural domains of this multifunctional subunit by limited proteolysis of C-terminal biotin-tagged tau proteins. The cleavage sites of each of eight different proteases were found to be clustered within four regions of the tau subunit. The second susceptible region corresponds to the hinge between domain II and III of the highly homologous delta' subunit, and the third region is near the C-terminal end of the tau-delta' alignment (Guenther, B., Onrust, R., Sali, A., O'Donnell, M., and Kuriyan, J. (1997) Cell 91, 335-345). We propose a five-domain structure for the tau protein. Domains I and II are based on the crystallographic structure of delta' by Guenther and colleagues. Domains III-V are based on our protease cleavage results. Using this information, we expressed biotin-tagged tau proteins lacking specific protease-resistant domains and analyzed their binding to the alpha subunit by surface plasmon resonance. Results from these studies indicated that the alpha binding site of tau lies within its C-terminal 147 residues (domain V).

A novel assembly mechanism for the DNA polymerase III holoenzyme DnaX complex: association of deltadelta' with DnaX(4) forms DnaX(3)deltadelta'

We have constructed a plasmid-borne artificial operon that expresses the six subunits of the DnaX complex of Escherichia coli DNA polymerase III holoenzyme: tau, gamma, delta, delta', chi and psi. Induction of this operon followed by assembly in vivo produced two taugamma mixed DnaX complexes with stoichiometries of tau(1)gamma(2)deltadelta'chipsi and tau(2)gamma(1)deltadelta'chipsi rather than the expected gamma(2)tau(2)deltadelta'chipsi. We observed the same heterogeneity when taugamma mixed DnaX complexes were reconstituted in vitro. Re-examination of homomeric DnaX tau and gamma complexes assembled either in vitro or in vivo also revealed a stoichiometry of DnaX(3)deltadelta'chipsi. Equilibrium sedimentation analysis showed that free DnaX is a tetramer in equilibrium with a free monomer. An assembly mechanism, in which the association of heterologous subunits with a homomeric complex alters the stoichiometry of the homomeric assembly, is without precedent. The significance of our findings to the architecture of the holoenzyme and the clamp-assembly apparatus of all other organisms is discussed.

The delta subunit of DNA polymerase III holoenzyme serves as a sliding clamp unloader in Escherichia coli

In Escherichia coli, the circular beta sliding clamp facilitates processive DNA replication by tethering the polymerase to primer-template DNA. When synthesis is complete, polymerase dissociates from beta and DNA and cycles to a new start site, a primed template loaded with beta. DNA polymerase cycles frequently during lagging strand replication while synthesizing 1-2-kilobase Okazaki fragments. The clamps left behind remain stable on DNA (t(12) approximately 115 min) and must be removed rapidly for reuse at numerous primed sites on the lagging strand. Here we show that delta, a single subunit of DNA polymerase III holoenzyme, opens beta and slips it off DNA (k(unloading) = 0.011 s(-)(1)) at a rate similar to that of the multisubunit gamma complex clamp loader by itself (0.015 s(-)(1)) or within polymerase (pol) III* (0.0065 s(-)(1)). Moreover, unlike gamma complex and pol III*, delta does not require ATP to catalyze clamp unloading. Quantitation of gamma complex subunits (gamma, delta, delta', chi, psi) in E. coli cells reveals an excess of delta, free from gamma complex and pol III*. Since pol III* and gamma complex occur in much lower quantities and perform several DNA metabolic functions in replication and repair, the delta subunit probably aids beta clamp recycling during DNA replication.

Two distinct triggers for cycling of the lagging strand polymerase at the replication fork

There are two modes of DNA synthesis at a replication fork. The leading strand is synthesized in a continuous fashion in lengths that in Escherichia coli can be in excess of 2 megabases. On the other hand, the lagging strand is synthesized in relatively short stretches of 2 kilobases. Nevertheless, identical assemblies of the DNA polymerase III core tethered to the beta sliding clamp account for both modes of DNA synthesis. Yet the same lagging strand polymerase accounts for the synthesis of all Okazaki fragments at a replication fork, cycling repeatedly every 1 or 2 s from the 3'-end of the just-completed fragment to the 3'-end of the new primer. Several models have been invoked to account for the rapid cycling of a polymerase complex that can remain bound to the template for upward of 40 min. By using isolated replication protein-DNA template complexes, we have tested these models and show here that cycling of the lagging strand polymerase can be triggered by either the action of primase binding to the replisome and synthesizing a primer or by collision of the lagging strand polymerase with the 5'-end of the previous Okazaki fragment.

Escherichia coli DNA polymerase III tau- and gamma-subunit conserved residues required for activity in vivo and in vitro

The Escherichia coli DNA polymerase III tau and gamma subunits are single-strand DNA-dependent ATPases (the latter requires the delta and delta' subunits for significant ATPase activity) involved in loading processivity clamp beta. They are homologous to clamp-loading proteins of many organisms from phages to humans. Alignment of 27 prokaryotic tau/gamma homologs and 1 eukaryotic tau/gamma homolog has refined the sequences of nine previously defined identity and functional motifs. Mutational analysis has defined highly conserved residues required for activity in vivo and in vitro. Specifically, mutations introduced into highly conserved residues within three of those motifs, the P loop, the DExx region, and the SRC region, inactivated complementing activity in vivo and clamp loading in vitro and reduced ATPase catalytic efficiency in vitro. Mutation of a highly conserved residue within a fourth motif, VIc, inactivated clamp-loading activity and reduced ATPase activity in vitro, but the mutant gene, on a multicopy plasmid, retained complementing activity in vivo and the mutant gene also supported apparently normal replication and growth as a haploid, chromosomal allele.

Mechanisms of DNA replication

Advances in recent years have led to exciting new ideas about the initiation, regulation and coordination of DNA replication. Structural studies have yielded fascinating glimpses of replisome action. In addition, the involvement of replication proteins in other cellular processes has blurred the lines between replication, repair and recombination.

Tandem duplication. A novel type of triplet repeat instability

Triplet repeat sequence (TRS) inserts containing (CTG.CAG)(n) (17-175 units in length) were tandemly duplicated when propagated in plasmids in Escherichia coli. The products of this novel type of TRS genetic instability are tracts of as many as 34 multiple units, which contain the entire TRS as well as 129 base pairs of nonrepetitive flanking sequence. The duplication process required the presence of two or more TRS-containing units. Close proximity (170 base pairs) of the TRS to the R6K gamma origin of replication of the pUTminiTn5Cm-derived constructs stimulated the tandem duplication process. These events are proposed to occur due to secondary structure formation, stalling of DNA synthesis, and slippage-mediated misalignment of the complementary strands relative to each other during DNA replication. This mechanism may account for the TRS-associated duplications in protein kinase and metalloprotease genes in neuroblastomas and melanomas, as well as the massive repeat expansions in type II triplet repeat neurological diseases.

Characterization of bacteriophage T4-coordinated leading- and lagging-strand synthesis on a minicircle substrate

The DNA replication complex of bacteriophage T4 has been assembled as a single unit on a minicircle substrate with a replication fork that permits an independent measurement of the amount of DNA synthesis on both the leading and lagging strands. The assembled replisome consists of the T4 polymerase [gene product 43 (gp43)], clamp protein (gp45), clamp loader (gp44/62), helicase (gp41), helicase accessory factor (gp59), primase (gp61), and single-stranded DNA binding protein (gp32). We demonstrate that on the minicircle the synthesis of the leading and lagging strands are coordinated and that the C-terminal domain of the gp32 protein regulates this coordination. We show that the reconstituted replisome encompasses two coupled holoenzyme complexes and present evidence that this coupling might include a gp43 homodimer interaction.

Characterization of the unique C terminus of the Escherichia coli tau DnaX protein. Monomeric C-tau binds alpha AND DnaB and can partially replace tau in reconstituted replication forks

A contact between the dimeric tau subunit within the DNA polymerase III holoenzyme and the DnaB helicase is required for replication fork propagation at physiologically-relevant rates (Kim, S., Dallmann, H. G., McHenry, C. S., and Marians, K. J. (1996) Cell 84, 643-650). In this report, we exploit the OmpT protease to generate C-tau, a protein containing only the unique C-terminal sequences of tau, free of the sequences shared with the alternative gamma frameshifting product of dnaX. We have established that C-tau is a monomer by sedimentation equilibrium and sedimentation velocity ultracentrifugation. Monomeric C-tau binds the alpha catalytic subunit of DNA polymerase III with a 1:1 stoichiometry. C-tau also binds DnaB, revealed by a coupled immunoblotting method. C-tau restores the rapid replication rate of inefficient forks reconstituted with only the gamma dnaX gene product. The acceleration of the DnaB helicase can be observed in the absence of primase, when only leading-strand replication occurs. This indicates that C-tau, bound only to the leading-strand polymerase, can trigger the conformational change necessary for DnaB to assume the fast, physiologically relevant form.

Suppression of a DnaX temperature-sensitive polymerization defect by mutation in the initiation gene, dnaA, requires functional oriC

Temperature sensitivity of DNA polymerization and growth, resulting from mutation of the tau and gamma subunits of Escherichia coli DNA polymerase III, are suppressed by Cs,Sx mutations of the initiator gene, dnaA. These mutations simultaneously cause defective initiation at 20 degrees C. Efficient suppression, defined as restoration of normal growth rate at 39 degrees C to essentially all the cells, depends on functional oriC. Increasing DnaA activity in a strain capable of suppression, by introducing a copy of the wild-type allele, increasing the suppressor gene dosage or introducing a seqA mutation, reversed the suppression. This suggests that the suppression mechanism depends on reduced activity of DnaACs, Sx. Models that assume that suppression results from an initiation defect or from DnaACs,Sx interaction with polymerization proteins during nascent strand synthesis are proposed.

Recombinational DNA repair in bacteria and the RecA protein

In bacteria, the major function of homologous genetic recombination is recombinational DNA repair. This is not a process reserved only for rare double-strand breaks caused by ionizing radiation, nor is it limited to situations in which the SOS response has been induced. Recombinational DNA repair in bacteria is closely tied to the cellular replication systems, and it functions to repair damage at stalled replication forks, Studies with a variety of rec mutants, carried out under normal aerobic growth conditions, consistently suggest that at least 10-30% of all replication forks originating at the bacterial origin of replication are halted by DNA damage and must undergo recombinational DNA repair. The actual frequency may be much higher. Recombinational DNA repair is both the most complex and the least understood of bacterial DNA repair processes. When replication forks encounter a DNA lesion or strand break, repair is mediated by an adaptable set of pathways encompassing most of the enzymes involved in DNA metabolism. There are five separate enzymatic processes involved in these repair events: (1) The replication fork assembled at OriC stalls and/or collapses when encountering DNA damage. (2) Recombination enzymes provide a complementary strand for a lesion isolated in a single-strand gap, or reconstruct a branched DNA at the site of a double-strand break. (3) The phi X174-type primosome (or repair primosome) functions in the origin-independent reassembly of the replication fork. (4) The XerCD site-specific recombination system resolves the dimeric chromosomes that are the inevitable by-product of frequent recombination associated with recombinational DNA repair. (5) DNA excision repair and other repair systems eliminate lesions left behind in double-stranded DNA. The RecA protein plays a central role in the recombination phase of the process. Among its many activities, RecA protein is a motor protein, coupling the hydrolysis of ATP to the movement of DNA branches.

Illegitimate recombination induced by overproduction of DnaB helicase in Escherichia coli

Illegitimate recombination that usually takes place at a low frequency is greatly enhanced by treatment with DNA-damaging agents. It is thought that DNA double-strand breaks induced by this DNA damage are important for initiation of illegitimate recombination. Here we show that illegitimate recombination is enhanced by overexpression of the DnaB protein in Escherichia coli. The recombination enhanced by DnaB overexpression occurred between short regions of homology. We propose a model for the initiation of illegitimate recombination in which DnaB overexpression may excessively unwind DNA at replication forks and induce double-strand breaks, resulting in illegitimate recombination. The defect in RecQ has a synergistic effect on the increased illegitimate recombination in cells containing the overproduced DnaB protein, implying that DnaB works in the same pathway as RecQ does but that they work at different steps.

Mismatch extension by Escherichia coli DNA polymerase III holoenzyme

The in vitro fidelity of Escherichia coli DNA polymerase III holoenzyme (HE) is characterized by an unusual propensity for generating (-1)-frameshift mutations. Here we have examined the capability of HE isolated from both a wild-type and a proofreading-impaired mutD5 strain to polymerize from M13mp2 DNA primer-templates containing a terminal T(template).C mismatch. These substrates contained either an A or a G as the next (5') template base. The assay allows distinction between: (i) direct extension of the terminal C (producing a base substitution), (ii) exonucleolytic removal of the C, or (iii), for the G-containing template, extension after misalignment of the C on the next template G (producing a (-1)-frameshift). On the A-containing substrate, both HEs did not extend the terminal C (<1%); instead, they exonucleolytically removed it (>99%). In contrast, on the G-containing substrate, the MutD5 HE yielded 61% (-1)-frameshifts and 6% base substitutions. The wild-type HE mostly excised the mispaired C from this substrate before extension (98%), but among the 2% mutants, (-1)-frameshifts exceeded base substitutions by 20 to 1. The preference of polymerase III HE for misalignment extension over direct mismatch extension provides a basis for explaining the in vitro (-1)-frameshift specificity of polymerase III HE.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Coordinated leading and lagging strand DNA synthesis on a minicircular template

The coordinated synthesis of both leading and lagging DNA strands is thought to involve a dimeric DNA polymerase and a looping of the lagging strand so that both strands can be synthesized in the same direction. We have constructed a minicircle with a replication fork that permits an assessment of the stoichiometry of the proteins and a measurement of the synthesis of each strand. The replisome consisting of bacteriophage T7 DNA polymerase, helicase, primase, and single-stranded DNA-binding protein mediates coordinated replication. The criteria for coordination are fulfilled: (1) a replication loop is formed, (2) leading and lagging strand synthesis are coupled, (3) the lagging strand polymerase recycles from one Okazaki fragment to another, and (4) the length of Okazaki fragments is regulated. T7 single-stranded DNA-binding protein is essential for coordination.

Identification of dnaX as a high-copy suppressor of the conditional lethal and partition phenotypes of the parE10 allele

Termination of DNA replication, complete topological unlinking of the parental template DNA strands, partition of the daughter chromosomes, and cell division follow in an ordered and interdependent sequence during normal bacterial growth. In Escherichia coli, topoisomerase IV (Topo IV), encoded by parE and parC, is responsible for decatenation of the two newly formed chromosomes. In an effort to uncover the pathway of information flow between the macromolecular processes that describe these events, we identified dnaX, encoding the tau and gamma subunits of the DNA polymerase III holoenzyme, as a high-copy suppressor of the temperature-sensitive phenotype of the parE10 allele. We show that suppression derives from overexpression of the gamma, but not the tau, subunit of the holoenzyme and that the partition defect of parE10 cells is nearly completely reverted at the nonpermissive temperature as well. These observations suggest a possible association between Topo IV and the replication machinery.

Formation of a DNA loop at the replication fork generated by bacteriophage T7 replication proteins

Intermediates in the replication of circular and linear M13 double-stranded DNA by bacteriophage T7 proteins have been examined by electron microscopy. Synthesis generated double-stranded DNA molecules containing a single replication fork with a linear duplex tail. A complex presumably consisting of T7 DNA polymerase and gene 4 helicase/primase molecules was present at the fork together with a variable amount of single-stranded DNA sequestered by gene 2.5 single-stranded DNA binding protein. Analysis of the length distribution of Okazaki fragments formed at different helicase/primase concentrations was consistent with coupling of leading and lagging strand replication. Fifteen to forty percent of the templates engaged in replication have a DNA loop at the replication fork. The loops are fully double-stranded with an average length of approximately 1 kilobase. Labeling with biotinylated dCTP showed that the loops consist of newly synthesized DNA, and synchronization experiments using a linear template with a G-less cassette demonstrated that the loops are formed by active displacement of the lagging strand. A long standing feature of models for coupled leading/lagging strand replication has been the presence of a DNA loop at the replication fork. This study provides the first direct demonstration of such loops.

Role of the core DNA polymerase III subunits at the replication fork. Alpha is the only subunit required for processive replication

The DNA polymerase III holoenzyme is composed of 10 subunits. The core of the polymerase contains the catalytic polymerase subunit, alpha, the proofreading 3'-->5' exonuclease, epsilon, and a subunit of unknown function, theta. The availability of the holoenzyme subunits in purified form has allowed us to investigate their roles at the replication fork. We show here that of the three subunits in the core polymerase, only alpha is required to form processive replication forks that move at high rates and that exhibit coupled leading- and lagging-strand synthesis in vitro. Taken together with previous data this suggests that the primary determinant of replication fork processivity is the interaction between another holoenzyme subunit, tau, and the replication fork helicase, DnaB.

Conservation of the Escherichia coli dnaX programmed ribosomal frameshift signal in Salmonella typhimurium

Escherichia coli DNA polymerase III subunits tau and gamma are produced from one gene, dnaX, by a programmed ribosomal frameshift which generates the C terminal of gamma within the tau reading frame. To help evaluate the role of the dispensable gamma, the distribution of tau and gamma homologs in several other species and the sequence of the Salmonella typhimurium dnaX were determined. All four enterobacteria tested produce tau and gamma homologs. S. typhimurium dnaX is 83% identical to E. coli dnaX, but all four components of the frameshift signal are 100% conserved.

The interaction between helicase and primase sets the replication fork clock

The synthesis of an Okazaki fragment occurs once every 1-2 s at the Escherichia coli replication fork and requires precise coordination of the enzymatic activities required. We have shown previously that the primase is recruited anew from solution for each cycle of Okazaki fragment synthesis and that association of primase with the replication fork is via a protein-protein interaction with the helicase, DnaB. We describe here mutant primases that have an altered interaction with DnaB and that direct the synthesis of Okazaki fragments of altered length compared to the wild-type. The mutant primases were deficient only in their ability to participate in replication reactions where their entry to the DNA was provided by the initial protein-protein interaction with DnaB. The primer synthesis capacity of these proteins remained unaffected, as was their ability to interact with the DNA polymerase III holoenzyme. Neither replication fork rate nor the efficiency of primer utilization was affected at replication forks programmed by the mutant enzymes. Thus, the interaction between DnaG and DnaB at the replication fork is the primary regulator of the cycle of Okazaki fragment synthesis.

The extreme C terminus of primase is required for interaction with DnaB at the replication fork

We have shown previously that a protein-protein interaction between DnaG and DnaB is required to attract the primase to the replication fork. This interaction was mediated by the C-terminal 16-kDa domain (p16) of the primase. A screen was developed that allowed the detection of mutant p16 proteins that did not interact with DnaB. Various mutagenesis protocols were used to localize this interaction domain to the extreme C terminus of the primase. A mutant primase missing only the C-terminal 16 amino acids was isolated and its activities examined. This mutant enzyme was fully active as a primase, but was incapable of interacting with DnaB. Thus, the mutant primase could not support DNA synthesis in either the general priming reaction or during phiX174 complementary strand DNA replication. Alanine cluster mutagenesis and deletion analysis in p16 allowed the further localization of the interaction domain to the extreme C-terminal 8 amino acids in primase.