Replisome assembly reveals the basis for asymmetric function in leading and lagging strand 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.

A tale of toroids in DNA metabolism

A strikingly large number of the proteins involved in DNA metabolism adopt a toroidal -- or ring-shaped -- quaternary structure, even though they have completely unrelated functions. Given that these proteins all use DNA as a substrate, their convergence to one shape is probably not a coincidence. Ring-forming proteins may have been selected during evolution for advantages conferred by the toroidal shape on their interactions with DNA.

Analysis of the Okazaki fragment distributions along single long DNAs replicated by the bacteriophage T4 proteins

Rolling circle replication from M13 DNA circles was previously reconstituted in vitro using purified factors encoded by bacteriophage T4. The products are duplex circles with linear tails >100 kb. When T4 DNA polymerase deficient in 3' to 5' exonuclease activity was employed, electron microscopy revealed short single-stranded DNA "flaps" along the replicated tails. This marked the beginning of each Okazaki fragment, allowing an analysis of the lengths of sequential Okazaki fragments on individual replicating molecules. DNAs containing runs of Okazaki fragments of similar length were found, but most showed large length variations over runs of six or more fragments reflecting the broad population distribution.

The DNA replication machine of a gram-positive organism

This report outlines the protein requirements and subunit organization of the DNA replication apparatus of Streptococcus pyogenes, a Gram-positive organism. Five proteins coordinate their actions to achieve rapid and processive DNA synthesis. These proteins are: the PolC DNA polymerase, tau, delta, delta', and beta. S. pyogenes dnaX encodes only the full-length tau, unlike the Escherichia coli system in which dnaX encodes two proteins, tau and gamma. The S. pyogenes tau binds PolC, but the interaction is not as firm as the corresponding interaction in E. coli, underlying the inability to purify a PolC holoenzyme from Gram-positive cells. The tau also binds the delta and delta' subunits to form a taudeltadelta' "clamp loader." PolC can assemble with taudeltadelta' to form a PolC.taudeltadelta' complex. After PolC.taudeltadelta' clamps beta to a primed site, it extends DNA 700 nucleotides/second in a highly processive fashion. Gram-positive cells contain a second DNA polymerase, encoded by dnaE, that has homology to the E. coli alpha subunit of E. coli DNA polymerase III. We show here that the S. pyogenes DnaE polymerase also functions with the beta clamp.

Identification of a region of Escherichia coli DnaB required for functional interaction with DnaG at the replication fork

The fundamental activities of the replicative primosomes of Escherichia coli are provided by DnaB, the replication fork DNA helicase, and DnaG, the Okazaki fragment primase. As we have demonstrated previously, DnaG is recruited to the replication fork via a transient protein-protein interaction with DnaB. Here, using site-directed amino acid mutagenesis, we have defined the region on DnaB required for this protein-protein interaction. Mutations in this region of DnaB affect the DnaB-DnaG interaction during both general priming-directed and phiX174 complementary strand DNA synthesis, as well as at replication forks reconstituted in rolling circle DNA replication reactions. The behavior of the purified mutant DnaB proteins in the various replication systems suggests that access to the DnaG binding pocket on DnaB may be restricted at the replication fork.

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.

PriA-directed replication fork restart in Escherichia coli

The encounter of a replication fork with either a damaged DNA template, a nick in the template strand or a 'frozen' protein-DNA complex can stall the replisome and cause it to fall apart. Such an event generates a requirement for replication fork restart if the cell is going to survive. Recent evidence shows that replication fork restart is effected by the action of the recombination proteins generating a substrate for PriA-directed replication fork assembly.

Structure and activity associated with multiple forms of Schizosaccharomyces pombe DNA polymerase delta

DNA polymerase delta (Pol delta) isolated from Schizosaccharomyces pombe (sp) consists of at least four subunits, Pol3, Cdc1, Cdc27, and Cdm1. We have reconstituted the four-subunit complex by simultaneously expressing these polypeptides in baculovirus-infected insect cells. The properties of the purified cloned spPol delta were identical to the native spPol delta isolated from S. pombe cells. In addition, we also isolated a three-subunit complex containing Pol3, Cdc1, and Cdm1. Both three- and four-subunit complexes required replication factor C and proliferating cell nuclear antigen for DNA replication. However, in the presence of low levels of polymerase complexes, the three-subunit complex was less efficient than the four-subunit complex in supporting DNA replication. The inefficient synthesis of DNA by the three-subunit complex can be remedied by the addition of Cdc27, the subunit missing in the three-subunit complex. Gel filtration analysis demonstrated that the three-subunit complex is a monomer of the heterotrimer (Pol3, Cdc1, and Cdm1) and that the four-subunit complex is a dimer of the heterotetramer (Pol3, Cdc1, Cdc27, and Cdm1), similar to the structure of native spPol delta. We have further shown that Cdc1 and Cdc27 interact to form a heterodimeric complex. Gel filtration studies indicate that the structure of this complex is dimeric. These observations suggest that the Cdc27 subunit may play an important role contributing to the dimerization of Pol delta.

Nonlinearity in genetic decoding: homologous DNA replicase genes use alternatives of transcriptional slippage or translational frameshifting

The tau and gamma subunits of DNA polymerase III are both encoded by a single gene in Escherichia coli and Thermus thermophilus. gamma is two-thirds the size of tau and shares virtually all its amino acid sequence with tau. E. coli and T. thermophilus have evolved very different mechanisms for setting the approximate 1:1 ratio between tau and gamma. Both mechanisms put ribosomes into alternate reading frames so that stop codons in the new frame serve to make the smaller gamma protein. In E. coli, approximately 50% of initiating ribosomes translate the dnaX mRNA conventionally to give tau, but the other 50% shift into the -1 reading frame at a specific site (A AAA AAG) in the mRNA to produce gamma. In T. thermophilus ribosomal frameshifting is not required: the dnaX mRNA is a heterogeneous population of molecules with different numbers of A residues arising from transcriptional slippage on a run of nine T residues in the DNA template. Translation of the subpopulation containing nine As (or +/- multiples of three As) yields tau. The rest of the population of mRNAs (containing nine +/- nonmultiples of three As) puts ribosomes into the alternate reading frames to produce the gamma protein(s). It is surprising that two rather similar dnaX sequences in E. coli and T. thermophilus lead to very different mechanisms of expression.

The DnaX-binding subunits delta' and psi are bound to gamma and not tau in the DNA polymerase III holoenzyme

The DnaX complex subassembly of the DNA polymerase III holoenzyme is comprised of the DnaX proteins tau and gamma and the auxiliary subunits delta, delta', chi, and psi, which together load the beta processivity factor onto primed DNA in an ATP-dependent reaction. delta' and psi bind directly to DnaX whereas delta and chi bind to delta' and psi, respectively (Onrust, R., Finkelstein, J., Naktinis, V., Turner, J., Fang, L., and O'Donnell, M. (1995) J. Biol. Chem. 270, 13348-13357). Until now, it has been unclear which DnaX protein, tau or gamma, in holoenzyme binds the auxiliary subunits delta, delta', chi,and psi. Treatment of purified holoenzyme with the homobifunctional cross-linker bis(sulfosuccinimidyl)suberate produces covalently cross-linked gamma-delta' and gamma-psi complexes identified by Western blot analysis. Immunodetection of cross-linked species with anti-delta' and anti-psi antibodies revealed that no tau-delta' or tau-psi cross-links had formed, suggesting that the delta' and psi subunits reside only on gamma within holoenzyme.

Dynamics of beta and proliferating cell nuclear antigen sliding clamps in traversing DNA secondary structure

Chromosomal replicases of cellular organisms utilize a ring shaped protein that encircles DNA as a mobile tether for high processivity in DNA synthesis. These "sliding clamps" have sufficiently large linear diameters to encircle duplex DNA and are perhaps even large enough to slide over certain DNA secondary structural elements. This report examines the Escherichia coli beta and human proliferating cell nuclear antigen clamps for their ability to slide over various DNA secondary structures. The results show that these clamps are capable of traversing a 13-nucleotide ssDNA loop, a 4-base pair stem-loop, a 4-nucleotide 5' tail, and a 15-mer bubble within the duplex. However, upon increasing the size of these structures (20-nucleotide loop, 12-base pair stem-loop, 28-nucleotide 5' tail, and 20-nucleotide bubble) the sliding motion of the beta and proliferating cell nuclear antigen over these elements is halted. Studies of the E. coli replicase, DNA polymerase III holoenzyme, in chain elongation with the beta clamp demonstrate that upon encounter with an oligonucleotide annealed in its path, it traverses the duplex and resumes synthesis on the 3' terminus of the oligonucleotide. This sliding and resumption of synthesis occurs even when the oligonucleotide contains a secondary structure element, provided the beta clamp can traverse the structure. However, upon encounter with a downstream oligonucleotide containing a large internal secondary structure, the holoenzyme clears the obstacle by strand displacing the oligonucleotide from the template. Implications of these protein dynamics to DNA transactions are discussed.

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.

Correlations and anticorrelations among nucleotide distributions along the genomes of various organisms

We have analyzed correlations of nucleotide distributions along more than 50 megabases of the longest sequenced parts of the human, mouse, Drosophila, Arabidopsis, yeast, E.coli and three kinds of viral genomes. The strongest correlations were observed between the distributions of C and G, in particular in the genome of Drosophila. This correlation was much weaker, though still strong, in the human genome and E.coli that exhibited the same level of this correlation. The C/G correlation hardly originates from the isochores because the isochores were not reported to occur in the genomes of Drosophila and E. coil. The genomic distribution curves of adenine and thymine were also positively correlated in all analyzed organisms except for the yeast where they were anticorrelated. Still stronger anticorrelations were, however, observed between the genomic distributions of A and C and between G and T. These genomic distributions anticorrelated almost generally and very strong. These anticorrelations are likely to originate from point mutations resulting from unrepaired GA mispairing as a replication intermediate. The C/A or G/T anticorrelation or compensation is a very strong and general new phenomenon that shapes the genomic nucleotide sequences.

Replisome assembly at oriC, the replication origin of E. coli, reveals an explanation for initiation sites outside an origin

This study outlines the events downstream of origin unwinding by DnaA, leading to assembly of two replication forks at the E. coli origin, oriC. We show that two hexamers of DnaB assemble onto the opposing strands of the resulting bubble, expanding it further, yet helicase action is not required. Primase cannot act until the helicases move 65 nucleotides or more. Once primers are formed, two molecules of the large DNA polymerase III holoenzyme machinery assemble into the bubble, forming two replication forks. Primer locations are heterogeneous; some are even outside oriC. This observation generalizes to many systems, prokaryotic and eukaryotic. Heterogeneous initiation sites are likely explained by primase functioning with a moving helicase target.

Asymmetric substitution patterns: a review of possible underlying mutational or selective mechanisms

In the absence of bias between the two DNA strands for mutation and selection, the base composition within each strand should be such that A = T and C = G (this state is called Parity Rule type 2, PR2). At a genome scale, i.e. when considering the base composition of a whole genome, PR2 is a good approximation, but there are local and systematic deviations. The question is whether these deviations are a consequence of an underlying bias in mutation or selection. We have tried to review published hypotheses to classify them within the mutational or selective group. This dichotomy is, however, too crude because there is at least one hypothesis based simultaneously upon mutation and selection.

Initiation of bidirectional replication at the chromosomal origin is directed by the interaction between helicase and primase

Several protein-protein interactions have been shown to be critical for proper replication fork function in Escherichia coli. These include interactions between the polymerase and the helicase, the helicase and the primase, and the primase and the polymerase. We have studied the influence of these interactions on proper initiation at oriC by using mutant primases defective in their interaction with the helicase and DNA polymerase III holoenzyme lacking the tau subunit so that it will not interact with the helicase. We show here that accurate initiation of bidirectional DNA replication from oriC is dependent on proper placement of the primers for leading strand synthesis and is thus governed primarily by the interaction between the helicase and primase.

Inactivation of Escherichia coli DnaA protein by DNA polymerase III and negative regulations for initiation of chromosomal replication

Genetic and biochemical evidence indicates that initiation of chromosomal replication in Escherichia coli occurs in a nucleoprotein complex at the replication origin (oriC) formed with DnaA protein. The frequency of initiation at oriC is tightly regulated to only once per chromosome per cell cycle. To prevent untimely, extra initiations, negative control for initiation is indispensable. Recently, we found that the function of the initiator protein, DnaA, is controlled by DNA polymerase III holoenzyme, the replicase of the chromosome. The ATP-bound form of DnaA protein, an active form for initiation, is efficiently converted to the ADP bound form, an inactive form, since a subunit of the polymerase loaded on DNA (beta subunit sliding clamp) stimulates hydrolysis of ATP bound to DnaA protein. Comparison of this system, RIDA (regulatory inactivation of DnaA), with other systems for negative regulation of initiation is included in this review, and the roles of these systems for concerted control for initiation during the cell cycle are discussed.

Replication of tobacco mosaic virus RNA

The replication of tobacco mosaic virus (TMV) RNA involves synthesis of a negative-strand RNA using the genomic positive-strand RNA as a template, followed by the synthesis of positive-strand RNA on the negative-strand RNA templates. Intermediates of replication isolated from infected cells include completely double-stranded RNA (replicative form) and partly double-stranded and partly single-stranded RNA (replicative intermediate), but it is not known whether these structures are double-stranded or largely single-stranded in vivo. The synthesis of negative strands ceases before that of positive strands, and positive and negative strands may be synthesized by two different polymerases. The genomic-length negative strand also serves as a template for the synthesis of subgenomic mRNAs for the virus movement and coat proteins. Both the virus-encoded 126-kDa protein, which has amino-acid sequence motifs typical of methyltransferases and helicases, and the 183-kDa protein, which has additional motifs characteristic of RNA-dependent RNA polymerases, are required for efficient TMV RNA replication. Purified TMV RNA polymerase also contains a host protein serologically related to the RNA-binding subunit of the yeast translational initiation factor, eIF3. Study of Arabidopsis mutants defective in RNA replication indicates that at least two host proteins are needed for TMV RNA replication. The tomato resistance gene Tm-1 may also encode a mutant form of a host protein component of the TMV replicase. TMV replicase complexes are located on the endoplasmic reticulum in close association with the cytoskeleton in cytoplasmic bodies called viroplasms, which mature to produce 'X bodies'. Viroplasms are sites of both RNA replication and protein synthesis, and may provide compartments in which the various stages of the virus mutiplication cycle (protein synthesis, RNA replication, virus movement, encapsidation) are localized and coordinated. Membranes may also be important for the configuration of the replicase with respect to initiation of RNA synthesis, and synthesis and release of progeny single-stranded RNA.

Biochemical and electron microscopic image analysis of the hexameric E1 helicase

DNA replication initiator proteins bind site specifically to origin sites and in most cases participate in the early steps of unwinding the duplex. The papillomavirus preinitiation complex that assembles on the origin of replication is composed of proteins E1 and the activator protein E2. E2 is an ancillary factor that increases the affinity of E1 for the ori site through cooperative binding. Here we show that duplex DNA affects E1 (in the absence of E2) to assemble into an active hexameric structure. As a 10-base oligonucleotide can also induce this oligomerization, it seems likely that DNA binding allosterically induces a conformation that enhances hexamers. E1 assembles as a bi-lobed, presumably double hexameric structure on duplex DNA and can initiate bi-directional unwinding from an ori site. The DNA takes an apparent straight path through the double hexamers. Image analysis of E1 hexameric rings shows that the structures are heterogeneous and have either a 6- or 3-fold symmetry. The rings are about 40-50 A thick and 125 A in diameter. The density of the central cavity appears to be a variable and we speculate that a plugged center may represent a conformational flexibility of a subdomain of the monomer, to date unreported for other hexameric helicases.

The internal workings of a DNA polymerase clamp-loading machine

Replicative DNA polymerases are multiprotein machines that are tethered to DNA during chain extension by sliding clamp proteins. The clamps are designed to encircle DNA completely, and they are manipulated rapidly onto DNA by the ATP-dependent activity of a clamp loader. We outline the detailed mechanism of gamma complex, a five-protein clamp loader that is part of the Escherichia coli replicase, DNA polymerase III holoenzyme. The gamma complex uses ATP to open the beta clamp and assemble it onto DNA. Surprisingly, ATP is not needed for gamma complex to crack open the beta clamp. The function of ATP is to regulate the activity of one subunit, delta, which opens the clamp simply by binding to it. The delta' subunit acts as a modulator of the interaction between delta and beta. On binding ATP, the gamma complex is activated such that the delta' subunit permits delta to bind beta and crack open the ring at one interface. The clamp loader-open clamp protein complex is now ready for an encounter with primed DNA to complete assembly of the clamp around DNA. Interaction with DNA stimulates ATP hydrolysis which ejects the gamma complex from DNA, leaving the ring to close around the duplex.

Trading places on DNA--a three-point switch underlies primer handoff from primase to the replicative DNA polymerase

This study reports a primase-to-polymerase switch in E. coli that closely links primase action with extension by DNA polymerase III holoenzyme. We find that primase tightly grips its RNA primer, protecting it from the action of other proteins. However, primase must be displaced before the beta sliding clamp can be assembled on the primed site. A single subunit of the holoenzyme, chi, is dedicated to this primase displacement task. The displacement mechanism depends on a third protein, SSB. Primase requires contact to SSB for its grip on the primed site. The chi subunit also binds SSB, upon which the primase-to-SSB contact is destabilized leading to dissociation of primase and assembly of beta onto the RNA primer. The conservation of this three-point switch, in which two proteins exchange places on DNA via mutually exclusive interaction with a third protein, is discussed.

Mechanism of recruitment of DnaB helicase to the replication origin of the plasmid pSC101

Although many bacterial chromosomes require only one replication initiator protein, e.g., DnaA, most plasmid replicons depend on dual initiators: host-encoded DnaA and plasmid-encoded Rep initiator protein for replication initiation. Using the plasmid pSC101 as a model system, this work investigates the biological rationale for the requirement for dual initiators and shows that the plasmid-encoded RepA specifically interacts with the replicative helicase DnaB. Mutations in DnaB or RepA that disrupt RepA-DnaB interaction cause failure to load DnaB to the plasmid ori in vitro and to replicate the plasmid in vivo. Although, interaction of DnaA with DnaB could not substitute for RepA-DnaB interaction for helicase loading, DnaA along with integration host factor, DnaC, and RepA was essential for helicase loading. Therefore, DnaA is indirectly needed for helicase loading. Instead of a common surface of interaction with initiator proteins, interestingly, DnaB helicase appears to have at least a limited number of nonoverlapping surfaces, each of which interacts specifically with a different initiator protein.

Bacillus subtilis DnaG primase stabilises the bacteriophage SPP1 G40P helicase-ssDNA complex

Purified Bacillus subtilis DnaG primase (predicted molecular mass 68.8 kDa) behaves as a monomer in solution. We demonstrate that DnaG physically interacts with bacteriophage SPP1 hexameric helicase G40P (G40P6) in the absence of ATP. G40P6-ATP forms an unstable complex with ssDNA, and by itself carries out ATP-driven translocation along a ssDNA template with low processivity. The presence of DnaG in the reaction mixture increased the helicase activity of G40P6 about 3-fold, but not the ATPase activity. The results presented here suggest that the DnaG protein stabilises the G40P6-ssDNA complexes.

Role of the putative zinc finger domain of Saccharomyces cerevisiae DNA polymerase epsilon in DNA replication and the S/M checkpoint pathway

It has been proposed that C-terminal motifs of the catalytic subunit of budding yeast polymerase (pol) epsilon (POL2) couple DNA replication to the S/M checkpoint (Navas, T. A., Zheng, Z., and Elledge, S. J. (1995) Cell 80, 29-39). Scanning deletion analysis of the C terminus reveals that 20 amino acid residues between two putative C-terminal zinc fingers are essential for DNA replication and for an intact S/M cell cycle checkpoint. All mutations affecting the inter-zinc finger amino acids or the zinc fingers themselves are sensitive to methylmethane sulfonate and have reduced ability to induce RNR3, showing that the mutants are defective in the transcriptional response to DNA damage as well as the cell cycle response. The mutations affect the assembly of the pol epsilon holoenzyme. Two-hybrid assays show that the POL2 subunit interacts with itself, and that the replication and checkpoint mutants are specifically defective in the interaction, suggesting (but not proving) that direct or indirect dimerization may be important for the normal functions of pol epsilon. The POL2 C terminus is sufficient for interaction with DPB2, the essential and phylogenetically conserved subunit of pol epsilon, but not for interaction with DPB3. Neither Dpb3p nor Dpb2p homodimerizes in the two-hybrid assay.

Bacteriophage T4 initiates bidirectional DNA replication through a two-step process

Two-dimensional gel analysis of the bacteriophage T4 ori(uvsY) region revealed a novel "comet" on the Y arc. This comet contains simple Y molecules in which the branch points map to the ori(uvsY) transcript region. The comet depends on the the origin and DNA synthesis and is abolished by a mutation that reduces replication without affecting transcription. These results argue that the branched molecules are intermediates in replication initiation. A transcriptional terminator, cloned just downstream of the origin promoter, shortened the tail of the comet. Therefore, the location of the transcript determines the DNA branch points. We conclude that the comet DNA consists of intermediates in which unidirectional replication has been triggered by priming from the RNA of the origin R loop.

ATP binding to the Escherichia coli clamp loader powers opening of the ring-shaped clamp of DNA polymerase III holoenzyme

The Escherichia coli gamma complex serves as a clamp loader, catalyzing ATP-dependent assembly of beta protein clamps onto primed DNA templates during DNA replication. These ring-shaped clamps tether DNA polymerase III holoenzyme to the template, facilitating rapid and processive DNA synthesis. This report focuses on the role of ATP binding and hydrolysis catalyzed by the gamma complex during clamp loading. We show that the energy from ATP binding to gamma complex powers several initial events in the clamp loading pathway. The gamma complex (gamma2 delta delta'chi psi) binds two ATP molecules (one per gamma subunit in the complex) with high affinity (Kd = 1-2. 5 x 10(-6) M) or two adenosine 5'-O-(3-thiotriphosphate)(ATPgammaS) molecules with slightly lower affinity (Kd = 5-6.5 x 10(-6) M). Experiments performed prior to the first ATP turnover (kcat = 4 x 10(-3) s-1 at 4 degreesC), or in the presence of ATPgammaS (kcat = 1 x 10(-4) s-1 at 37 degreesC), demonstrate that upon interaction with ATP the gamma complex undergoes a change in conformation. This ATP-bound gamma complex binds beta and opens the ring at the dimer interface. Still prior to ATP hydrolysis, the composite of gamma complex and the open beta ring binds with high affinity to primer-template DNA. Thus ATP binding powers all the steps in the clamp loading pathway leading up to the assembly of a gamma complex. open beta ring.DNA intermediate, setting the stage for ring closing and turnover of the clamp loader, steps that may be linked to subsequent hydrolysis of ATP.

The structure of supercoiled intermediates in DNA replication

We studied the structure of replication intermediates accumulated by Tus-induced arrest of plasmid DNA replication at termination sites. For intermediates generated both in vitro with purified components and in vivo, superhelical stress is distributed throughout the entire partially replicated molecule; daughter DNA segments are wound around each other, and the unreplicated region is supercoiled. Thus, unlinking of parental DNA strands by topoisomerases can be carried out both behind and in front of the replication fork. We explain why previous studies with prokaryotic and eukaryotic replication intermediates discerned only supercoiling in the unreplicated portion.

The base substitution and frameshift fidelity of Escherichia coli DNA polymerase III holoenzyme in vitro

We have investigated the in vitro fidelity of Escherichia coli DNA polymerase III holoenzyme from a wild-type and a proofreading-impaired mutD5 strain. Exonuclease assays showed the mutD5 holoenzyme to have a 30-50-fold reduced 3'-->5'-exonuclease activity. Fidelity was assayed during gap-filling synthesis across the lacId forward mutational target. The error rate for both enzymes was lowest at low dNTP concentrations (10-50 microM) and highest at high dNTP concentration (1000 microM). The mutD5 proofreading defect increased the error rate by only 3-5-fold. Both enzymes produced a high level of (-1)-frameshift mutations in addition to base substitutions. The base substitutions were mainly C-->T, G-->T, and G-->C, but dNTP pool imbalances suggested that these may reflect misincorporations opposite damaged template bases and that, instead, T-->C, G-->A, and C-->T transitions represent the normal polymerase III-mediated base.base mispairs. The frequent (-1)-frameshift mutations do not result from direct slippage but may be generated via a mechanism involving "misincorporation plus slippage." Measurements of the fidelity of wild-type and mutD5 holoenzyme during M13 in vivo replication revealed significant differences between the in vivo and in vitro fidelity with regard to both the frequency of frameshift errors and the extent of proofreading.

The role of SOS and flap processing in microsatellite instability in Escherichia coli

Mutations affecting mismatch repair result in elevated frequencies of microsatellite length alteration in prokaryotes and eukaryotes. However, the finding that microsatellite instability is found often in cells with a functional mismatch repair system prompted a search for other factors of tract alteration. In the present report, we show that, in Escherichia coli, poly(AC/TG) tracts are destabilized by mutations that induce SOS. These observations may have implications for eukaryotic cells because recent results suggest the existence of a mammalian SOS response analogous to that in prokaryotes. In addition, a defect in the 5'-3' exonuclease domain of DNA polymerase I, homologous to the mammalian FEN1 and the yeast RAD27 nucleases, leads to a marked increase in repeat expansions characteristic of several genetic disorders. Finally, we found that the combination of a proofreading defect with mismatch repair deficiency results in extreme microsatellite instability.

The initiator function of DnaA protein is negatively regulated by the sliding clamp of the E. coli chromosomal replicase

The beta subunit of DNA polymerase III is essential for negative regulation of the initiator protein, DnaA. DnaA inactivation occurs through accelerated hydrolysis of ATP bound to DnaA; the resulting ADP-DnaA fails to initiate replication. The ability of beta subunit to promote DnaA inactivation depends on its assembly as a sliding clamp on DNA and must be accompanied by a partially purified factor, IdaB protein. DnaA inactivation in the presence of IdaB and DNA polymerase III is further stimulated by DNA synthesis, indicating close linkage between initiator inactivation and replication. In vivo, DnaA predominantly takes on the ADP form in a beta subunit-dependent manner. Thus, the initiator is negatively regulated by action of the replicase, a mechanism that may be key to effective control of the replication cycle.

PcrA is an essential DNA helicase of Bacillus subtilis fulfilling functions both in repair and rolling-circle replication

The only DNA helicase essential for Escherichia coli viability is DnaB, the chromosome replication for helicase. In contrast, in Bacillus subtilis, in addition to the DnaB counterpart called DnaC, we have found a second essential DNA helicase, called PcrA. It is 40% identical to the Rep and UvrD DNA helicases of E. coli and 61% identical to the PcrA helicase of Staphylococcus aureus. This gene is located at 55 degree on the chromosome and belongs to a putative operon together with a ligase gene (lig) and two unknown genes named pcrB and yerH. As PcrA was essential for cell viability, conditional mutants were constructed. In such mutants, chromosomal DNA synthesis was slightly decreased upon PcrA depletion, and rolling-circle replication of the plasmid pT181 was inhibited. Analysis of the replication intermediates showed that leading-strand synthesis of pT181 was prevented upon PcrA depletion. To compare PcrA with Rep and UvrD directly, the protein was produced in rep and uvrD mutants of E. coli. PcrA suppressed the UV sensitivity defect at a uvrD mutant but not its mutator phenotype. Furthermore, it conferred a Rep-phenotype on E. coli. Altogether, these results show that PcrA is an helicase used for plasmid rolling-circle replication and suggest that it is also involved in UV repair.

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.

Does single-stranded DNA pass through the inner channel of the protein hexamer in the complex with the Escherichia coli DnaB Helicase? Fluorescence energy transfer studies

The structure of the complex of the Escherichia coli primary replicative helicase DnaB protein with single-stranded (ss) DNA and replication fork substrates has been examined using the fluorescence energy transfer method. In these experiments, we used the DnaB protein variant, R14C, which has arginine 14 replaced by cysteine in the small 12-kDa domain of the protein using site-directed mutagenesis. The cysteine residues have been modified with a fluorescent marker which serves as a donor or an acceptor to another fluorescence label placed in different locations on the DNA substrates. Using the multiple fluorescence donor-acceptor approach, we provide evidence that, in the complex with the enzyme, ssDNA passes through the inner channel of the DnaB hexamer. This is the first evidence of the existence of such a structure of a hexameric helicase-ssDNA complex in solution. In the stationary complex with the 5' arm of the replication fork, without ATP hydrolysis, the distance between the 5' end of the arm and the 12-kDa domains of the hexamer (R = 47 A) is the same as in the complex with the isolated ssDNA oligomer (R = 47 A) having the same length as the arm of the fork. These data indicate that both ssDNA and the 5' arm of the fork bind in the same manner to the DNA binding site. Moreover, in the complex with the helicase, the length of the ssDNA is similar to the length of the ssDNA strand in the double-stranded DNA conformation. In the stationary complex, the helicase does not invade the duplex part of the fork beyond the first 2-3 base pairs. This result corroborates the quantitative thermodynamic data which showed that the duplex part of the fork does not contribute to the free energy of binding of the enzyme to the fork. Implications of these results for the mechanism of a hexameric helicase binding to DNA are discussed.

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.

The phiX174-type primosome promotes replisome assembly at the site of recombination in bacteriophage Mu transposition

Initiation of Escherichia coli DNA synthesis primed by homologous recombination is believed to require the phiX174-type primosome, a mobile priming apparatus assembled without the initiator protein DnaA. We show that this primosome plays an essential role in bacteriophage Mu DNA replication by transposition. Upon promoting transfer of Mu ends to target DNA, the Mu transpososome undergoes transition to a pre-replisome that permits initiation of DNA synthesis only in the presence of primosome assembly proteins PriA, DnaT, DnaB and DnaC. These assembly proteins promote the engagement of primase and DNA polymerase III holoenzyme, initiating semi-discontinuous replication preferentially at the Mu left end. The results indicate that these proteins play a crucial role in promoting replisome assembly on a recombination intermediate.

Functionally interacting telomerase RNAs in the yeast telomerase complex

The ribonucleoprotein (RNP) enzyme telomerase from Saccharomyces cerevisiae adds telomeric DNA to chromosomal ends in short increments both in vivo and in vitro. Whether or not telomerase functions as a multimer has not been addressed previously. Here we show, first, that following polymerization, the telomerase RNP remains stably bound to its telomeric oligonucleotide reaction product. We then exploit this finding and a previously reported mutant telomerase RNA to demonstrate that, unexpectedly, the S. cerevisiae telomerase complex contains at least two functionally interacting RNA molecules that both act as templates for DNA polymerization. Here, functional telomerase contains at least two active sites.

Thermus thermophilis dnaX homolog encoding gamma- and tau-like proteins of the chromosomal replicase

This report identifies the dnaX homolog from Thermus thermophilis. Replicases from bacteria to humans contain subunits that are homologous to one another. These homologs are subunits of a clamp loading apparatus that loads sliding clamps onto DNA, which in turn act as mobile tethers for the replication machinery. In Escherichia coli, two of these subunits (gamma and tau) are encoded by one gene (dnaX) in nearly equal amounts by way of an efficient translational frameshift. The gamma and tau subunits form the central touchpoint that holds together two DNA polymerases with one clamp loading apparatus to form the E. coli chromosomal replicase, DNA polymerase III holoenzyme. The E. coli holoenzyme is an efficient replication machine that simultaneously replicates both strands of duplex DNA. The T. thermophilis dnaX homolog also contains a frameshift signature and produces both tau- and gamma-like proteins. Recombinant T. thermophilis tau- and gamma-like proteins, expressed in E. coli, have an oligomeric state similar to that of their E. coli counterparts and display ATPase activity that is stimulated by DNA. These results imply that T. thermophilis utilizes a DNA polymerase III holoenzyme replication machinery similar to that of E. coli.

A DNA helicase from Schizosaccharomyces pombe stimulated by single-stranded DNA-binding protein at low ATP concentration

A DNA helicase named DNA helicase I was isolated from cell-free extracts of the fission yeast Schizosaccharomyces pombe. Both DNA helicase and single-stranded DNA-dependent ATPase activities copurified with a polypeptide of 95 kDa on an SDS-polyacrylamide gel. The helicase possessed a sedimentation coefficient of 6.0 S and a Stokes radius of 44.8 A determined by glycerol gradient centrifugation and gel filtration analysis, respectively. From these data the native molecular mass was calculated to be 110 kDa, indicating that the active enzyme is a monomer. The DNA-unwinding and ATP hydrolysis activities associated with DNA helicase I have been examined. One notable property of the enzyme was its relatively high rate of ATP turnover (35-50 molecules of ATP hydrolyzed/s/enzyme molecule) that may contribute to its inefficient unwinding activity at low concentrations of ATP (<0.2 mM). Addition of an ATP-regenerating system to the reaction mixture restored the DNA-unwinding activity of the enzyme. S. pombe single-stranded DNA-binding protein (SpSSB, also called SpRPA) stimulated the DNA helicase activity significantly at low levels of ATP (0.025-0.2 mM) even in the absence of an ATP-regenerating system. In contrast, SpRPA had no effect on ATP hydrolysis at any ATP concentration examined. These observations suggest that the stimulation of DNA unwinding by SpRPA is not simply a result of suppression of nonproductive ATP hydrolysis. Rather, the role of SpRPA is to lower the Km for ATP in the unwinding reaction, allowing the helicase to function efficiently at low ATP concentrations.

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.