Interaction of dnaA46 protein with a stimulatory protein in replication from the Escherichia coli chromosomal origin

60 Years of Studies into the Initiation of Chromosome Replication in Bacteria

The Replicon Theory has guided the way experiments into DNA replication have been designed and interpreted for 60 years. As part of the related, explanatory package guiding experiments, it is thought that the timing of the cell cycle depends in some way on a critical mass for initiation, Mi, as licensed by a variety of macromolecules and molecules reflecting the state of the cell. To help in the re-interpretation of this data, we focus mainly on the roles of DnaA, RNA polymerase, SeqA, and ribonucleotide reductase in the context of the "nucleotypic effect".

Defects in ribosome function delay the initiation of chromosome replication in Escherichia coli

The Sra protein is a component of the 30S ribosomal subunit while RimJ is a ribosome-associated protein that plays a role in the maturation of the 30S ribosomal subunit. Here we found that Δsra and ΔrimJ cells showed a delayed initiation of DNA replication, prolonged doubling time, decreased cell size, and decreased amounts of total protein and DnaA per cell compared with these observed for wild-type cells. A temperature sensitivity test demonstrated that absence of the Sra or RimJ protein did not change the temperature sensitivity of the dnaA46, dnaB252, or dnaC2 mutants. Moreover, ectopic expression of Sra reversed the mutant phenotype while cells carrying the pACYC177-rimJ plasmid did not reverse the rimJ mutant phenotype. The results indicate that deletion of sra or rimJ cause defects in ribosomal function and affect the translation process, leading to a decrease in synthesis of proteins including DnaA. Therefore, we conclude that Sra- and RimJ-mediated ribosomal function is required for precise timing of initiation of chromosome replication.

The DnaA Tale

More than 50 years have passed since the presentation of the Replicon Model which states that a positively acting initiator interacts with a specific site on a circular chromosome molecule to initiate DNA replication. Since then, the origin of chromosome replication, oriC, has been determined as a specific region that carries sequences required for binding of positively acting initiator proteins, DnaA-boxes and DnaA proteins, respectively. In this review we will give a historical overview of significant findings which have led to the very detailed knowledge we now possess about the initiation process in bacteria using Escherichia coli as the model organism, but emphasizing that virtually all bacteria have DnaA proteins that interacts with DnaA boxes to initiate chromosome replication. We will discuss the dnaA gene regulation, the special features of the dnaA gene expression, promoter strength, and translation efficiency, as well as, the DnaA protein, its concentration, its binding to DnaA-boxes, and its binding of ATP or ADP. Furthermore, we will discuss the different models for regulation of initiation which have been proposed over the years, with particular emphasis on the Initiator Titration Model.

DnaC, the indispensable companion of DnaB helicase, controls the accessibility of DnaB helicase by primase

Former studies relying on hydrogen/deuterium exchange analysis suggest that DnaC bound to DnaB alters the conformation of the N-terminal domain (NTD) of DnaB to impair the ability of this DNA helicase to interact with primase. Supporting this idea, the work described herein based on biosensor experiments and enzyme-linked immunosorbent assays shows that the DnaB-DnaC complex binds poorly to primase in comparison with DnaB alone. Using a structural model of DnaB complexed with the C-terminal domain of primase, we found that Ile-85 is located at the interface in the NTD of DnaB that contacts primase. An alanine substitution for Ile-85 specifically interfered with this interaction and impeded DnaB function in DNA replication, but not its activity as a DNA helicase or its ability to bind to ssDNA. By comparison, substitutions of Asn for Ile-136 (I136N) and Thr for Ile-142 (I142T) in a subdomain previously named the helical hairpin in the NTD of DnaB altered the conformation of the helical hairpin and/or compromised its pairwise arrangement with the companion subdomain in each brace of protomers of the DnaB hexamer. In contrast with the I85A mutant, the latter were defective in DNA replication due to impaired binding to both ssDNA and primase. In view of these findings, we propose that DnaC controls the ability of DnaB to interact with primase by modifying the conformation of the NTD of DnaB.

DnaC traps DnaB as an open ring and remodels the domain that binds primase

Helicase loading at a DNA replication origin often requires the dynamic interactions between the DNA helicase and an accessory protein. In E. coli, the DNA helicase is DnaB and DnaC is its loading partner. We used the method of hydrogen/deuterium exchange mass spectrometry to address the importance of DnaB–DnaC complex formation as a prerequisite for helicase loading. Our results show that the DnaB ring opens and closes, and that specific amino acids near the N-terminus of DnaC interact with a site in DnaB's C-terminal domain to trap it as an open ring. This event correlates with conformational changes of the RecA fold of DnaB that is involved in nucleotide binding, and of the AAA+ domain of DnaC. DnaC also causes an alteration of the helical hairpins in the N-terminal domain of DnaB, presumably occluding this region from interacting with primase. Hence, DnaC controls the access of DnaB by primase.

Mutant DnaAs of Escherichia coli that are refractory to negative control

DnaA is the initiator of DNA replication in bacteria. A mutant DnaA named DnaAcos is unusual because it is refractory to negative regulation. We developed a genetic method to isolate other mutant DnaAs that circumvent regulation to extend our understanding of mechanisms that control replication initiation. Like DnaAcos, one mutant bearing a tyrosine substitution for histidine 202 (H202Y) withstands the regulation exerted by datA, hda and dnaN (β clamp), and both DnaAcos and H202Y resist inhibition by the Hda-β clamp complex in vitro. Other mutant DnaAs carrying G79D, E244K, V303M or E445K substitutions are either only partially sensitive or refractory to inhibition by the Hda-β clamp complex in vitro but are responsive to hda expression in vivo. All mutant DnaAs remain able to interact directly with Hda. Of interest, both DnaAcos and DnaAE244K bind more avidly to Hda. These mutants, by sequestrating Hda, may limit its availability to regulate other DnaA molecules, which remain active to induce extra rounds of DNA replication. Other evidence suggests that a mutant bearing a V292M substitution hyperinitiates by escaping the effect of an unknown regulatory factor. Together, our results provide new insight into the mechanisms that regulate replication initiation in Escherichia coli.

Two forms of ribosomal protein L2 of Escherichia coli that inhibit DnaA in DNA replication

We purified an inhibitor of oriC plasmid replication and determined that it is a truncated form of ribosomal protein L2 evidently lacking 59 amino acid residues from the C-terminal region encoded by rplB. We show that this truncated form of L2 or mature L2 physically interacts with the N-terminal region of DnaA to inhibit initiation from oriC by apparently interfering with DnaA oligomer formation, and the subsequent assembly of the prepriming complex on an oriC plasmid. Both forms of L2 also inhibit the unwinding of oriC by DnaA. These in vitro results raise the possibility that one or both forms of L2 modulate DnaA function in vivo to regulate the frequency of initiation.

Synchronous replication initiation in novel Mycobacterium tuberculosis dnaA cold-sensitive mutants

The genetic aspects of oriC replication initiation in Mycobacterium tuberculosis are largely unknown. A two-step genetic screen was utilized for isolating M. tuberculosis dnaA cold-sensitive (cos) mutants. First, a resident plasmid expressing functional dnaA integrated at the attB locus in dnaA null background was exchanged with an incoming plasmid bearing a mutagenized dnaA gene. Next, the mutants that were defective for growth at 30 degrees C, a non-permissive temperature, but resumed growth and DNA synthesis when shifted to 37 degrees C, a permissive temperature, were subsequently selected. Nucleotide sequencing analysis located mutations to different regions of the dnaA gene. Modulation of the growth temperatures led to synchronized DNA synthesis. The dnaA expression under synchronized DNA replication conditions continued to increase during the replication period, but decreased thereafter reflecting autoregulation. The dnaAcos mutants at 30 degrees C were elongated suggesting that they may possibly be blocked during the cell division. The DnaA115 protein is defective in its ability to interact with ATP at 30 degrees C, but not at 37 degrees C. Our results suggest that the optimal cell cycle progression and replication initiation in M. tuberculosis requires that the dnaA promoter remains active during the replication period and that the DnaA protein is able to interact with ATP.

Escherichia coli Dps interacts with DnaA protein to impede initiation: a model of adaptive mutation

During exponential growth, the level of Dps transiently increases in response to oxidative stress to sequester and oxidize Fe2+, which would otherwise lead to hydroxyl radicals that damage the bacterial chromosome. We report that Dps specifically interacts with DnaA protein by affinity chromatography and a solid phase binding assay, requiring the N-terminal region of DnaA to interact. In vitro, Dps inhibits DnaA function in initiation by interfering with strand opening of the replication origin. Comparing isogenic dps+ and dps::kan strains by flow cytometry and by quantitative polymerase chain reaction assays at either the chromosomally encoded level, or at an elevated level encoded by an inducible plasmid, we show that Dps causes less frequent initiations. Results from genetic experiments support this conclusion. We suggest that Dps acts as a checkpoint during oxidative stress to reduce initiations, providing an opportunity for mechanisms to repair oxidative DNA damage. Because Dps does not block initiations absolutely, duplication of the damaged DNA is expected to increase the genetic variation of a population, and the probability that genetic adaptation leads to survival under conditions of oxidative stress.

Escherichia coli DnaA interacts with HU in initiation at the E. coli replication origin

Escherichia coli HU protein is a dimer encoded by two closely related genes whose expression is growth phase-dependent. As a major component of the bacterial nucleoid, HU binds to DNA non-specifically, but acts at the chromosomal origin (oriC) during initiation by stimulating strand opening in vitro. We show that the alpha dimer of HU is more active than other forms of HU in initiation of an oriC-containing plasmid because it more effectively promotes strand opening of oriC. Other results demonstrate that HU stabilizes the DnaA oligomer bound to oriC, and that the alpha subunit of HU interacts with the N-terminal region of DnaA. These observations support a model whereby DnaA interacts with the alpha dimer or the alphabeta heterodimer, depending on their cellular abundance, to recruit the respective form of HU to oriC. The greater activity of the alpha dimer of HU at oriC may stimulate initiation during early log phase compared with the lesser activity of the alphabeta heterodimer or the beta dimer.

Initiation of heat-induced replication requires DnaA and the L-13-mer of oriC

An upshift of 10 degrees C or more in the growth temperature of an Escherichia coli culture causes induction of extra rounds of chromosome replication. This stress replication initiates at oriC but has functional requirements different from those of cyclic replication. We named this phenomenon heat-induced replication (HIR). Analysis of HIR in bacterial strains that had complete or partial oriC deletions and were suppressed by F integration showed that no sequence outside oriC is used for HIR. Analysis of a number of oriC mutants showed that deletion of the L-13-mer, which makes oriC inactive for cyclic replication, was the only mutation studied that inactivated HIR. The requirement for this sequence was strictly correlated with Benham's theoretical stress-induced DNA duplex destabilization. oriC mutations at DnaA, FIS, or IHF binding sites showed normal HIR activation, but DnaA was required for HIR. We suggest that strand opening for HIR initiation occurs due to heat-induced destabilization of the L-13-mer, and the stable oligomeric DnaA-single-stranded oriC complex might be required only to load the replicative helicase DnaB.

An essential tryptophan of Escherichia coli DnaA protein functions in oligomerization at the E. coli replication origin

In the initiation of bacterial DNA replication, DnaA protein recruits DnaB helicase to the chromosomal origin, oriC, leading to the assemble of the replication fork machinery at this site. Because a region near the N terminus of DnaA is required for self-oligomerization and the loading of DnaB helicase at oriC, we asked if these functions are separable or interdependent by substituting many conserved amino acids in this region with alanine to identify essential residues. We show that alanine substitutions of leucine 3, phenylalanine 46, and leucine 62 do not affect DnaA function in initiation. In contrast, we find on characterization of a mutant DnaA that tryptophan 6 is essential for DnaA function because its substitution by alanine abrogates self-oligomerization, resulting in the failure to load DnaB at oriC. These results indicate that DnaA bound to oriC forms a specific oligomeric structure, which is required to load DnaB helicase.

New non-detrimental DNA-binding mutants of the Escherichia coli initiator protein DnaA

The initiator protein DnaA has several unique DNA-binding features. It binds with high affinity as a monomer to the nonamer DnaA box. In the ATP form, DnaA binds cooperatively to the low-affinity ATP-DnaA boxes, and to single-stranded DNA in the 13mer region of the origin. We have carried out an extensive mutational analysis of the DNA-binding domain of the Escherichia coli DnaA protein using mutagenic PCR. We analyzed mutants exhibiting more or less partial activity by selecting for complementation of a dnaA(Ts) mutant strain at different expression levels of the new mutant proteins. The selection gave rise to 30 single amino acid substitutions and, including double substitutions, more than 100 mutants functional in initiation of chromosome replication were characterized. The analysis indicated that all regions of the DNA-binding domain are involved in DNA binding, but the most important amino acid residues are located between positions 30 and 80 of the 94 residue domain. Residues where substitutions with non-closely related amino acids have very little effect on protein function are located primarily on the periphery of the 3D structure. By comparison of the effect of substitutions on the activity for initiation of replication with the activity for repression of the mioC promoter, we identified residues that might be involved specifically in the cooperative interaction with ATP-DnaA boxes.

The box VII motif of Escherichia coli DnaA protein is required for DnaA oligomerization at the E. coli replication origin

Escherichia coli DnaA protein initiates DNA replication from the chromosomal origin, oriC, and regulates the frequency of this process. Structure-function studies indicate that the replication initiator comprises four domains. Based on the structural similarity of Aquifex aeolicus DnaA to other AAA+ proteins that are oligomeric, it was proposed that Domain III functions in oligomerization at oriC (Erzberger, J. P., Pirruccello, M. M., and Berger, J. M. (2002) EMBO J. 21, 4763-4773). Because the Box VII motif within Domain III is conserved among DnaA homologues and may function in oligomerization, we substituted conserved Box VII amino acids of E. coli DnaA with alanine by site-directed mutagenesis to examine the role of this motif. All mutant proteins are inactive in initiation from oriC in vivo and in vitro, but they support RK2 plasmid DNA replication in vivo. Thus, RK2 requires only a subset of DnaA functions for plasmid DNA replication. Biochemical studies on a mutant DnaA carrying an alanine substitution at arginine 281 (R281A) in Box VII show that it is inactive in in vitro replication of an oriC plasmid, but this defect is not from the failure to bind to ATP, DnaB in the DnaB-DnaC complex, or oriC. Because the mutant DnaA is also active in the strand opening of oriC, whereas DnaB fails to bind to this unwound region, the open structure is insufficient by itself to load DnaB helicase. Our results show that the mutant fails to form a stable oligomeric DnaA-oriC complex, which is required for the loading of DnaB.

Eclipse–Synchrony Relationship in Escherichia coli Strains with Mutations Affecting Sequestration, Initiation of Replication and Superhelicity of the Bacterial Chromosome

Initiation of replication from oriC on the Escherichia coli chromosomes occurs once and only once per generation at the same cell mass per origin. During rapid growth there are overlapping replication cycles, and initiation occurs synchronously at two or more copies of oriC. Since the bacterial growth can vary over a wide range (from three divisions per hour to 2.5 hours or more per division) the frequency of initiation should change in coordination with bacterial growth. Prevention of reinitiation from a newly replicated origin by temporary sequestration of the hemi-methylated GATC-sites in the origin region provides the molecular/genetic basis for the maintenance of the eclipse period between two successive rounds of replication. Sequestration is also believed to be responsible for initiation synchrony, since inactivation of either the seqA or the dam gene abolishes synchrony while drastically reducing the eclipse. In this work, we attempted to examine the functional relationship(s) between the eclipse period and the synchrony of initiation in E.coli strains by direct measurements of these parameters by density-shift centrifugation and flow-cytometric analyses, respectively. The eclipse period, measured as a fraction of DNA-duplication times, varied continuously from 0.6 for the wild-type E.coli K12 to 0.1 for strains with mutations in seqA, dam, dnaA, topA and gyr genes (all of which have been shown to cause asynchrony) and their various combinations. The asynchrony index, a quantitative indicator for the loss of synchrony of initiation, changed from low (synchronous) to high (asynchronous) values in a step-function-like relationship with the eclipse. An eclipse period of approximately 0.5 generation time appeared to be the critical value for the switch from synchronous to asynchronous initiation.

Eclipse period without sequestration in Escherichia coli

The classical Meselson-Stahl density shift experiment was used to determine the length of the eclipse period in Escherichia coli, the minimum time period during which no new initiation is allowed from a newly replicated origin of chromosome replication, oriC. Populations of bacteria growing exponentially in heavy ((15)NH(4)+ and (13)C(6)-glucose) medium were shifted to light ((14)NH(4)+ and (12)C(6)-glucose) medium. The HH-, HL- and LL-DNA were separated by CsCl density gradient centrifugation, and their relative amounts were determined using radioactive gene-specific probes. The eclipse period, estimated from the kinetics of conversion of HH-DNA to HL- and LL-DNA, turned out to be 0.60 generation times for the wild-type strain. This was invariable for widely varying doubling times (35, 68 and 112 min) and was independent of the chromosome locus at which the eclipse period was measured. For strains with seqA, dam and damseqA mutants, the length of the eclipse period was 0.16, 0.40 and 0.32 generation times respectively. Thus, initiations from oriC were repressed for a considerable proportion of the generation time even when the sequestration function seemed to be severely compromised. The causal relationship between the length of the eclipse period and the synchrony of initiations from oriC is discussed.

Essential amino acids of Escherichia coli DnaC protein in an N-terminal domain interact with DnaB helicase

Escherichia coli DnaC protein bound to ATP forms a complex with DnaB protein. To identify the domain of DnaC that interacts with DnaB, a genetic selection was used based on the lethal effect of induced dnaC expression and a model that inviability arises by the binding of DnaC to DnaB to inhibit replication fork movement. The analysis of dnaC alleles that preserved viability under elevated expression revealed an N-terminal domain of DnaC involved in binding to DnaB. Mutant proteins bearing single amino acid substitutions (R10P, L11Q, L29Q, S41P, W32G, and L44P) that reside in regions of predicted secondary structure were inert in DNA replication activity because of their inability to bind to DnaB, but they retained ATP binding activity, as indicated by UV cross-linking to [alpha-(32)P]ATP. These alleles also failed to complement a dnaC28 mutant. Other selected mutations that map to regions carrying Walker A and B boxes are expected to be defective in ATP binding, a required step in DnaB-DnaC complex formation. Lastly, we found that the sixth codon from the N terminus encodes aspartate, resolving a reported discrepancy between the predicted amino acid sequence based on DNA sequencing data and the results from N-terminal amino acid sequencing (Nakayama, N., Bond, M. W., Miyajima, A., Kobori, J., and Arai, K. (1987) J. Biol. Chem. 262, 10475-10480).

The Escherichia coli SeqA protein destabilizes mutant DnaA204 protein

In wild-type Escherichia coli cells, initiation of DNA replication is tightly coupled to cell growth. In slowly growing dnaA204 (Ts) mutant cells, the cell mass at initiation and its variability is increased two- to threefold relative to wild type. Here, we show that the DnaA protein concentration was two- to threefold lower in the dnaA204 mutant compared with the wild-type strain. The reason for the DnaA protein deficiency was found to be a rapid degradation of the mutant protein. Absence of SeqA protein stabilized the DnaA204 protein, increased the DnaA protein concentration and normalized the initiation mass in the dnaA204 mutant cells. During rapid growth, the dnaA204 mutant displayed cell cycle parameters similar to wild-type cells as well as a normal DnaA protein concentration, even though the DnaA204 protein was highly unstable. Apparently, the increased DnaA protein synthesis compensated for the protein degradation under these growth conditions, in which the doubling time was of the same order of magnitude as the half-life of the protein. Our results suggest that the DnaA204 protein has essentially wild-type activity at permissive temperature but, as a result of instability, the protein is present at lower concentration under certain growth conditions. The basis for the stabilization in the absence of SeqA is not known. We suggest that the formation of stable DnaA-DNA complexes is enhanced in the absence of SeqA, thereby protecting the DnaA protein from degradation.

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.

Two types of cold sensitivity associated with the A184-->V change in the DnaA protein

Multicopy dnaA(Ts) strains carrying the dnaA5 or dnaA46 allele are high-temperature resistant but are cold sensitive for colony formation. The DnaA5 and DnaA46 proteins both have an A184-->V change in the ATP binding motif of the protein, but they also have one additional mutation. The mutations were separated, and it was found that a plasmid carrying exclusively the A184-->V mutation conferred a phenotype virtually identical to that of the dnaA5 plasmid. Strains carrying plasmids with either of the additional mutations behaved like a strain carrying the dnaA+ plasmid. In temperature downshifts from 42 degrees C to 30 degrees C, chromosome replication was stimulated in the multicopy dnaA46 strain. The DNA per mass ratio increased threefold, and exponential growth was maintained for more than four mass doublings. Strains carrying plasmids with the dnaA(A184-->V) or the dnaA5 gene behaved differently. The temperature downshift resulted in run out of DNA synthesis and the strains eventually ceased growth. The arrest of DNA synthesis was not due to the inability to initiate chromosome replication because marker frequency analysis showed high initiation activity after temperature downshift. However, the marker frequencies indicated that most, if not all, of the newly initiated replication forks were stalled soon after the onset of chromosome replication. Thus, it appears that the multicopy dnaA(A184-->V) strains are cold sensitive because of an inability to elongate replication at low temperature. The multicopy dnaA46 strains, on the contrary, exhibit productive initiation and normal fork movement. In this case, the cold-sensitive phenotype may be due to DNA overproduction.

Interaction of SeqA and Dam methylase on the hemimethylated origin of Escherichia coli chromosomal DNA replication

Preferential binding of SeqA protein to hemimethylated oriC, the origin of Escherichia coli chromosomal replication, delays methylation by Dam methylase. Because the SeqA-oriC interaction appears to be essential in timing of chromosomal replication initiation, the biochemical functions of SeqA protein and Dam methylase at the 13-mer L, M, and R region containing 4 GATC sequences at the left end of oriC were examined. We found that SeqA protein preferentially bound hemimethylated 13-mers but not fully nor unmethylated 13-mers. Regardless of strand methylation, the binding of SeqA protein to the hemimethylated GATC sequence of 13-mer L was followed by additional binding to other hemimethylated GATC sequences of 13-mer M and R. On the other hand, Dam methylase did not discriminate binding of 13-mers in different methylation patterns and was not specific to GATC sequences. The binding specificity and higher affinity of SeqA protein over Dam methylase to the hemimethylated 13-mers along with the reported cellular abundance of this protein explains the dominant action of SeqA protein over Dam methylase to the newly replicated oriC for the sequestration of chromosomal replication. Furthermore, SeqA protein bound to hemimethylated 13-mers was not dissociated by Dam methylase, and most SeqA protein spontaneously dissociated 10 min after binding. Also, SeqA protein delayed the in vitro methylation of hemimethylated 13-mers by Dam methylase. These in vitro results suggest that the intrinsic binding instability of SeqA protein results in release of sequestrated hemimethylated oriC.

Escherichia coli DnaA protein. The N-terminal domain and loading of DnaB helicase at the E. coli chromosomal origin

Initiation of DNA replication at the Escherichia coli chromosomal origin occurs through an ordered series of events that depends first on the binding of DnaA protein, the replication initiator, to DnaA box sequences followed by unwinding of an AT-rich region. A step that follows is the binding of DnaB helicase at oriC so that it is properly positioned at each replication fork. We show that DnaA protein actively mediates the entry of DnaB at oriC. One region (amino acids 111-148) transiently binds to DnaB as determined by surface plasmon resonance. A second functional domain, possibly involving formation of a unique nucleoprotein structure, promotes the stable binding of DnaB during the initiation process and is inactivated in forming an intermediate termed the prepriming complex by removal of the N-terminal 62 residues. Based on similarities in the replication process between prokaryotes and eukaryotes, these results suggest that a similar mechanism may load the eukaryotic replicative helicase.

The FIS protein fails to block the binding of DnaA protein to oriC, the Escherichia coli chromosomal origin

The Escherichia coli chromosomal origin contains several bindings sites for factor for inversion stimulation (FIS), a protein originally identified to be required for DNA inversion by the Hin and Gin recombinases. The primary FIS binding site is close to two central DnaA boxes that are bound by DnaA protein to initiate chromosomal replication. Because of the close proximity of this FIS site to the two DnaA boxes, we performed in situ footprinting with 1, 10-phenanthroline-copper of complexes formed with FIS and DnaA protein that were separated by native gel electrophoresis. These studies show that the binding of FIS to the primary FIS site did not block the binding of DnaA protein to DnaA boxes R2 and R3. Also, FIS appeared to be bound more stably to oriC than DnaA protein, as deduced by its reduced rate of dissociation from a restriction fragment containing oriC . Under conditions in which FIS was stably bound to the primary FIS site, it did not inhibit oriC plasmid replication in reconstituted replication systems. Inhibition, observed only at high levels of FIS, was due to absorption by FIS binding of the negative superhelicity of the oriC plasmid that is essential for the initiation process.

Site-directed mutational analysis for the membrane binding of DnaA protein. Identification of amino acids involved in the functional interaction between DnaA protein and acidic phospholipids

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli, interacts with acidic phospholipids, such as cardiolipin, and its activity seems to be regulated by membrane binding in cells. In this study we introduced site-directed mutations at the positions of hydrophobic or basic amino acids which are conserved among various bacteria species and which are located in the putative membrane-binding region of DnaA protein (from Asp357 to Val374). All mutant DnaA proteins showed much the same ATP and ADP binding activity as that of the wild-type protein. The release of ATP bound to the mutant DnaA protein, in which three hydrophobic amino acids were mutated to hydrophilic ones, was stimulated by cardiolipin, as in the case of the wild-type protein. On the other hand, the release of ATP bound to another mutant DnaA protein, in which three basic amino acids were mutated to acidic ones, was not stimulated by cardiolipin. These results suggest not only that the region is a membrane-binding domain of DnaA protein but also that these basic amino acids are important for the binding and the ionic interaction between the basic amino acids and acidic residues of cardiolipin and is involved in the interaction between DnaA protein and cardiolipin.

The central lysine in the P-loop motif of the Escherichia coli DnaA protein is essential for initiating DNA replication from the chromosomal origin, oriC, and the F factor origin, oriS, but is dispensable for initiation from the P1 plasmid origin, oriR

The Escherichia coli DnaA protein is essential for initiation of DNA replication from the chromosomal origin, oriC, and from certain plasmid origins such as oriR of P1, oriS of F, and ori of pSCS101. The DnaA protein binds ATP with high affinity and contains a P-loop motif assumed to be the binding site. Three mutations in the E. coli dnaA gene were constructed by oligonucleotide-directed mutagenesis that changed amino acids in the P-loop. A DnaA protein, K178T, in which the central lysine was changed to the smaller amino acid threonine, was able to initiate DNA replication from P1 oriR, but was unable to initiate replication from E. coli oriC or F oriS in vivo. Mutant and wild-type DnaA proteins were overexpressed, partially purified, and tested for replication activity in vitro. The K178T DnaA protein could initiate replication from oriR, although with a decreased activity compared to the wild-type DnaA protein. No replication activity was detected for this mutant protein from oriC. The different responses of the oriR and oriC replicons to the K178T DnaA protein indicate that the role of DnaA is different in the two systems.

Site-directed mutational analysis for the ATP binding of DnaA protein. Functions of two conserved amino acids (Lys-178 and Asp-235) located in the ATP-binding domain of DnaA protein in vitro and in vivo

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli, is activated by binding to ATP in vitro. We introduced site-directed mutations into two amino acids of the protein conserved among various ATP-binding proteins and examined functions of the mutated DnaA proteins, in vitro and in vivo. Both mutated DnaA proteins (Lys-178 --> Ile or Asp-235 --> Asn) lost the affinity for both ATP and ADP but did maintain binding activity for oriC. Specific activities in an oriC DNA replication system in vitro were less than one-tenth those of the wild-type protein. Assay of the generation of oriC sites sensitive to P1 nuclease, using the mutated DnaA proteins, revealed a defect in induction of the duplex opening at oriC. On the other hand, expression of each mutated DnaA protein in the temperature-sensitive dnaA46 mutant did not complement the temperature sensitivity. We suggest that Lys-178 and Asp-235 of DnaA protein are essential for the activity needed to initiate oriC DNA replication in vitro and in vivo and that ATP binding to DnaA protein is required for DNA replication-related functions.

The Escherichia coli dnaA gene: four functional domains

The Escherichia coli DnaA protein is a sequence-specific DNA binding protein that promotes the initiation of replication of the bacterial chromosome, and of several plasmids including pSC101. Twenty-eight novel missense mutations of the E. coli dnaA gene were isolated by selecting for their inability to replicate a derivative of pSC101 when contained in a lambda vector. Characterization of these as well as seven novel nonsense mutations and one in-frame deletion mutation are described here. Results suggest that E. coli DnaA protein contains four functional domains. Mutations that affect residues in the P-loop or Walker A motif thought to be involved in ATP binding identify one domain. The second domain maps to a region near the C terminus and is involved in DNA binding. The function of the third domain that maps near the N terminus is unknown but may be involved in the ability of DnaA protein to oligomerize. Two alleles encoding different truncated gene products retained the ability to promote replication from the pSC101 origin but not oriC, identifying a fourth domain dispensable for replication of pSC101 but essential for replication from the bacterial chromosomal origin, oriC.

Domains of DnaA protein involved in interaction with DnaB protein, and in unwinding the Escherichia coli chromosomal origin

DnaA protein of Escherichia coli is a sequence-specific DNA-binding protein required for the initiation of DNA replication from the chromosomal origin, oriC. It is also required for replication of several plasmids including pSC101, F, P-1, and R6K. A collection of monoclonal antibodies to DnaA protein has been produced and the primary epitopes recognized by them have been determined. These antibodies have also been examined for the ability to inhibit activities of DNA binding, ATP binding, unwinding of oriC, and replication of both an oriC plasmid, and an M13 single-stranded DNA with a proposed hairpin structure containing a DnaA protein-binding site. Replication of the latter DNA is dependent on DnaA protein by a mechanism termed ABC priming. These studies suggest regions of DnaA protein involved in interaction with DnaB protein, and in unwinding of oriC, or low-affinity binding of ATP.

The A184V missense mutation of the dnaA5 and dnaA46 alleles confers a defect in ATP binding and thermolability in initiation of Escherichia coli DNA replication

The temperature-sensitive dnaA5 and dnaA46 alleles each contain two missense mutations. These mutations have been separated and the resulting mutant proteins studied with regard to their role in initiation of DNA replication in vitro. Whereas the His-252 to tyrosine substitution (H252Y) unique to the dnaA46 allele did not affect the activities of DnaA protein, the unique substitution of the dnaA5 allele, Gly-426 to serine (G426S), was reduced in its DNA-binding affinity for oriC, the chromosomal origin. This suggests that the C-terminal region of the DnaA protein is involved in DNA binding. The alanine-to-valine substitution at amino acid 184 (A184V) that is common to both of the alleles is responsible for the thermolabile defect and lag in DNA synthesis of these mutants. Mutant proteins bearing the common substitution were defective in ATP binding and were inactive in a replication system reconstituted with purified proteins. DnaK and GrpE protein activated these mutant proteins for replication and ATP binding; the latter was measured indirectly by the ATP-dependent formation of a trypsin-resistant peptide. However, with this assay, the ATP-binding affinity appeared to be reduced relative to wild-type DnaA protein. Activation was by conversion of a self-aggregate to the monomer, and also by a conformational alteration that correlated with ATP binding.

SeqA limits DnaA activity in replication from oriC in Escherichia coli

A mutant Escherichia coli that transforms minichromosomes with high efficiency in the absence of Dam methylation has been isolated and the mutation mapped to 16.25 min on the E. coli map. The mutant strain containing seqA2 is defective for growth in rich medium but not in minimal medium. A similar mutation in this gene, named seqA1, has also been isolated. Here we show that the product of the seqA gene, SeqA, normally acts as an inhibitor of chromosomal initiation. In the seqA2-containing mutant, the frequency of initiation increases by a factor of three. Introduction of the wild-type seqA gene on a low-copy plasmid suppresses the cold sensitivity of a dnaAcos mutant known to overinitiate at temperatures below 39 degrees C. In addition, the seqA2 mutation is a suppressor of several dnaA (Ts) alleles. The seqA2 mutant overinitiates replication from oriC and displays the asynchronous initiation phenotype. Also the seqA2 mutant has an elevated level of DnaA protein (twofold). The introduction of minichromosomes or a low-copy-number plasmid carrying five DnaA-boxes from the oriC region increases the growth rate of the seqA2 mutant in rich medium to the wild-type level, reduces overinitiation but does not restore synchrony. We propose that the role of SeqA is to limit the activity level of the E. coli regulator of chromosome initiation, DnaA.

Physiological consequences of DnaK and DnaJ overproduction in Escherichia coli

The physiological consequences of molecular chaperone overproduction in Escherichia coli are presented. Constitutive overproduction of DnaK from a multicopy plasmid containing large chromosomal fragments spanning the dnaK region resulted in plasmid instability. Co-overproduction of DnaJ with DnaK stabilized plasmid levels. To examine the effects of altered levels of DnaK and DnaJ in a more specific manner, an inducible expression system for dnaK and dnaJ was constructed and characterized. Differential rates of DnaK synthesis were determined by quantitative Western blot (immunoblot) analysis. Moderate levels of DnaK overproduction resulted in a defect in cell septation and formation of cell filaments, but co-overproduction of DnaJ overcame this effect. Further increases in the level of DnaK terminated culture growth despite increased levels of DnaJ. DnaK overproduction was found to be bacteriocidal, and this effect was also partially suppressed by DnaJ. The bacteriocidal effect was apparent only with cultures which were allowed to enter stationary phase, indicating that DnaK toxicity is growth phase dependent.

Cloning and nucleotide sequence determination of twelve mutant dnaA genes of Escherichia coli

Plasmids carrying different regions of the wild-type dnaA gene were used for marker rescue analysis of the temperature sensitivity of twelve strains carrying dnaA mutations. The different dnaA(Ts) mutations could be unambiguously located within specific regions of the dnaA gene. The mutant dnaA genes were cloned on pBR322-derived plasmids and on nucleotide sequencing by dideoxy chain termination the respective mutations were determined using M13 clones carrying the relevant parts of the mutant dnaA gene. Several of the mutant dnaA genes were found to have two mutations. The dnaA5, dnaA46, dnaA601, dnaA602, dnaA604, and dnaA606 genes all had identical mutations corresponding to an amino acid change from alanine to valine at amino acid 184 in the DnaA protein, close to the proposed ATP binding site, but all carried one further mutation giving rise to an amino acid substitution. The dnaA508 gene also had two mutations, whereas dnaA167, dnaA203, dnaA204, dnaA205, and dnaA211 each had only one. The pairs dnaA601/602, dnaA604/606, and dnaA203/204 were each found to have identical mutations. Plasmids carrying the different dnaA mutant genes intact were introduced into the respective dnaA mutant strains. Surprisingly, these homopolyploid mutant strains were found to be temperature resistant in most cases, indicating that a high intracellular concentration of the mutant DnaA protein can compensate for the decreased activity of the protein.