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.     

Hda inactivation of DnaA is the predominant mechanism preventing hyperinitiation of Escherichia coli DNA replication

Initiation of DNA replication from the Escherichia coli chromosomal origin is highly regulated, assuring that replication occurs precisely once per cell cycle. Three mechanisms for regulation of replication initiation have been proposed: titration of free DnaA initiator protein by the datA locus, sequestration of newly replicated origins by SeqA protein and regulatory inactivation of DnaA (RIDA), in which active ATP-DnaA is converted to the inactive ADP-bound form. DNA microarray analyses showed that the level of initiation in rapidly growing cells that lack datA was indistinguishable from that in wild-type cells, and that the absence of SeqA protein caused only a modest increase in initiation, in agreement with flow-cytometry data. In contrast, cells lacking Hda overinitiated replication twofold, implicating RIDA as the predominant mechanism preventing extra initiation events in a cell cycle.     

The datA locus predominantly contributes to the initiator titration mechanism in the control of replication initiation in Escherichia coli

Replication of the Escherichia coli chromosome is initiated synchronously from all origins (oriC) present in a cell at a fixed time in the cell cycle under given steady state culture conditions. A mechanism to ensure the cyclic initiation events operates through the chromosomal site, datA, which titrates exceptionally large amounts of the bacterial initiator protein, DnaA, to prevent overinitiation. Deletion of the datA locus results in extra initiations and altered temporal control of replication. There are many other sites on the E. coli chromosome that can bind DnaA protein, but the contribution of these sites to the control of replication initiation has not been investigated. In the present study, seven major DnaA binding sites other than datA have been examined for their influence on the timing of replication initiation. Disruption of these seven major binding sites, either individually or together, had no effect on the timing of initiation of replication. Thus, datA seems to be a unique site that adjusts the balance between free and bound DnaA to ensure that there is only a single initiation event in each bacterial cell cycle. Mutation either in the second or the third DnaA box (a 9 basepair DnaA-binding sequence) in datA was enough to induce asynchronous and extra initiations of replication to a similar extent as that observed with the datA-deleted strain. These DnaA boxes may act as cores for the cooperative binding of DnaA to the entire datA region.     

An isolated Hda-clamp complex is functional in the regulatory inactivation of DnaA and DNA replication

In Escherichia coli, a complex consisting of Hda and the DNA-loaded clamp-subunit of the DNA polymerase III holoenzyme promotes hydrolysis of DnaA-ATP. The resultant ADP-DnaA is inactive for initiation of chromosomal DNA replication, thereby repressing excessive initiations. As the cellular content of the clamp is 10-100 times higher than that of Hda, most Hda molecules might be complexed with the clamp in vivo. Although Hda predominantly forms irregular aggregates when overexpressed, in the present study we found that co-overexpression of the clamp with Hda enhances Hda solubility dramatically and we efficiently isolated the Hda-clamp complex. A single molecule of the complex appears to consist of two Hda molecules and a single clamp. The complex is competent in DnaA-ATP hydrolysis and DNA replication in the presence of DNA and the clamp deficient subassembly of the DNA polymerase III holoenzyme (pol III*). These findings indicate that the clamp contained in the complex is loaded onto DNA through an interaction with the pol III* and that the Hda activity is preserved in these processes. The complex consisting of Hda and the DNA-unloaded clamp may play a specific role in a process proceeding to the DnaA-ATP hydrolysis in vivo.     

Regulation of chromosomal replication by DnaA protein availability in Escherichia coli: effects of the datA region.

Initiation of chromosomal replication in Escherichia coli is dependent on availability of the initiator protein DnaA. We have introduced into E. coli cells plasmids carrying the chromosomal locus datA, which has a high affinity for DnaA. To be able to monitor oriC initiation as a function of datA copy number, we introduced a minichromosome which only replicates from oriC, using a host cell which replicates its chromosome independently of oriC. Our data show that a moderate increase in datA copy number is accompanied by increased DnaA protein synthesis that allows oriC initiation to occur normally, as measured by minichromosome copy number. As datA gene dosage is increased dnaA expression cannot be further derepressed, and the minichromosome copy number is dramatically reduced. Under these conditions the minichromosome was maintained by integration into the chromosome. These findings suggest that the datA locus plays a significant role in regulating oriC initiation, by its capacity to bind DnaA. They also suggest that auto regulation of the dnaA gene is of minor importance in regulation of chromosome initiation.     

Replication cycle-coordinated change of the adenine nucleotide-bound forms of DnaA protein in Escherichia coli

The ATP-bound but not the ADP-bound form of DnaA protein is active for replication initiation at the Escherichia coli chromosomal origin. The hydrolysis of ATP bound to DnaA is accelerated by the sliding clamp of DNA polymerase III loaded on DNA. Using a culture of randomly dividing cells, we now have evidence that the cellular level of ATP-DnaA is repressed to only approximately 20% of the total DnaA molecules, in a manner depending on DNA replication. In a synchronized culture, the ATP-DnaA level showed oscillation that has a temporal increase around the time of initiation, and decreases rapidly after initiation. Production of ATP-DnaA depended on concomitant protein synthesis, but not on SOS response, Dam or SeqA. Regeneration of ATP-DnaA from ADP-DnaA was also observed. These results indicate that the nucleotide form shifts of DnaA are tightly linked with an epistatic cell cycle event and with the chromosomal replication system.     

DnaA protein DNA-binding domain binds to Hda protein to promote inter-AAA+ domain interaction involved in regulatory inactivation of DnaA

Chromosomal replication is initiated from the replication origin oriC in Escherichia coli by the active ATP-bound form of DnaA protein. The regulatory inactivation of DnaA (RIDA) system, a complex of the ADP-bound Hda and the DNA-loaded replicase clamp, represses extra initiations by facilitating DnaA-bound ATP hydrolysis, yielding the inactive ADP-bound form of DnaA. However, the mechanisms involved in promoting the DnaA-Hda interaction have not been determined except for the involvement of an interaction between the AAA+ domains of the two. This study revealed that DnaA Leu-422 and Pro-423 residues within DnaA domain IV, including a typical DNA-binding HTH motif, are specifically required for RIDA-dependent ATP hydrolysis in vitro and that these residues support efficient interaction with the DNA-loaded clamp·Hda complex and with Hda in vitro. Consistently, substitutions of these residues caused accumulation of ATP-bound DnaA in vivo and oriC-dependent inhibition of cell growth. Leu-422 plays a more important role in these activities than Pro-423. By contrast, neither of these residues is crucial for DNA replication from oriC, although they are highly conserved in DnaA orthologues. Structural analysis of a DnaA·Hda complex model suggested that these residues make contact with residues in the vicinity of the Hda AAA+ sensor I that participates in formation of a nucleotide-interacting surface. Together, the results show that functional DnaA-Hda interactions require a second interaction site within DnaA domain IV in addition to the AAA+ domain and suggest that these interactions are crucial for the formation of RIDA complexes that are active for DnaA-ATP hydrolysis.     

Suppressors of DnaA(ATP) imposed overinitiation in Escherichia coli

Chromosome replication in Escherichia coli is limited by the supply of DnaA associated with ATP. Cells deficient in RIDA (Regulatory Inactivation of DnaA) due to a deletion of the hda gene accumulate suppressor mutations (hsm) to counteract the overinitiation caused by an elevated DnaA(ATP) level. Eight spontaneous hda suppressor mutations were identified by whole-genome sequencing, and three of these were analysed further. Two mutations (hsm-2 and hsm-4) mapped in the dnaA gene and led to a reduced ability to initiate replication from oriC. One mutation (hsm-1) mapped to the seqA promoter and increased the SeqA protein level in the cell. hsm-1 cells had prolonged origin sequestration, reduced DnaA protein level and reduced DnaA-Reactivating Sequence (DARS)-mediated rejuvenation of DnaA(ADP) to DnaA(ATP) , all of which could contribute to the suppression of RIDA deficiency. Despite of these defects hsm-1 cells were quite similar to wild type with respect to cell cycle parameters. We speculate that since SeqA binding sites might overlap with DnaA binding sites spread throughout the chromosome, excess SeqA could interfere with DnaA titration and thereby increase free DnaA level. Thus, in spite of reduction in total DnaA, the amount of DnaA molecules available for initiation may not be reduced.     

Feedback controls restrain the initiation of Escherichia coli chromosomal replication

In Escherichia coli, initiation of chromosomal replication is activated by a nucleoprotein complex formed primarily between the DnaA protein and oriC (replication origin) DNA. After replicational initiation, this complex has to be inactivated in order to repress the appearance of initiation events until the next scheduled round of initiation. Studies of the mechanisms responsible for this repression have recently revealed direct coupling between these mechanisms and key elements of the replication process, suggesting that feedback-type regulatory loops exist between the factors implicated in initiation and the elements yielded by the replication process. The loading of the ring-shaped beta-subunit of DNA polymerase III onto DNA plays a key role in the inactivation of the DnaA protein. Duplication of oriC DNA results in hemimethylated DNA, which is inert for reinitiation. Titration of large amounts of DnaA protein to a non-oriC locus can repress untimely initiations, and timely duplication of this locus is required for this repression in rapidly growing cells. All these systems functionally complement one another to ensure the maintenance of the interinitiation interval between two normal DNA replication cycles. The mechanisms that link the replication cycle to the progression of the cell cycle are also discussed.     

Titration of the Escherichia coli DnaA protein to excess datA sites causes destabilization of replication forks, delayed replication initiation and delayed cell division

In Escherichia coli, the level of the initiator protein DnaA is limiting for initiation of replication at oriC. A high-affinity binding site for DnaA, datA, plays an important role. Here, the effect of extra datA sites was studied. A moderate increase in datA dosage ( approximately fourfold) delayed initiation of replication and cell division, but increased the rate of replication fork movement about twofold. At a further increase in the datA gene dosage, the SOS response was induced, and incomplete rounds of chromosome replication were detected. Overexpression of DnaA protein suppressed the SOS response and restored normal replication timing and rate of fork movement. In the presence of extra datA sites, cells showed a dependency on PriA and RecA proteins, indicating instability of the replication fork. The results suggest that wild-type replication fork progression normally includes controlled pausing, and that this is a prerequisite for normal replication fork function.     

A nucleotide switch in the Escherichia coli DnaA protein initiates chromosomal replication: evidnece from a mutant DnaA protein defective in regulatory ATP hydrolysis in vitro and in vivo

The ATP-bound DnaA protein opens duplex DNA at the Escherichia coli origin of replication, leading to a series of initiation reactions in vitro. When loaded on DNA, the DNA polymerase III sliding clamp stimulates hydrolysis of DnaA-bound ATP in the presence of the IdaB/Hda protein, thereby yielding ADP-DnaA, which is inactive for initiation in vitro. This negative feedback regulation of DnaA activity is proposed to play a crucial role in the replication cycle. We here report that the mutant protein DnaA R334A is inert to hydrolysis of bound ATP, although its affinities for ATP and ADP remain unaffected. The ATP-bound DnaA R334A protein, but not the ADP form, initiates minichromosomal replication in vitro at a level similar to that seen for wild-type DnaA. When expressed at moderate levels in vivo, DnaA R334A is predominantly in the ATP-bound form, unlike the wild-type and DnaA E204Q proteins, which in vitro hydrolyze ATP in a sliding clamp- and IdaB/Hda-dependent manner. Furthermore, DnaA R334A, but not the wild-type or the DnaA E204Q proteins, promotes overinitiation of chromosomal replication. These in vivo data support a crucial role for bound nucleotides in regulating the activity of DnaA during replication. Based on a homology modeling analysis, we suggest that the Arg-334 residue closely interacts with bound nucleotides.     

Replication Initiator DnaA of Escherichia coli Changes Its Assembly Form on the Replication Origin during the Cell Cycle

DnaA is a replication initiator protein that is conserved among bacteria. It plays a central role in the initiation of DNA replication. In order to monitor its behavior in living Escherichia coli cells, a nonessential portion of the protein was replaced by a fluorescent protein. Such a strain grew normally, and flow cytometry data suggested that the chimeric protein has no substantial loss of the initiator activity. The initiator was distributed all over the nucleoid. Furthermore, a majority of the cells exhibited certain distinct foci that emitted bright fluorescence. These foci colocalized with the replication origin (oriC) region and were brightest during the period spanning the initiation event. In cells that had undergone the initiation, the foci were enriched in less intense ones. In addition, a significant portion of the oriC regions at this cell cycle stage had no colocalized DnaA-enhanced yellow fluorescent protein (EYFP) focus point. It was difficult to distinguish the initiator titration locus (datA) from the oriC region. However, involvement of datA in the initiation control was suggested from the observation that, in ΔdatA cells, DnaA-EYFP maximally colocalized with the oriC region earlier in the cell cycle than it did in wild-type cells and oriC concentration was increased.Initiation of DNA replication is highly regulated to coordinate with cell proliferation. It begins with a series of events in which the replication machinery is assembled at the replication origin of the chromosomal DNA (15, 26, 28, 38). Central to this process are the initiator proteins that bind to the origin of replication and eventually lead to the unwinding of the origin and to helicase loading on the unwound region. Previous biochemical studies and recent structural studies of the bacterial initiator protein DnaA have proposed the molecular mechanism of the action of ATP-DnaA in forming a large oligomeric complex to remodel the unique origin, oriC, and trigger duplex melting (12, 26). However, it is still not clear how the timing of initiation is controlled so that it takes place at a fixed time in the cell cycle. It has been reported that a basal level of DnaA molecules is bound by high-affinity DnaA binding sites (DnaA boxes R1, R2, and R4) at oriC throughout the cell cycle (9, 37). It is also suggested that noncanonical ATP-DnaA binding sites within oriC are occupied at elevated levels of the initiator molecules prior to the initiation event (18, 25). Thus, regulation of the activity and availability of DnaA is an important factor for the initiation control.At least three schemes are known to prevent untimely initiations in Escherichia coli. First, oriC is subject to sequestration, a process that prevents reinitiation, possibly by blocking ATP-DnaA from binding to newly replicated oriC (8, 24). E. coli oriC contains 11 GATC sites that are normally methylated on both strands by Dam methyltransferase. Immediately after passage of the replication fork, GATC sites are in a hemimethylated state, with the newly synthesized strands remaining unmethylated. SeqA binds specifically to such sites and, at oriC, protects these regions from reinitiation for about one-third of the cell cycle (6, 39). Second, in a process termed regulatory inactivation of DNA (RIDA), ATP-DnaA molecules are converted to an inactive ADP-bound form after initiation by the combined action of a β subunit of DNA polymerase III holoenzyme and Hda (16, 17). Newly synthesized DnaA molecules are able to bind ATP for the next initiation event, since its cellular concentration is much higher than that of ADP. ATP-DnaA is also regenerated from the inactive ADP-DnaA later in the cell cycle (21). Finally, the chromosomal segment datA serves to reduce the level of free DnaA protein by titrating a large number of DnaA molecules after replication of the site close to oriC (20).Cytological studies would be very useful for developing our understanding of the regulation mechanisms associated with the initiation step. In the present study, we tagged E. coli DnaA with a fluorescent protein in order to monitor its behavior in live cells. Microscopic observation revealed that DnaA is distributed all over the nucleoid. Remarkably, the majority of cells bore distinct foci that emitted brighter fluorescence against a weak fluorescent background on the nucleoid. We analyzed the behavior of these foci during the cell cycle with respect to oriC and datA.     

Hda, a novel DnaA-related protein, regulates the replication cycle in Escherichia coli

The bacterial DnaA protein binds to the chromosomal origin of replication to trigger a series of initiation reactions, which leads to the loading of DNA polymerase III. In Escherichia coli, once this polymerase initiates DNA synthesis, ATP bound to DnaA is efficiently hydrolyzed to yield the ADP-bound inactivated form. This negative regulation of DnaA, which occurs through interaction with the beta-subunit sliding clamp configuration of the polymerase, functions in the temporal blocking of re-initiation. Here we show that the novel DnaA-related protein, Hda, from E.coli is essential for this regulatory inactivation of DnaA in vitro and in vivo. Our results indicate that the hda gene is required to prevent over-initiation of chromosomal replication and for cell viability. Hda belongs to the chaperone-like ATPase family, AAA(+), as do DnaA and certain eukaryotic proteins essential for the initiation of DNA replication. We propose that the once-per-cell-cycle rule of replication depends on the timely interaction of AAA(+) proteins that comprise the apparatus regulating the activity of the initiator of replication.     

Association of the chromosome replication initiator DnaA with the Escherichia coli inner membrane in vivo: quantity and mode of binding

DnaA initiates chromosome replication in most known bacteria and its activity is controlled so that this event occurs only once every cell division cycle. ATP in the active ATP-DnaA is hydrolyzed after initiation and the resulting ADP is replaced with ATP on the verge of the next initiation. Two putative recycling mechanisms depend on the binding of DnaA either to the membrane or to specific chromosomal sites, promoting nucleotide dissociation. While there is no doubt that DnaA interacts with artificial membranes in vitro, it is still controversial as to whether it binds the cytoplasmic membrane in vivo. In this work we looked for DnaA-membrane interaction in E. coli cells by employing cell fractionation with both native and fluorescent DnaA hybrids. We show that about 10% of cellular DnaA is reproducibly membrane-associated. This small fraction might be physiologically significant and represent the free DnaA available for initiation, rather than the vast majority bound to the datA reservoir. Using the combination of mCherry with a variety of DnaA fragments, we demonstrate that the membrane binding function is delocalized on the surface of the protein's domain III, rather than confined to a particular sequence. We propose a new binding-bending mechanism to explain the membrane-induced nucleotide release from DnaA. This mechanism would be fundamental to the initiation of replication.     

Escherichia coli cells with increased levels of DnaA and deficient in recombinational repair have decreased viability

The dnaA operon of Escherichia coli contains the genes dnaA, dnaN, and recF encoding DnaA, beta clamp of DNA polymerase III holoenzyme, and RecF. When the DnaA concentration is raised, an increase in the number of DNA replication initiation events but a reduction in replication fork velocity occurs. Because DnaA is autoregulated, these results might be due to the inhibition of dnaN and recF expression. To test this, we examined the effects of increasing the intracellular concentrations of DnaA, beta clamp, and RecF, together and separately, on initiation, the rate of fork movement, and cell viability. The increased expression of one or more of the dnaA operon proteins had detrimental effects on the cell, except in the case of RecF expression. A shorter C period was not observed with increased expression of the beta clamp; in fact, many chromosomes did not complete replication in runout experiments. Increased expression of DnaA alone resulted in stalled replication forks, filamentation, and a decrease in viability. When the three proteins of the dnaA operon were simultaneously overexpressed, highly filamentous cells were observed (>50 micro m) with extremely low viability and, in runout experiments, most chromosomes had not completed replication. The possibility that recombinational repair was responsible for the survival of cells overexpressing DnaA was tested by using mutants in different recombinational repair pathways. The absence of RecA, RecB, RecC, or the proteins in the RuvABC complex caused an additional approximately 100-fold drop in viability in cells with increased levels of DnaA, indicating a requirement for recombinational repair in these cells.     

DnaA structure, function, and dynamics in the initiation at the chromosomal origin

Escherichia coli DnaA is the initiator of chromosomal replication. Multiple ATP-DnaA molecules assemble at the oriC replication origin in a highly regulated manner, and the resultant initiation complexes promote local duplex unwinding within oriC, resulting in open complexes. DnaB helicase is loaded onto the unwound single-stranded region within oriC via interaction with the DnaA multimers. The tertiary structure of the functional domains of DnaA has been determined and several crucial residues in the initiation process, as well as their unique functions, have been identified. These include specific DNA binding, inter-DnaA interaction, specific and regulatory interactions with ATP and with the unwound single-stranded oriC DNA, and functional interaction with DnaB helicase. An overall structure of the initiation complex is also proposed. These are important for deepening our understanding of the molecular mechanisms that underlie DnaA assembly, oriC duplex unwinding, regulation of the initiation reaction, and DnaB helicase loading. In this review, we summarize recent progress on the molecular mechanisms of the functions of DnaA on oriC. In addition, some members of the AAA+ protein family related to the initiation of replication and its regulation (e.g., DnaA) are briefly discussed.     

Protein associations in DnaA-ATP hydrolysis mediated by the Hda-replicase clamp complex

In Escherichia coli, the activity of ATP-bound DnaA protein in initiating chromosomal replication is negatively controlled in a replication-coordinated manner. The RIDA (regulatory inactivation of DnaA) system promotes DnaA-ATP hydrolysis to produce the inactivated form DnaA-ADP in a manner depending on the Hda protein and the DNA-loaded form of the beta-sliding clamp, a subunit of the replicase holoenzyme. A highly functional form of Hda was purified and shown to form a homodimer in solution, and two Hda dimers were found to associate with a single clamp molecule. Purified mutant Hda proteins were used in a staged in vitro RIDA system followed by a pull-down assay to show that Hda-clamp binding is a prerequisite for DnaA-ATP hydrolysis and that binding is mediated by an Hda N-terminal motif. Arg(168) in the AAA(+) Box VII motif of Hda plays a role in stable homodimer formation and in DnaA-ATP hydrolysis, but not in clamp binding. Furthermore, the DnaA N-terminal domain is required for the functional interaction of DnaA with the Hda-clamp complex. Single cells contain approximately 50 Hda dimers, consistent with the results of in vitro experiments. These findings and the features of AAA(+) proteins, including DnaA, suggest the following model. DnaA-ATP is hydrolyzed at a binding interface between the AAA(+) domains of DnaA and Hda; the DnaA N-terminal domain supports this interaction; and the interaction of DnaA-ATP with the Hda-clamp complex occurs in a catalytic mode.     

DnaAcos hyperinitiates by circumventing regulatory pathways that control the frequency of initiation in Escherichia coli

Mutants of dnaAcos are inviable at 30°C because DnaAcos hyperinitiates, leading to new replication forks that apparently collide from behind with stalled forks, thereby generating lethal double-strand breaks. By comparison, an elevated level of DnaA also induces extra initiations, but lethality occurs only in strains defective in repairing double-strand breaks. To explore the model that the chromosomal level of DnaAcos, or the increased abundance of DnaA, increases initiation frequency by, escaping or overcoming pathways that control initiation, respectively, we developed a genetic selection and identified seqA , datA , dnaN and hda , which function in pathways that either act at oriC or modulate DnaA activity. To assess each pathway's relative effectiveness, we used genetically inactivated strains, and quantified initiation frequency after elevating the level of DnaA. The results indicate that the hda -dependent pathway has a stronger effect on initiation than pathways involving seqA and datA . Testing the model that DnaAcos overinitiates because it fails to respond to one or more regulatory mechanisms, we show that dnaAcos is unresponsive to hda and dnaN , which encodes the β clamp, and also datA , a locus proposed to titer excess DnaA. These results explain how DnaAcos hyperinitiates to interfere with viability.     

Reactivation of DnaA by DNA sequence-specific nucleotide exchange in vitro

In Escherichia coli, ATP-bound DnaA protein can initiate chromosomal replication. After initiation, DnaA-ATP is hydrolyzed by interactions with a complex containing a replicase subunit to yield the inactive ADP-DnaA. However, the mechanisms which regenerate ATP-DnaA from ADP-DnaA are not well understood. We report here that a 70-bp DNA segment promotes exchange of the DnaA-bound nucleotide in a sequence-specific manner, thus reactivating the initiation function of DnaA in vitro. This segment contains a typical DnaA-binding 9-mer motif, the DnaA box, and two DnaA box-like sequences. The presence and precise composition of these three motifs are required for the DnaA-reactivating activity, which suggests that a highly ordered complex which includes multimeric DnaA molecules is formed for isomerization of DnaA. We named this DNA segment DARS, for DnaA-reactivating sequence. The role of DARS in regulation of DnaA function in vivo is discussed.