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 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.     

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.     

A novel role for cAMP in the control of the activity of the E. coli chromosome replication initiator protein, DnaA

DnaA protein interacts with cAMP with a KD of 1 microM. This interaction stimulates DnaA protein binding to the chromosome replication origin (oriC) and the mioC promoter region, protects DnaA protein from thermal inactivation, releases ADP but not ATP bound to DnaA protein, and restores normal DNA replication activity and ATPase activity in inactive ADP-DnaA protein preparations. A model is proposed in which cellular cAMP levels govern the replication activity of DnaA protein by promoting the recycling of the inactive ADP-DnaA protein form into the active ATP form.     

Timely binding of IHF and Fis to DARS2 regulates ATP–DnaA production and replication initiation

In Escherichia coli, the ATP-bound form of DnaA (ATP–DnaA) promotes replication initiation. During replication, the bound ATP is hydrolyzed to ADP to yield the ADP-bound form (ADP–DnaA), which is inactive for initiation. The chromosomal site DARS2 facilitates the regeneration of ATP–DnaA by catalyzing nucleotide exchange between free ATP and ADP bound to DnaA. However, the regulatory mechanisms governing this exchange reaction are unclear. Here, using in vitro reconstituted experiments, we show that two nucleoid-associated proteins, IHF and Fis, bind site-specifically to DARS2 to activate coordinately the exchange reaction. The regenerated ATP–DnaA was fully active in replication initiation and underwent DnaA–ATP hydrolysis. ADP–DnaA formed heteromultimeric complexes with IHF and Fis on DARS2, and underwent nucleotide dissociation more efficiently than ATP–DnaA. Consistently, mutant analyses demonstrated that specific binding of IHF and Fis to DARS2 stimulates the formation of ATP–DnaA production, thereby promoting timely initiation. Moreover, we show that IHF–DARS2 binding is temporally regulated during the cell cycle, whereas Fis only binds to DARS2 in exponentially growing cells. These results elucidate the regulation of ATP–DnaA and replication initiation in coordination with the cell cycle and growth phase.     

The DnaA Protein Is Not the Limiting Factor for Initiation of Replication in Escherichia coli

The bacterial replication cycle is driven by the DnaA protein which cycles between the active ATP-bound form and the inactive ADP-bound form. It has been suggested that DnaA also is the main controller of initiation frequency. Initiation is thought to occur when enough ATP-DnaA has accumulated. In this work we have performed cell cycle analysis of cells that contain a surplus of ATP-DnaA and asked whether initiation then occurs earlier. It does not. Cells with more than a 50% increase in the concentration of ATP-DnaA showed no changes in timing of replication. We suggest that although ATP-DnaA is the main actor in initiation of replication, its accumulation does not control the time of initiation. ATP-DnaA is the motor that drives the initiation process, but other factors will be required for the exact timing of initiation in response to the cell’s environment. We also investigated the in vivo roles of datA dependent DnaA inactivation (DDAH) and the DnaA-binding protein DiaA. Loss of DDAH affected the cell cycle machinery only during slow growth and made it sensitive to the concentration of DiaA protein. The result indicates that compromised cell cycle machines perform in a less robust manner.     

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.     

Multiple conformational states of DnaA protein regulate its interaction with DnaA boxes in the initiation of DNA replication

DnaA protein is the initiator of genomic DNA replication in prokaryotes. It binds to specific DNA sequences in the origin of DNA replication and unwinds small AT-rich sequences downstream for the assembly of the replisome. The mechanism of activation of DnaA that enables it to bind and organize the origin DNA and leads to replication initiation remains unclear. In this study, we have developed double-labeled fluorescent DnaA probes to analyze conformational states of DnaA protein upon binding DNA, nucleotide, and Soj sporulation protein using Fluorescence Resonance Energy Transfer (FRET). Our studies demonstrate that DnaA protein undergoes large conformational changes upon binding to substrates and there are multiple distinct conformational states that enable it to initiate DNA replication. DnaA protein adopted a relaxed conformation by expanding ~ 15 Å upon binding ATP and DNA to form the ATP·DnaA·DNA complex. Hydrolysis of bound ATP to ADP led to a contraction of DnaA within the complex. The relaxed conformation of DnaA is likely required for the formation of the multi-protein ATP·DnaA·DNA complex. In the initiation of sporulation, Soj binding to DnaA prevented relaxation of its conformation. Soj·ADP appeared to block the activation of DnaA, suggesting a mechanism for Soj·ADP in switching initiation of DNA replication to sporulation. Our studies demonstrate that multiple conformational states of DnaA protein regulate its binding to DNA in the initiation of DNA replication.     

Membrane-catalyzed nucleotide exchange on DnaA. Effect of surface molecular crowding

DnaA is the initiator protein for chromosomal replication in bacteria; its activity plays a central role in the timing of the primary initiations within the Escherichia coli cell cycle. A controlled, reversible conversion between the active ATP-DnaA and the inactive ADP forms modulates this activity. In a DNA-dependent manner, bound ATP is hydrolyzed to ADP. Acidic phospholipids with unsaturated fatty acids are capable of reactivating ADP-DnaA by promoting the release of the tightly bound ADP. The nucleotide dissociation kinetics, measured in the present study with the fluorescent derivative 3'-O-(N-methylantraniloyl)-5'-adenosine triphosphate, was dependent on the density of DnaA on the membrane in a cooperative manner: it increased 5-fold with decreased protein density. At all surface densities the nucleotide was completely released, presumably due to protein exchange on the membrane. Distinct temperature dependences and the effect of the crowding agent Ficoll suggest that two functional states of DnaA exist at high and low membrane occupancy, ascribed to local macromolecular crowding on the membrane surface. These novel phenomena are thought to play a major role in the mechanism regulating the initiation of chromosomal replication in bacteria.     

The intrinsic ATPase activity of Mycobacterium tuberculosis DnaA promotes rapid oligomerization of DnaA on oriC

Oligomerization of the initiator protein, DnaA, on the origin of replication (oriC) is crucial for initiation of DNA replication. Studies in Escherichia coli (Gram-negative) have revealed that binding of DnaA to ATP, but not hydrolysis of ATP, is sufficient to promote DnaA binding, oligomerization and DNA strand separation. To begin understanding the initial events involved in the initiation of DNA replication in Mycobacterium tuberculosis (Gram-positive), we investigated interactions of M. tuberculosis DnaA (DnaA(TB)) with oriC using surface plasmon resonance in the presence of ATP and ADP. We provide evidence that, in contrast to what is observed in E. coli, ATPase activity of DnaA(TB) promoted rapid oligomerization on oriC. In support, we found that a recombinant mutant DnaA(TB) proficient in binding to ATP, but deficient in ATPase activity, did not oligomerize as rapidly. The corresponding mutation in the dnaA gene of M. tuberculosis resulted in non-viability, presumably due to a defect in oriC-DnaA interactions. Dimethy sulphate (DMS) footprinting experiments revealed that DnaA(TB) bound to DnaA boxes similarly with ATP or ADP. DnaA(TB) binding to individual DnaA boxes revealed that rapid oligomerization on oriC is triggered only after the initial interaction of DnaA with individual DnaA boxes. We propose that ATPase activity enables the DnaA protomers on oriC to rapidly form oligomeric complexes competent for replication initiation.     

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.     

Rapid Exchange of Bound ADP on the Staphylococcus aureus Replication Initiation Protein DnaA

In Escherichia coli, regulatory inactivation of the replication initiator DnaA occurs after initiation as a result of hydrolysis of bound ATP to ADP, but it has been unknown how DnaA is controlled to coordinate cell growth and chromosomal replication in Gram-positive bacteria such as Staphylococcus aureus. This study examined the roles of ATP binding and its hydrolysis in the regulation of the S. aureus DnaA activity. In vitro, S. aureus DnaA melted S. aureus oriC in the presence of ATP but not ADP by a mechanism independent of ATP hydrolysis. Unlike E. coli DnaA, binding of ADP to S. aureus DnaA was unstable. As a result, at physiological concentrations of ATP, ADP bound to S. aureus DnaA was rapidly exchanged for ATP, thereby regenerating the ability of DnaA to form the open complex in vitro. Therefore, we examined whether formation of ADP-DnaA participates in suppression of replication initiation in vivo. Induction of the R318H mutant of the AAA+ sensor 2 protein, which has decreased intrinsic ATPase activity, caused over-initiation of chromosome replication in S. aureus, suggesting that formation of ADP-DnaA suppresses the initiation step in S. aureus. Together with the biochemical features of S. aureus DnaA, the weak ability to convert ATP-DnaA into ADP-DnaA and the instability of ADP-DnaA, these results suggest that there may be unidentified system(s) for reducing the cellular ratio of ATP-DnaA to ADP-DnaA in S. aureus and thereby delaying the re-initiation of DNA replication.     

Phospholipids promote dissociation of ADP from the Mycobacterium avium DnaA protein

The biochemical aspects of the initiation of DNA replication in Mycobacterium avium are unknown. As a first step towards understanding this process, M. avium DnaA protein, the counterpart of Escherichia coli replication initiator protein, was overproduced in E. coli with an N-terminal histidine tag and purified to homogeneity on a nickel affinity column. The recombinant DnaA protein bound both ATP and ADP with high affinity and showed a weak ATPase activity. ADP, following the hydrolysis of ATP, remained bound to the protein strongly and the exchange of ATP for bound ADP was found to be weak. Acidic phospholipids such as phosphatidylinositol, phosphatidylglycerol, and cardiolipin, promoted the dissociation of ADP from the DnaA protein, whereas the neutral phospholipid, phosphatidylethanolamine, did not. The phospholipid promoted dissociation of ADP from DnaA protein was stimulated in the presence of the M. avium origin of replication. We suggest that the initiation of DNA replication in M. avium involves an interplay among DnaA, adenine nucleotides and phospholipids.     

YabA and DnaD inhibit helix assembly of the DNA replication initiation protein DnaA

Control of DNA replication initiation is essential for cell growth. A unifying characteristic of DNA replication initiator proteins is their distinctive AAA+ nucleotide‐binding domains. The bacterial initiator DnaA assembles into a right‐handed helical oligomer built upon interactions between neighbouring AAA+ domains to form an active initiation complex. Recently we developed a unique cross‐linking assay that specifically detects ATP‐dependent DnaA helix assembly. Here we have utilized this assay to show that two DnaA regulatory proteins in Bacillus subtilis, YabA and DnaD, inhibit DnaA helix formation. These results, in combination with our previous finding that the regulatory factor Soj/ParA also targets DnaA filament formation, highlight the critical importance of regulating DnaA helix formation during the initiation reaction. Moreover, these observations lead us to suggest that DnaA oligomerization may be the main regulatory step of the initiator assembly pathway in B. subtilis, in contrast to the prevailing model of bacterial DNA replication based on Escherichia coli DnaA where ATP binding appears to be the targeted activity.     

The chromosome origin of Escherichia coli stabilizes DnaA protein during rejuvenation by phospholipids.

DnaA protein (the initiator protein) binds and clusters at the four DnaA boxes of the Escherichia coli chromosomal origin (oriC) to promote the strand opening for DNA replication. DnaA protein activity depends on the tight binding of ATP; the ADP form of DnaA protein, generated by hydrolysis of the bound ATP, is inactive. Rejuvenation of ADP-DnaA protein, by replacement with ATP, is catalyzed by acidic phospholipids in a highly fluid bilayer. We find that interaction of DnaA protein with oriC DNA is needed to stabilize DnaA protein during this rejuvenation process. Whereas DnaA protein bound to oriC DNA responds to phospholipids, free DnaA protein is inactivated by phospholipids and then fails to bind oriC. Furthermore, oriC DNA facilitates the high affinity binding of ATP to DnaA protein during treatment with phospholipids. A significant portion of the DnaA protein associated with oriC DNA can be replaced by the ADP form of the protein, suggesting that all of the DnaA protein bound to oriC DNA need not be rejuvenated between rounds of replication.     

Characterization of Escherichia coli DnaAcos protein in replication systems reconstituted with highly purified proteins

Excessive initiation of chromosomal replication occurs in the dnaAcos mutant at 30°C. Whereas purified wild-type DnaA protein binds ATP and ADP tightly, DnaAcos protein is defective for such nucleotide binding. As initiation is a multistep reaction and DnaA protein functions at each step, activities of DnaAcos protein need to be examined precisely. DnaAcos protein specifically bound a DNA fragment containing the chromosomal replication origin with an affinity similar to that seen with the wild-type protein. In a system reconstituted with purified proteins at 30°C, the mutant protein initiated replication of single-stranded DNA that contains a DnaA-binding hairpin structure. Thus, DnaAcos protein basically sustains affinity to a DnaA-binding sequence and functions in the loading of DnaB helicase onto single-stranded DNA. Thermal stabilities of wild-type DnaA and DnaAcos activities were comparable. Unlike wild-type DnaA protein, DnaAcos protein was inactive for minichromosomal replication in systems reconstituted with purified proteins in which the ATP-bound form of DnaA protein is required for initiation. Taken together, the data indicate that the prominent defect in DnaAcos protein appears to be the inability to bind nucleotide.     

DNA replication-coupled inactivation of DnaA protein in vitro: a role for DnaA arginine-334 of the AAA+ Box VIII motif in ATP hydrolysis

The DnaA protein, which initiates chromosomal replication in Escherichia coli, is negatively regulated by both the sliding clamp of DNA polymerase III holoenzyme and the IdaB protein. We have found that, when the amount of minichromosome is limited in an in vitro replication system, minichromosomal replication-stimulated hydrolysis of DnaA-bound ATP yields the ADP-bound inactive form. The number of sliding clamps formed during replication was at least five per minichromosome, which is 2.7-fold higher than the number formed during incubation without replication. These results support the notion that coupling of DnaA-ATP hydrolysis to DNA replication is the outcome of enhanced clamp formation. We have also found that the amino acid substitution R334H in DnaA severely inhibits the hydrolysis of bound ATP in vitro. Whereas ATP bound to wild-type DnaA is hydrolysed in a DNA-dependent intrinsic manner or in a sliding clamp-dependent manner, ATP bound to DnaA R334H protein was resistant to hydrolysis under the same conditions. This arginine residue may be located in the vicinity where ATP binds, and therefore may play an essential role in ATP hydrolysis. This residue is highly conserved among DnaA homologues and also in the Box VIII motif of the AAA+ protein family.     

Negative control of DNA replication by hydrolysis of ATP bound to DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli.

DnaA protein, the initiation factor for chromosomal DNA replication in Escherichia coli, is activated by ATP. ATP bound to DnaA protein is slowly hydrolyzed to ADP, but the physiological role of ATP hydrolysis is unclear. We constructed, by site-directed mutagenesis, mutated DnaA protein with lower ATPase activity, and we examined its function in vitro and in vivo. The ATPase activity of purified mutated DnaA protein (Glu204-->Gln) decreased to one-third that of the wild-type DnaA protein. The mutation did not significantly affect the affinity of DnaA protein for ATP or ADP. The mutant dnaA gene showed lethality in wild-type cells but not in cells growing independently of the function of oriC. Induction of the mutated DnaA protein in wild-type cells caused an overinitiation of DNA replication. Our results lead to the thesis that the intrinsic ATPase activity of DnaA protein negatively regulates chromosomal DNA replication in E. coli cells.