ATP activates dnaA protein in initiating replication of plasmids bearing the origin of the E. coli chromosome

ATP is bound to dnaA protein with high affinity (KD = 0.03 microM) and hydrolyzed slowly to ADP in the presence of DNA. ADP is also bound tightly to dnaA protein and exchanges with ATP very slowly. The ATP form is active in replication; the ADP form is not. A unique conformation of oriC, formed in an early initiation stage, depends on dnaA protein being in the ATP form. The subsequent entry of dnaB protein to form a prepriming complex also requires ATP binding and is blocked by bound ADP. Inasmuch as hydrolysis of ATP is far slower than these initiation reactions and since the poorly hydrolyzable analogue ATP gamma S can replace ATP, the ATP function appears to be allosteric. The extraordinary affinity of ATP for dnaA protein, its slow hydrolysis to ADP, the profound inhibition of dnaA functions by ADP, and the very slow exchange of ADP all point to a possible regulatory role for these nucleotides in the cell cycle.     

Cardiolipin activation of dnaA protein, the initiation protein of replication in Escherichia coli

ATP binding to dnaA protein is essential for its action in initiating the replication of plasmids that bear the unique origin of the Escherichia coli chromosome (oriC). ADP bound to that site renders dnaA protein inactive for replication. Diphosphatidylglycerol (cardiolipin), a diacidic membrane phospholipid, displaces the bound nucleotide, and in the presence of components that reconstitute replication, fully reactivates the inert ADP form of dnaA protein. The monacidic phosphatidylglycerol is one-tenth as active as cardiolipin, whereas the neutral phosphatidylethanolamine, the principal E. coli phospholipid, is inactive. Fluphenazine, a tranquilizer drug, blocks cardiolipin activation of dnaA protein, in keeping with the inhibitory action of such agents on phospholipid-dependent enzymes. With the use of this drug to terminate cardiolipin action, dependence of the activation on time, elevated temperature, and high levels of ATP was demonstrated. Cardiolipin binding of nucleotide-free dnaA protein prevents binding of ATP and initiation of oriC replication. Removal of a fatty acid from cardiolipin by phospholipase A reverses this inhibitory effect. The strong and specific interaction of cardiolipin, a cell membrane component, with an essential nucleotide-binding site of dnaA protein, the protein essential for the initiation of chromosome replication, may be an important element in regulating the cell cycle.     

The ABC-primosome. A novel priming system employing dnaA, dnaB, dnaC, and primase on a hairpin containing a dnaA box sequence

A priming mechanism requiring dnaA, dnaB, and dnaC proteins operates on a single-stranded DNA coated with single-stranded DNA-binding protein. This novel priming, referred to as "ABC-priming," requires a specific hairpin structure whose stem carries a dnaA protein recognition sequence (dnaA box). In conjunction with primase and DNA polymerase III holoenzyme, ABC-priming can efficiently convert single-stranded DNA into the duplex replicative form. dnaA protein specifically recognizes and binds the single-stranded hairpin and permits the loading of dnaB protein to form a prepriming protein complex containing dnaA and dnaB proteins which can be physically isolated. ABC-priming can replace phi X174 type priming on the lagging strand template of pBR322 in vitro, suggesting a possible function of ABC-priming for the lagging strand synthesis and duplex unwinding. Similar to the phi X174 type priming, a mobile nature of ABC-priming was indicated by helicase activity in the presence of ATP of a prepriming protein complex formed at the hairpin. The implications of this novel priming in initiation of replication at the chromosomal origin, oriC, and in its contribution to the replication fork are discussed.     

The dnaA initiator protein binds separate domains in the replication origin of Escherichia coli

After binding to its four 9-mer boxes in the 245-base pair Escherichia coli replication origin (oriC), dnaA protein effects the formation of an "open complex" in an adjacent region made up of three 13-mers (Bramhill, D., and Kornberg, A. (1988) Cell 52, 743-755). This open complex formation requires the ATP form of dnaA protein assisted by HU protein (Sekimizu, K., Bramhill, D., and Kornberg, A. (1987) Cell 50, 259-265). We now provide direct evidence that dnaA protein binds the 13-mers, sequences that bear no resemblance to the 9-mer box. The evidence is (i) displacement of dnaA protein from the open complex by oriC or by a synthetic oligonucleotide containing the 13-mers, but not by a mutant of oriC lacking the 13-mers; (ii) filter binding of the synthetic (13-mer) oligonucleotide by dnaA protein; and (iii) requirement for the ATP form of dnaA protein assisted by HU protein for temperature-dependent binding to the 13-mer region. Controlled proteolysis of dnaA protein results in a prompt loss of oriC binding; an NH2-terminal 30-kDa peptide contains the domain that binds ATP and phospholipids known to destabilize the tightly bound ATP.     

Stoichiometry of DnaA and DnaB protein in initiation at the Escherichia coli chromosomal origin

Initiation of DNA replication at the Escherichia coli chromosomal origin, oriC, occurs through an ordered series of events that depend first on the binding of DnaA protein, the replication initiator, to DnaA box sequences within oriC followed by unwinding of an AT-rich region near the left border. The prepriming complex then forms, involving the binding of DnaB helicase at oriC so that it is properly positioned at each replication fork. We assembled and isolated the prepriming complexes on an oriC plasmid, then determined the stoichiometries of proteins in these complexes by quantitative immunoblot analysis. DnaA protein alone binds to oriC with a stoichiometry of 4-5 monomers per oriC DNA. In the prepriming complex, the stoichiometries are 10 DnaA monomers and 2 DnaB hexamers per oriC plasmid. That only two DnaB hexamers are bound, one for each replication fork, suggests that the binding of additional molecules of DnaA in forming the prepriming complex restricts the loading of additional DnaB hexamers that can bind at oriC.     

Duplex opening by dnaA protein at novel sequences in initiation of replication at the origin of the E. coli chromosome

Three tandem repeats of a 13-mer in the AT-rich region are essential to the unique replication origin of E. coli and of remotely related Enterobacteriaceae. These iterated sequences are identified by deletion analysis and sensitivities to endonucleases as the site for initial duplex opening by the initiator dnaA protein. This "open complex" requires ATP and 38 degrees C for optimum formation and stability. The subsequent dnaC-dependent entry of dnaB helicase to form a "prepriming complex" stabilizes the open structure, blocks cleavages by a restriction endonuclease in the 13-mer region, and broadens the endonuclease cutting pattern. We propose that dnaA protein recognizes and successively opens the 13-mer sequences, thereby guiding the entry of dnaB helicase into the duplex preparatory to priming of replication.     

DnaA Protein of Escherichia coli: oligomerization at the E. coli chromosomal origin is required for initiation and involves specific N-terminal amino acids

Iterated DnaA box sequences within the replication origins of bacteria and prokaryotic plasmids are recognized by the replication initiator, DnaA protein. At the E. coli chromosomal origin, oriC, DnaA is speculated to oligomerize to initiate DNA replication. We developed an assay of oligomer formation at oriC that relies on complementation between two dnaA alleles that are inactive by themselves. One allele is dnaA46; its inactivity at the non-permissive temperature is due to a specific defect in ATP binding. The second allele, T435K, does not support DNA replication because of its inability to bind to DnaA box sequences within oriC. We show that the T435K allele can complement the dnaA46(Ts) allele. The results support a model of oligomer formation in which DnaA box sequences of oriC are bound by DnaA46 to which T435K then binds to form an active complex. Relying on this assay, leucine 5, tryptophan 6 and cysteine 9 in a predicted alpha helix were identified that, when altered, interfere with oligomer formation. Glutamine 8 is additionally needed for oligomer formation on an oriC-containing plasmid, suggesting that the structure of the DnaA-oriC complex at the chromosomal oriC locus is similar but not identical to that assembled on a plasmid. Other evidence suggests that proline 28 of DnaA is involved in the recruitment of DnaB to oriC. These results provide direct evidence that DnaA oligomerization at oriC is required for initiation to occur.     

In vitro assembly of a prepriming complex at the origin of the Escherichia coli chromosome

During initiation of DNA replication of plasmids containing the origin of the Escherichia coli chromosome (oriC), the proteins dnaA, dnaB, and dnaC interact and assemble a complex at oriC. The complex is larger and more asymmetric than that formed by dnaA protein and embraces an extra 50 base pairs at the left side of the minimal oriC sequence. Both dnaA and dnaB proteins have been identified in the complex by electron microscopy and antibody binding; dnaC protein was not detected. HU protein, which stimulates the activity of the initiation reaction, was often present. Entry of dnaB protein required dnaA and dnaC proteins and a supercoiled template. Thus, a complex structure, involving multiple proteins and a large region of DNA, must be formed at the origin to prepare the template for priming and replication.     

Extensive unwinding of the plasmid template during staged enzymatic initiation of DNA replication from the origin of the Escherichia coli chromosome

Early in the staged initiation of enzymatic replication of plasmids containing the unique origin of the E. coli chromosome (oriC), the plasmid is converted to a new topological form which is highly underwound, two to 15 times more than native supercoiled DNA. The underwinding reaction precedes priming of DNA synthesis and follows an initial complex formation, requiring ATP and proteins dnaA, dnaB, and dnaC; underwinding depends on the further addition of gyrase and SSB. DnaB protein as a helicase and gyrase as a topoisomerase drive the underwinding with the energy of ATP hydrolysis. The underwound template, extensively single-stranded and complexed with proteins, is an active form for priming by primase and elongation by DNA polymerase III holoenzyme.     

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.     

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.     

A novel protein binds a key origin sequence to block replication of an E. coli minichromosome

A sequence of three tandem repeats of a 13-mer in the replication origin (oriC) of E. coli is the highly conserved site of opening of the duplex for initiation of DNA synthesis. A protein that binds this sequence has been discovered in E. coli and purified to homogeneity. This novel 33 kd polypeptide behaves as a dimer. Binding to the 13-mers is specific and limited to this region. At a ratio of 10-20 monomers per oriC plasmid, the binding blocks initiation by preventing the opening of the 13-mer region by dnaA protein. Once the 13-mers are opened by dnaA protein action, the 33 kd protein is without effect on the subsequent stages of replication. The specificity of binding and profound inhibitory effect suggest a regulatory role for this protein at an early stage of chromosome initiation.     

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.     

Coordinated replication and sequestration of oriC and dnaA are required for maintaining controlled once-per-cell-cycle initiation in Escherichia coli

Escherichia coli cells were constructed in which the dnaA gene was moved to a location opposite oriC on the circular chromosome. In these cells the dnaA gene was replicated with significant delay relative to the origin. Consequently, the period where the newly replicated and hemimethylated oriC was sequestered no longer coincided with the period where the dnaA gene promoter was sequestered. DnaA protein synthesis was therefore expected to continue during origin sequestration. Despite a normal length of the sequestration period in such cells, they had increased origin content and also displayed asynchrony of initiation. This indicated that reinitiation occasionally occurred at some origins within the same cell cycle. The extra initiations took place in spite of a reduction in total DnaA protein concentration to about half of the wild-type level. We propose that this more efficient utilization of DnaA protein results from an increased availability at the end of the origin sequestration period. Therefore, coordinated sequestration of oriC and dnaA is required for maintaining controlled once-per-cell-cycle initiation.     

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.