Heat shock proteins DnaJ, DnaK, and GrpE stimulate P1 plasmid replication by promoting initiator binding to the origin.

Binding of the P1-encoded protein RepA to the origin of P1 plasmid replication is essential for initiation of DNA replication and for autoregulatory repression of the repA promoter. Previous studies have shown defects in both initiation and repression in hosts lacking heat shock proteins DnaJ, DnaK, and GrpE and have suggested that these proteins play a role in the RepA-DNA binding required for initiation and repression. In this study, using in vivo dimethyl sulfate footprinting, we have confirmed the roles of the three heat shock proteins in promoting RepA binding to the origin. The defects in both activities could be suppressed by increasing the concentration of wild-type RepA over the physiological level. We also isolated RepA mutants that were effective initiators and repressors without requiring the heat shock proteins. These data suggest that the heat shock proteins facilitate both repression and initiation by promoting only the DNA-binding activity of RepA. In a similar plasmid, F, initiator mutants that confer heat shock protein independence for replication were also found, but they were defective for repression. We propose that the initiator binding involved in repression and the initiator binding involved in initiation are similar in P1 but different in F.     

Bacterial replication initiator DnaA. Rules for DnaA binding and roles of DnaA in origin unwinding and helicase loading

We review the processes leading to the structural modifications required for the initiation of replication in Escherichia coli, the conversion of the initial complex to the open complex, loading of helicase, and the assembly of two replication forks. Rules for the binding of DnaA to its binding sites are derived, and the properties of ATP-DnaA are described. We provide new data on cooperative interaction and dimerization of DnaA proteins of E. coli, Streptomyces and Thermus thermophilus, and on the stoichiometry of DnaA-oriC complexes of E. coli.     

DnaA boxes in the P1 plasmid origin: the effect of their position on the directionality of replication and plasmid copy number.

The DnaA protein is essential for initiation of DNA replication in a wide variety of bacterial and plasmid replicons. The replication origin in these replicons invariably contains specific binding sites for the protein, called DnaA boxes. Plasmid P1 contains a set of DnaA boxes at each end of its origin but can function with either one of the sets. Here we report that the location of origin-opening, initiation site of replication forks and directionality of replication do not change whether the boxes are present at both or at one of the ends of the origin. Replication was bidirectional in all cases. These results imply that DnaA functions similarly from the two ends of the origin. However, origins with DnaA boxes proximal to the origin-opening location opened more efficiently and maintained plasmids at higher copy numbers. Origins with the distal set were inactive unless the adjacent P1 DNA sequences beyond the boxes were included. At either end, phasing of the boxes with respect to the remainder of the origin influenced the copy number. Thus, although the boxes can be at either end, their precise context is critical for efficient origin function.     

Missing-base and ethylation interference footprinting of P1 plasmid replication initiator.

RepA, the replication initiator protein of plasmid P1, binds to specific 19 bp sequences on the plasmid DNA. Earlier footprinting studies with dimethylsulfate identified the guanines that contact RepA through the major groove of DNA. In this study, base elimination was used to identify the contribution of all four bases to the binding reaction. Depurination and depyrimidation of any base in the neighborhood of the contacting guanines was found to decrease RepA binding. These results are consistent with the notion that RepA contacts bases of two consecutive major grooves on the same face of DNA. We also observed that depurination but not methylation of three guanines (G3, G8 and G9) affected binding. We identified the DNA phosphate groups (3 in the top strand, one of which mapped between G8 and G9, and 4 in the bottom strand, one of which was adjacent to C3) that strongly interfered with RepA binding upon ethylation. These results indicate that certain bases (e.g. G3, G8 and G9) may not contact RepA directly but contribute to base and backbone contacts by maintaining proper structure of the binding site.     

The bacterial replication initiator DnaA. DnaA and oriC,the bacterial mode to initiate DNA replication

The initiation of replication is the central event in the bacterial cell cycle. Cells control the rate of DNA synthesis by modulating the frequency with which new chains are initiated, like all macromolecular synthesis. The end of the replication cycle provides a checkpoint that must be executed for cell division to occur. This review summarizes recent insight into the biochemistry, genetics and control of the initiation of replication in bacteria, and the central role of the initiator protein DnaA.     

Relaxation of replication control in chaperone-independent initiator mutants of plasmid P1.

Escherichia coli chaperones DnaJ, DnaK and GrpE increase P1 plasmid initiator binding to the origin by promoting initiator folding. The binding allows initiation and also promotes pairing of origins which is believed to control initiation frequency. Chaperone-independent DNA binding mutants are often defective in replication control. We show here that these mutants have increased rates of association for DNA binding and defects in origin pairing. The increases in association rates were found to be due either to increased protein folding into active forms or to increases in the association rate constant, kon. Since the dissociation rate constants for DNA release with these mutants are not changed, it is unlikely that the DNA binding domain is affected. The pairing domain may thus control replication and modulate DNA binding. The role of the pairing domain in DNA binding can be significant in vivo as the selection for chaperone-independent binding favors pairing-defective mutants.     

P1 plasmid replication. Role of initiator titration in copy number control

The copy number control locus incA of unit copy plasmid P1 maps in a region containing nine 19 base-pair repeats. Previous results from studies in vivo and in vitro indicated that incA interacts with the plasmid-encoded RepA protein, which is essential for replication. It has been proposed that the repeat sequences negatively control copy number by sequestering the RepA protein, which is rate-limiting for replication. Our results lend further support to this hypothesis. Here we show that the repeats can be deleted completely from P1 miniplasmids and the deletion results in an approximately eightfold increase in plasmid copy number. So, incA sequences are totally dispensable for replication and have only a regulatory role. The copy number of incA-deleted plasmids can be reduced if incA sequences are present in trans or are reincorporated at two different positions in the plasmid. This reduction in copy number is not due to lowered expression of the repA gene in the presence of incA. We show that one repeat sequence is sufficient to bind RepA and can reduce the copy number of incA-deleted plasmids. When part of the repeat was deleted, it lost its ability to bind as well as influence copy number. These results show a strong correlation between the capacity of incA repeats to bind RepA protein both in vivo and in vitro, and the function of incA in the control of copy number.     

P1 plasmid replication: measurement of initiator protein concentration in vivo.

To study the functions of the mini-P1 replication initiation protein RepA quantitatively, we have developed a method to measure RepA concentration by using immunoblotting. In vivo, there are about 20 RepA dimers per unit-copy plasmid DNA. RepA was deduced to be a dimer from gel filtration of the purified protein. Since there are 14 binding sites of the protein per replicon, the physiological concentration of the protein appears to be sufficiently low to be a rate-limiting factor for replication. Autoregulation is apparently responsible for the low protein level; at the physiological concentration of the protein, the repA promoter retains only 0.1% of its full activity as determined by gene fusions to lacZ. When the concentration is further decreased by a factor of 3 or increased by a factor of 40, replication is no longer detectable.     

A single DnaA box is sufficient for initiation from the P1 plasmid origin.

The P1 plasmid replication origin requires the host DnaA protein for function. Two DnaA-binding boxes lie in tandem within the previously defined minimal origin, constituting its left boundary. Three more boxes lie 200 base pairs to the right of these, in the leader region for the P1 repA gene. We show that either set alone is active for origin function. One of the two origin boxes is relatively inactive. Constructs with just one of the five boxes are active for specific origin function as long as the box conforms exactly to the published consensus. This single consensus box is functional when placed either to the left or right of the core origin sequences. The flexibility shown by this system suggests that the boxes play a role different from those in the host oriC origin, where the number and position of boxes are critical.     

Fate of the DnaA initiator protein in replication at the origin of the Escherichia coli chromosome in vitro

The dnaA initiator protein binds specific sequences in the 245-base pair Escherichia coli origin (oriC) to form a series of complexes which eventually are opened enough to admit dnaB helicase into a prepriming complex (Bramhill, D., and Kornberg, A. (1988) Cell 52, 743-755). ATP bound to a high-affinity site on dnaA protein is the preferred form for one or more of the early stages, but an elevated level of ATP is needed for a later stage; further evidence for a low-affinity site has now been obtained. We find that at limiting levels of dnaA protein only the ATP form produces an active initial complex; neither the ADP nor the non-nucleotide forms are effective. Augmentation of the activity of a limiting level of the ATP form of dnaA protein by the otherwise inert ADP form implies that at some stage of initiation both forms are active. The dnaA protein is essential up to the stage of forming the prepriming complex; upon salt dissociation from an oriC complex, the protein can be recycled to function at a fresh origin. Distinctive conformational states of the ATP form are implied by interactions with oriC DNA, by the influence of phospholipids on accelerating nucleotide exchange, and by the susceptibility to proteolytic cleavage.     

Control of the replication initiator DnaA by an anti-cooperativity factor

Proper coordination of DNA replication with cell growth and division is critical for production of viable progeny. In bacteria, coordination of DNA replication with cell growth is generally achieved by controlling activity of the replication initiator DnaA and its access to the chromosomal origin of replication, oriC. Here we describe a previously unknown mechanism for regulation of DnaA. YabA, a negative regulator of replication initiation in Bacillus subtilis, interacts with DnaA and DnaN, the sliding (processivity) clamp of DNA polymerase. We found that in vivo, YabA associated with the oriC region in a DnaA-dependent manner and limited the amount of DnaA at oriC. In vitro, purified YabA altered binding of DnaA to DNA by inhibiting cooperativity. Although previously undescribed, proteins that directly inhibit cooperativity may be a common mechanism for regulating replication initiation. Conditions that cause release of DnaN from the replisome, or overproduction of DnaN, caused decreased association of YabA and increased association of DnaA with oriC. This effect of DnaN, either directly or indirectly, is likely responsible, in part, for enabling initiation of a new round of replication following completion of a previous round.     

Identification of the chromosomal replication origin from Thermus thermophilus and its interaction with the replication initiator DnaA

The chromosomal replication origin oriC and the gene encoding the replication initiator protein DnaA from Thermus thermophilus have been identified and cloned into an Escherichia coli vector system. The replication origin is composed of 13 characteristically arranged DnaA boxes, binding sites for the DnaA protein, and an AT-rich stretch, followed by the dnaN gene. The dnaA gene is located upstream of the origin and expresses a typical DnaA protein that follows the division into four domains, as with other members of the DnaA protein family. Here, we report the purification of Thermus-DnaA (Tth-DnaA) and characterize the interaction of the purified protein with the replication origin, with regard to the binding kinetics and stoichiometry of this interaction. Using gel retardation assays, surface plasmon resonance (SPR) and electron microscopy, we show that, unlike the E. coli DnaA, Tth-DnaA does not recognize a single DnaA box, instead a cluster of three tandemly repeated DnaA boxes is the minimal requirement for specific binding. The highest binding affinities are observed with full-length oriC or six clustered, tandemly repeated DnaA boxes. Furthermore, high-affinity DNA-binding of Tth-DnaA is dependent on the presence of ATP. The Thermus DnaA/oriC interaction will be compared with oriC complex formation generated by other DnaA proteins.     

Soj/ParA stalls DNA replication by inhibiting helix formation of the initiator protein DnaA

Control of DNA replication initiation is essential for normal cell growth. A unifying characteristic of DNA replication initiator proteins across the kingdoms of life 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, that in vitro stretches DNA to promote replication origin opening. The Bacillus subtilis protein Soj/ParA has previously been shown to regulate DnaA-dependent DNA replication initiation; however, the mechanism underlying this control was unknown. Here, we report that Soj directly interacts with the AAA+ domain of DnaA and specifically regulates DnaA helix assembly. We also provide critical biochemical evidence indicating that DnaA assembles into a helical oligomer in vivo and that the frequency of replication initiation correlates with the extent of DnaA oligomer formation. This work defines a significant new regulatory mechanism for the control of DNA replication initiation in bacteria.     

SirA enforces diploidy by inhibiting the replication initiator DnaA during spore formation in Bacillus subtilis

How cells maintain their ploidy is relevant to cellular development and disease. Here, we investigate the mechanism by which the bacterium Bacillus subtilis enforces diploidy as it differentiates into a dormant spore. We demonstrate that a sporulation-induced protein SirA (originally annotated YneE) blocks new rounds of replication by targeting the highly conserved replication initiation factor DnaA. We show that SirA interacts with DnaA and displaces it from the replication origin. As a result, expression of SirA during growth rapidly blocks replication and causes cell death in a DnaA-dependent manner. Finally, cells lacking SirA over-replicate during sporulation. These results support a model in which induction of SirA enforces diploidy by inhibiting replication initiation as B. subtilis cells develop into spores.     

P1 plasmid replication: initiator sequestration is inadequate to explain control by initiator-binding sites.

The unit-copy plasmid replicon mini-P1 consists of an origin, a gene for an initiator protein, RepA, and a control locus, incA. Both the origin and the incA locus contain repeat sequences that bind RepA. It has been proposed that the incA repeats control replication by sequestering the rate-limiting RepA initiator protein. Here we show that when the concentration of RepA was increased about fourfold beyond its normal physiological level from an inducible source in trans, the copy number of a plasmid carrying the P1 origin increased about eightfold. However, when the origin and a single copy of incA were present in the same plasmid, the copy number did not even double. The failure of an increased supply of RepA to overcome the inhibitory activity of incA is inconsistent with the hypothesis that incA inhibits replications solely by sequestering RepA. We propose that incA, in addition to sequestration, can also restrain replication by causing steric hindrance to the origin function. Our proposal is based on the observation that incA can bind to a RepA-origin complex in vitro.     

Critical sequences in the core of the P1 plasmid replication origin.

The core of the P1 plasmid replication origin consists of a series of 7-bp repeats and a G+C-rich stretch. Methylation of the GATC sequences in the repeats is essential. Forty different single-base mutations in the region were isolated and assayed for origin function. A single-base change within any 7-bp repeat could block the origin, irrespective of whether GATC bases were affected. The repeats themselves were critical, but the short intervals between them were not. Mutations in the G+C-rich region showed it to be a spacer whose exact length is important but whose sequence can vary considerably. It maintains a precise distance between the 7-bp repeats and binding sites for the P1 RepA initiator protein. It may also serve as a clamp to limit strand separation during initiation.     

Interactions of DnaA proteins from distantly related bacteria with the replication origin of the broad host range plasmid RK2

Replication initiation of the broad host range plasmid RK2 requires binding of the host-encoded DnaA protein to specific sequences (DnaA boxes) at its replication origin (oriV). In contrast to a chromosomal replication origin, which functionally interacts only with the native DnaA protein of the organism, the ability of RK2 to replicate in a wide range of Gram-negative bacterial hosts requires the interaction of oriV with many different DnaA proteins. In this study we compared the interactions of oriV with five different DnaA proteins. DNase I footprint, gel mobility shift, and surface plasmon resonance analyses showed that the DnaA proteins from Escherichia coli, Pseudomonas putida, and Pseudomonas aeruginosa bind to the DnaA boxes at oriV and are capable of inducing open complex formation, the first step in the replication initiation process. However, DnaA proteins from two Gram-positive bacteria, Bacillus subtilis and Streptomyces lividans, while capable of specifically interacting with the DnaA box sequences at oriV, do not bind stably and fail to induce open complex formation. These results suggest that the inability of the DnaA protein of a host bacterium to form a stable and functional complex with the DnaA boxes at oriV is a limiting step for plasmid host range.     

DnaA, the initiator of Escherichia coli chromosomal replication, is located at the cell membrane

Given the lack of a nucleus in prokaryotic cells, the significance of spatial organization in bacterial chromosome replication is only beginning to be fully appreciated. DnaA protein, the initiator of chromosomal replication in Escherichia coli, is purified as a soluble protein, and in vitro it efficiently initiates replication of minichromosomes in membrane-free DNA synthesis reactions. However, its conversion from a replicatively inactive to an active form in vitro occurs through its association with acidic phospholipids in a lipid bilayer. To determine whether the in situ residence of DnaA protein is cytoplasmic, membrane associated, or both, we examined the cellular location of DnaA using immunogold cryothin-section electron microscopy and immunofluorescence. Both of these methods revealed that DnaA is localized at the cell membrane, further suggesting that initiation of chromosomal replication in E. coli is a membrane-affiliated event.     

Regulation of the replication initiator DnaA in Caulobacter crescentus

The decision to initiate DNA replication is a critical step in the cell cycle of all organisms. In nearly all bacteria, replication initiation requires the activity of the conserved replication initiation protein DnaA. Due to its central role in cell cycle progression, DnaA activity must be precisely regulated. This review summarizes the current state of DnaA regulation in the asymmetrically dividing α-proteobacterium Caulobacter crescentus, an important model for bacterial cell cycle studies. Mechanisms will be discussed that regulate DnaA activity and abundance under optimal conditions and in coordination with the asymmetric Caulobacter cell cycle. Furthermore, we highlight recent findings of how regulated DnaA synthesis and degradation collaborate to adjust DnaA abundance under stress conditions. The mechanisms described provide important examples of how DNA replication is regulated in an α-proteobacterium and thus represent an important starting point for the study of DNA replication in many other bacteria. This article is part of a Special Issue entitled: Dynamic gene expression, edited by Prof. Patrick Viollier.