Characterization of Staphylococcus aureus Primosomal DnaD Protein: Highly Conserved C-Terminal Region Is Crucial for ssDNA and PriA Helicase Binding but Not for DnaA Protein-Binding and Self-Tetramerization

The role of DnaD in the recruitment of replicative helicase has been identified. However, knowledge of the DNA, PriA, and DnaA binding mechanism of this protein for the DnaA- and PriA-directed replication primosome assemblies is limited. We characterized the DNA-binding properties of DnaD from Staphylococcus aureus (SaDnaD) and analyzed its interactions with SaPriA and SaDnaA. The gel filtration chromatography analysis of purified SaDnaD and its deletion mutant proteins (SaDnaD1-195, SaDnaD1-200 and SaDnaD1-204) showed a stable tetramer in solution. This finding indicates that the C-terminal region aa 196–228 is not crucial for SaDnaD oligomerization. SaDnaD forms distinct complexes with ssDNA of different lengths. In fluorescence titrations, SaDnaD bound to ssDNA with a binding-site size of approximately 32 nt. A stable complex of SaDnaD1-195, SaDnaD1-200, and SaDnaD1-204 with ssDNA dT40 was undetectable, indicating that the C-terminal region of SaDnaD (particularly aa 205–228) is crucial for ssDNA binding. The SPR results revealed that SaDnaD1-195 can interact with SaDnaA but not with SaPriA, which may indicate that DnaD has different binding sites for PriA and DnaA. Both SaDnaD and SaDnaDY176A mutant proteins, but not SaDnaD1-195, can significantly stimulate the ATPase activity of SaPriA. Hence, the stimulation effect mainly resulted from direct contact within the protein—protein interaction, not via the DNA—protein interaction. Kinetic studies revealed that the SaDnaD-SaPriA interaction increases the Vmax of the SaPriA ATPase fivefold without significantly affecting the Km. These results indicate that the conserved C-terminal region is crucial for ssDNA and PriA helicase binding, but not for DnaA protein-binding and self-tetramerization.


Introduction
Initiation and re-initiation of chromosomal DNA replication in bacteria is a complex process that depends on divergent multi-protein assembly for loading the replicative DNA helicase at the replication origin [1,2,3,4,5]. DNA damage causes arrest and disassembly of the replication machinery, anywhere along the DNA, leading to replication failure [6,7,8]. Genome integrity should be maintained from generation to generation to ensure proper cell function and survival; thus, collapsed DNA replication forks must be reactivated through origin-independent replisome reloading for genome duplication. The replication restart primosome [9,10,11] is a formidable enzymatic machine; it is a protein-DNA complex that reactivates stalled DNA replication at repaired replication forks after DNA damage [12]. In contrast to the DnaAdirected primosome initiated at the unique oriC site [3,4], the replication restart primosome preferentially recognizes three-way branched DNA structures that possess a leading strand [13,14,15,16].
The replication restart primosome in Escherichia coli includes seven essential proteins, namely, PriA helicase, PriB, PriC, DnaB helicase, DnaC, DnaT, and DnaG primase [10]. The mechanisms of action of DNA replication restart primosome in bacteria have mainly been studied in Gram-negative E. coli, and, to a lesser extent, in Gram-positive bacteria [17]. Different bacteria have different strategies for the functional loading of cellular replicative DNA helicases [18]. In the Gram-positive Bacillus subtilis, the DNA replication initiator protein PriA helicase has a homolog of E. coli [19]. Nevertheless, essential helicase-loading components, such as PriB, PriC, DnaT, and DnaC proteins, are not found in Gram-positive bacteria [20]. Instead, three other proteins, namely, DnaD, DnaB, and DnaI, have been genetically and biochemically proven to be required for the replication restart of the Gram-positive B. subtilis [21,22,23,25,26]. The DnaD and DnaB have no homologs in Gram-negative bacteria, and their functions for DnaA-and PriA-dependent initiation of DNA replication need to be examined.
DnaD interacts with DnaA [26], DnaB [24], and DnaD itself [27]. Following DnaA assembly at oriC in B. subtilis, DnaD and DnaB are sequentially recruited and are required to deposit the protein complex of the helicase loader DnaI and the DNA helicase DnaC onto the unwound DNA duplex [28]. DnaD inhibits the cooperative DNA-binding activity [29], and may regulate DNA replication initiation. DnaD forms scaffolds and enhances duplex melting [30]. DnaD functions as a global regulator of DNA architecture [22] and a potential modulator for global superhelical density [31]. Moreover, this protein interacts with linear DNA and forms a nucleoprotein structure with a round DnaD scaffold in an open circle [32]. DnaD consists of an N-terminal domain with oligomerization activity and a C-terminal domain with single-stranded DNA (ssDNA)-binding activity [27]. The crystal structure of the N-terminal domain of DnaD reveals an extended winged-helix fold [33] and a unique tetramerization motif for the DnaD-mediated scaffold formation [34]. NMR analysis of the structure of the DnaD C-terminal domain reveals the presence of five helices [35]. Although DnaD can bind to DNA and form large nucleoprotein complexes in the absence of the N-terminal domain, it does not exhibit DNA remodeling activity [27].
DnaD is a component of the DNA replication primosome, but information on PriA and DnaA binding of DnaD is limited. Knowledge of stoichiometry, domain function, and binding activity is a prerequisite for formulating any model of protein function in DNA replication. In this study, the DNA-DnaD interactions were analyzed through electrophoretic mobility shift analysis (EMSA) and fluorescence quenching. Furthermore, considering our collective data from surface plasmon resonance (SPR) experiments, ATPase stimulation effects and gold nanoparticle assays on DnaD-PriA and DnaD-DnaA interactions, as well as studies on deletion mutants, we propose and discuss probable domain functions of DnaD.

Materials and Methods
Construction of SaDnaD, SaDnaD1-195, SaDnaD1-200, SaDnaD1-204, SaPriA, and SaDnaA expression plasmids The gene encoding the putative Staphylococcus aureus PriA (SaPriA), SaDnaA, and SaDnaD was individually amplified by PCR using the genomic DNA of S. aureus subsp. aureus ED98 as template. The forward and reverse primers were designed to introduce unique restriction sites into SaDnaD and its deletion mutants, permitting the insertion of the amplified gene into the pET21e vector for protein expression in E. coli. SaDnaA gene was amplified and inserted into the pET21b vector. Construction of the SaPriA expression plasmid has been reported [36]. The pET21e vector [37] was engineered from the pET21b vector (Novagen Inc., Madison, WI, USA) to avoid N-terminal T7 tag. Primers used for the construction of these plasmids are listed in Table 1.

Protein expression and purification
The recombinant proteins were expressed and purified using the protocol described previously for PriB [38]. Briefly, E. coli BL21(DE3) cells were transformed with the expression vector and overexpression of the expression plasmids was induced by incubating with 1 mM isopropyl thiogalactopyranoside. The protein was purified from the soluble supernatant by Ni 2+ -affinity chromatography (HiTrap HP; GE Healthcare Bio-Sciences), eluted with Buffer A (20 mM Tris-HCl, 250 mM imidazole, and 0.5 M NaCl, pH 7.9), and dialyzed against a dialysis buffer (20 mM HEPES and 100 mM NaCl, pH 7.0; Buffer B). Protein purity remained at >97% as determined by SDS-PAGE (Mini-PROTEAN Tetra System; Bio-Rad, CA, USA).

Gel-filtration chromatography
Gel-filtration chromatography was carried out by the AKTA-FPLC system (GE Healthcare Bio-Sciences, Piscataway, NJ, USA). In brief, purified protein (2 mg/mL) in Buffer B was applied to a Superdex 200 HR 10/30 column (GE Healthcare Bio-Sciences, Piscataway, NJ, USA) equilibrated with the same buffer. The column was operated at a flow rate of 0.5 mL/ min, and the proteins were detected at 280 nm. The column was calibrated with proteins of known molecular weight: thyroglobulin (670 kDa), γ-globulin (158 kDa), ovalbumin (44 kDa), and myoglobin (17 kDa). The K av values for the standard proteins and the SaDnaD variants Table 1. Primers used for construction of plasmids.

Oligonucleotide
Primer were calculated from the equation: where V o is the column void volume, V e is the elution volume, and V c is the geometric column volume.

EMSA
EMSA for the SaDnaD variants was conducted using the protocol described previously for PriB [39]. In brief, radiolabeling of various lengths of ssDNA oligonucleotides was carried out with [γ 32 P]ATP (6000 Ci/mmol; PerkinElmer Life Sciences, Waltham, MA) and T4 polynucleotide kinase (Promega, Madison, WI, USA). Protein (0, 0.06, 0.12, 0.25, 0.5, 1, 2, 4, 8, and 16 μM; monomer) was incubated at 25°C for 30 min with 1.7 nM DNA substrates (dT20-65) in a total volume of 10 μL in 20 mM Tris-HCl (pH 8.0) and 100 mM NaCl. The resulting samples were mixed with gel-loading solution (0.25% bromophenol blue and 40% sucrose; w/v), resolved on a native 8% polyacrylamide gel (8.3 × 7.3 cm) at 4°C in TBE buffer for 1-1.5 h at 100 V, and were visualized by phosphorimaging. The phosphor storage plate was scanned, and the data for complex and free DNA bands were digitized for quantitative analysis. The ssDNAbinding ability for the protein was estimated using linear interpolation from the protein concentration that binds 50% of the input DNA [40]. Each [Protein] 50 was calculated as the average of at least three measurements ± S.D.

Fluorescence-quenching measurement
Fluorescence titrations were performed in a spectrofluorimeter (Hitachi F-2700; Hitachi High-Technologies, Tokyo, Japan) as described previously [41]. The excitation and emission of tryptophan fluorescence were detected at 295 and 340 nm, respectively. The protein solution (0.1 μM; tetramer) in 2 mL Tris-HCl buffer (20 mM Tris-HCl, and pH 8.0) containing 200 or 500 mM NaCl was titrated with increasing quantities of dT65 oligonucleotide. After the addition of ssDNA, the complex solution was equilibrated for 300 s until no fluorescence change could be observed. Tryptophan fluorescence quenching was used to detect and quantify protein-DNA interactions.

SPR
SPR was conducted using the protocol described previously for DnaC helicase [42].

Gold nanoparticle assay
The protein-protein interactions within SaDnaD-SaPriA and SaDnaD-SaDnaA were rapidly analyzed based on the intrinsic optical properties of the gold nanoparticles [43]. Cloning, protein expression, and purification of tag-free SaDnaD, SaDnaDY176A, and SaDnaD1-195 proteins To obtain proteins without a His tag, SaDnaD and SaDnaD1-195 were amplified through PCR and cloned in a pGEX-5X-1 vector (GE Healthcare Bio-Sciences, Piscataway, NJ, USA) by using the restriction sites EcoRI and XhoI. SaDnaDY176A mutant was generated using a Quik-Change Site-Directed Mutagenesis kit according to the manufacturer's protocol (Stratagene, LaJolla, CA). These expression plasmids were verified by DNA sequencing. Table 2 lists the primers utilized to construct these GST plasmids. E. coli BL21(DE3) cells were transformed with the expression vector, and overexpression of the proteins was induced through incubation with 1 mM of isopropyl thiogalactopyranoside Table 2. Primers used for construction of GST plasmids.

Oligonucleotide
Primer

Purification of SaDnaD
The gene SAAV1440 encoding for the putative DnaD was PCR-amplified using the genomic DNA of S. aureus subsp. aureus ED98 as template. This amplified gene was then ligated into the pET21e vector for protein expression. SaDnaD was heterologously overexpressed in E. coli and then purified from the soluble supernatant by Ni 2+ -affinity chromatography (S1 Fig). Pure protein was obtained in this single chromatographic step with an elution of Buffer B and dialyzed against a dialysis buffer (Buffer C). Approximately >10 mg of purified protein was obtained from 1 L of E. coli cell culture. The truncated SaDnaD proteins were also purified according to the same protocol as that for the wild-type protein, and the purification results were similar.

EMSA of SaDnaD
To investigate the length of nucleotides needed for the formation of the DnaD-ssDNA complex, as well as the ssDNA-binding ability of DnaD, we studied the binding of SaDnaD to dT20, dT25, dT35, dT45, dT55, dT60, and dT65 (Fig 1) with different protein concentrations using EMSA. When we incubated SaDnaD with dT20, no significant band shift was observed. This result indicates that SaDnaD could not form a stable complex with this homopolymer during electrophoresis (Fig 1A). Some smears were observed; thus, SaDnaD appeared to interact with dT20, but the ssDNA may be too short to form a stable complex with SaDnaD. In contrast to dT20, longer dT homopolymers, such as dT25-55 ( Fig 1B-1E), produced a significant band shift (C, complex). These findings indicate that the ssDNA-binding activity of SaDnaD is strong enough to form a stable protein-DNA complex in solution. Two different complexes for dT60 ( Fig 1F) and dT65 ( Fig 1G) were formed by SaDnaD.
Binding constants of SaDnaD-ssDNA complexes determined from EMSA Binding of SaDnaD to ssDNA of different lengths formed distinct complexes. To compare the binding abilities of SaDnaD to ssDNA of different lengths, the midpoint values for input ssDNA binding that were calculated from the titration curves of EMSA and the [Protein] 50 were quantified using linear interpolation from the protein concentration and are summarized in Table 3. As shown in Fig 1H, the DNA binding abilities of SaDnaD were length-dependent. The [SaDnaD] 50 for dT65 binding is 0.5 ± 0.1 μM, which is ninefold lower than that for dT25 binding (4.7 ± 0.8 μM). Thus, the protein-DNA contact for each complex of SaDnaD may not be similar.

C-terminal region of SaDnaD is crucial for ssDNA binding
Given that many conserved positively charged residues are located in the C-terminal domain of DnaD [35], the truncated SaDnaD proteins, namely, SaDnaD1-204 (the C-terminal 24 amino acid residues were removed), SaDnaD1-200, and SaDnaD1-195, were constructed and purified (S1 Fig) to investigate whether the C-terminal region is essential for ssDNA binding and SaDnaD oligomerization. The binding of SaDnaD1-195, SaDnaD1-200, and SaDnaD1-204

Oligomeric state of SaDnaD in solution
The analysis of purified SaDnaD protein (4 mg/mL) by gel filtration chromatography revealed a single peak with elution volume of 74.3 mL. Assuming that the shape and partial specific volume of SaDnaD are similar to the standard proteins, the native molecular mass of SaDnaD was estimated to be 107895 Da, which was calculated from a standard linear regression equation, K av = −0.3684 (logMw) + 2.2707 (Fig 2). The native molecular mass for SaDnaD is approximately four times the molecular mass of a SaDnaD monomer (~27 kDa). Thus, we conclude that SaDnaD in solution is a stable tetramer.

Fluorescence detection of SaDnaD and ssDNA interaction
We examined the quenching fluorescence intensity of tryptophan in SaDnaD upon addition of ssDNA. SaDnaD has three tryptophan residues, namely, Trp148, Trp184, and Trp219, allowing ssDNA binding analysis through tryptophan fluorescence quenching. The protein displayed strong intrinsic fluorescence with a peak wavelength of 340 nm when excited at 295 nm, which is consistent with tryptophan fluorescence. Upon the addition of ssDNA, fluorescence quenching of SaDnaD was observed. The intrinsic fluorescence was progressively quenched as dT65 was titrated into the SaDnaD solution, suggesting an interaction of SaDnaD with dT65 (Fig 3). Upon adding a saturating quantity of ssDNA in the presence of 200 and 500 mM NaCl, the intrinsic fluorescence at 340 nm was quenched by 75% and 65%, respectively. Using these fluorescence data, we calculated the binding stoichiometry between SaDnaD and ssDNA. The saturation curves of SaDnaD in the presence of 200 and 500 mM NaCl suggest that the binding is stoichiometric at 0.5 SaDnaD tetramer per 65-mer ssDNA if enough binding sites were present in the DNA for all SaDnaD molecules to bind. Therefore, the binding-site size of SaDnaD tetramer estimated from fluorescence quenching is approximately 32 nt (65 × 0.5 = 32.5). We also tested the fluorescence quenching of SaDnaD1-195, SaDnaD1-200, and SaDnaD1-204 by adding ssDNA. The ssDNA dT65 at the DNA-protein ratio of 1 only quenched <5%, <10%, and 20% of SaDnaD1-195, SaDnaD1-200, and SaDnaD1-204 fluorescence intensities, respectively. Thus, the ssDNA-binding abilities of SaDnaD1-195, SaDnaD1-200, and SaDnaD1-204 were significantly impaired and their ssDNA-binding site sizes were not estimated.

Characterization of SaDnaD bound to SaPriA or SaDnaA
B. subtilis DnaD-DnaA interaction is previously identified through the yeast two-hybrid analysis [26]. To gain insights into direct interactions and further quantitatively characterize whether the C-terminal domain of DnaD was involved in protein-protein interactions within PriA-DnaD or DnaA-DnaD, we provided experimental evidence using SPR to investigate the effect of various fragments on the ability of DnaD to bind to PriA or DnaA. PriA and DnaA were individually immobilized on a sensor chip (as a ligand), and the DnaD solution (as an analyte) was passed over the sensor chip in a microfluidic chamber. Fig 4 shows the SPR results at various DnaD concentrations. The K d values were calculated from the equilibrium binding isotherms using a simple binding model (a 1:1 Langmuir binding model). As shown in  Table 4, C-terminal deletion of DnaD resulted in decreased K d values for PriA and DnaA binding, indicating a crucial role for protein-protein interactions. DnaD1-195 was injected at increasing concentrations, but the binding response for PriA did not change; this result indicates that aa 196-228 is necessary for PriA binding in DnaD (Fig 4D) but not for DnaA binding (Fig 4F). Therefore, DnaD may bind to PriA in a different manner from that to DnaA.
To rapidly confirm whether SaDnaD1-195 can interact with SaDnaA and SaPriA, we carried out gold nanoparticle assays. As histidine-tagged proteins, SaDnaD1-195, SaPriA, and SaDnaA can be immobilized on commercialized Ni 2+ -NTA SAM nanoparticles. Protein-loaded  nanoparticles retain the same red color as the unmodified SAM-coated nanoparticles. However, the solution turns purple when gold nanoparticles aggregate, indicating the protein-protein interactions (Fig 5). The gold nanoparticle assay showed that the solution of SaDnaA-SaD-naD1-195 changed from red to purple (Fig 5A), whereas that of SaPriA-SaDnaD1-195 maintained the red color ( Fig 5B). Thus, the C-terminal region aa 196-228 in SaDnaD is relatively important for SaPriA binding, which is consistent with the SPR results.
SaDnaD can significantly stimulate the ATPase activity of SaPriA but SaDnaD1-195 cannot Gram-negative bacterial PriA is known as a poor helicase when acting alone in vitro [45]. E. coli PriA activity can be significantly stimulated by PriB and SSB [46,47,48]. Whether SaDnaD and SaDnaD1-195 can enhance SaPriA ATPase is unknown. SaPriA could hydrolyze ATP alone, and this ATPase activity was dramatically stimulated (twelvefold) in the presence of SaDnaD (S4 Fig). However, when acting with SaDnaD1-195, the stimulation of SaPriA ATPase was insignificant (only twofold). Thus, the C-terminal region of SaDnaD is important for the stimulation of SaPriA ATPase activity.
SaDnaDY176A significantly stimulated the ATPase activity of SaPriA as SaDnaD did In this study, we determined that the ATPase activity of PriA can be significantly stimulated via contact with the C-terminal region of DnaD (Fig 4). We further investigated whether the DNA binding ability of DnaD is related to the stimulation effect. The highly conserved DNAbinding motif of DnaD, YxxxIxxxW, has been identified [35]. The Y180A mutant protein of B. subtilis DnaD cannot bind DNA [35]. The same DNA-binding motif is also found in SaDnaD, and the residue Y180 in B. subtilis DnaD is Y176 in SaDnaD. To assess whether the DNA binding activity of DnaD is also involved in the stimulation of the ATPase activity of PriA, tag-free SaDnaDY176A mutant protein was produced using GST fusion and Factor Xa (S5 Fig). To exclude the possible effect of a His tag, tag-free SaDnaD and SaDnaD1-195 were also constructed and used in the ATPase assay for analysis. The stimulation effect of a tag-free SaDnaD Effect of SaDnaD, SaDnaD1-195, and SaDnaDY176A on the kinetic parameters of SaPriA ATPase We further determined the kinetic parameters of PriA ATPase in the presence or absence of DnaD. Given that DnaD can bind and may stabilize the dsDNA substrate, the SaDnaDY176A mutant protein was also used for this analysis to rule out any possible role of the DNA-binding involvement of DnaD. As shown in Fig 6, the ATP hydrolyzing reaction was insignificant when only PriA was added into the assay mixture. Under the same ATP concentration assay range, the kinetic parameters of SaPriA ATPase varied when SaDnaD, SaDnaD1-195, and SaD-naDY176A protein was individually added in the hydrolyzing reaction (Table 5). When acting with SaDnaD or SaDnaDY176A, the V max values of SaPriA ATPase increased fivefold, whereas the K m values were only slightly affected. The addition of SaDnaD1-195 to the hydrolyzing reaction induced only a minimal effect.

Discussion
S. aureus is a Gram-positive pathogen that exhibits a remarkable ability to develop antibiotic resistance [49,50,51,52,53,54]. Considering that PriA and DnaA-directed primosomes are required for bacterial DNA replication restart processes, these primosomes may be suitable targets for antibiotic development. Because PriA, DnaA, and DnaD are not found in mammals, inhibitors based on these proteins are potentially safe for human use. We found that SaDnaD1-195 can bind to DnaA and can form a tetramer, but it cannot interact with ssDNA and PriA. This binding information on SaDnaD is a prerequisite for new antibacterial drug development and for formulating any model of protein function in DNA replication and DNA replication restart.
In this study, we discovered that the primosomal DnaD protein, which is only found in the Gram-positive bacteria, can bind PriA helicase via the C-terminal region, and this interaction significantly stimulated the activity of PriA. PriA activity can also be stimulated by the Gramnegative E. coli PriB and SSB proteins [47,48]. For SSB, the 15 C-terminal amino acids are absolutely needed for PriA binding and stimulation. Moreover, the stimulation of PriA by the SSB C-terminus requires binding of SSB to ssDNA within the substrate [48]. For PriB, the stimulation of PriA by PriB needs to form a stable PriA-PriB-DNA complex. In addition, the ssDNAcontaining DNA substrate is required to simulate PriA by PriB [47]. These two stimulatory cases of PriA by PriB and SSB indicate that both protein-protein interaction and DNA-binding ability are important factors in simulating PriA. However, several lines of evidence indicate that the stimulatory mechanism of PriA by DnaD, PriB or SSB may differ. First, unlike PriB and SSB, DnaD is not an OB-fold protein, thus binding ssDNA differently [38,55]. Second, DnaD is found to bind dsDNA (but with lower affinity than ssDNA) [35], whereas PriB and SSB are not. Third, the DNA-binding mutant SaDnaDY176A still stimulated PriA activity as the wild-type SaDnaD did, whereas the DNA-binding mutants of PriB and SSB do not exhibit a stimulation effect for PriA. Fourth, although the C-terminal region of DnaD was also crucial for the PriA stimulation as the case in SSB, the amino acid residues in SSB and DnaD C-terminal region are quite different and the sequences are not similar. Fifth, the C-terminal region of DnaD is important both for DNA-and PriA-binding, whereas the ssDNA binding region is located at the Nterminal domain of SSB, not the C terminus [55]. Occupying of partially unwound intermediates of DNA unwinding reactions by SSB is known to prevent ssDNA reannealing and enhance the apparent processivity of more distributive helicases. If the DNA binding activity of DnaD plays no role in the activity stimulation of PriA, how can the protein-protein interactions within PriA-DnaD can conduct such effect? The results from our kinetic studies further reveal that PriA binding to DnaD did not significantly change the K m value. Thus, DnaD binding to PriA may not alter the ATP binding environment of PriA. Whether the conformation of PriA changes upon DnaD binding and whether the increased V max value of PriA ATPase for DnaD binding results from facilitating the product (ADP) release remains undiscovered. Roles of the N-terminal domain of DnaD have been well established. The structure and detailed functions of the C-terminal domain of DnaD are still poorly understood. The C-terminal region of DnaD was found to be crucial for both PriA and ssDNA binding, suggesting that these binding sites are overlapped on DnaD. Future studies should focus on whether the binding site for ssDNA on DnaD is necessary to overlap the binding site for PriA, because PriA (a monomer) and DnaD (a tetramer) have different oligomerization states. For example, only one monomer of the PriB dimer can interact with the DNA and its partner proteins [38,56]. The complex structures of DnaD are useful in helping us to understand the primosome assembly mechanisms.
Most DNA helicases of superfamily I and superfamily II are almost non-hexameric and have poor dsDNA unwinding activities when acting alone in vitro [45]. E. coli PriA helicase activity can be significantly stimulated by PriB and SSB. Determining whether DnaD can enhance the Gram-positive PriA helicase or the Gram-negative PriA helicase is important to understand deeply the role of DnaD in the primosome assembly. SPR results indicate that the binding sites on DnaD for PriA and ssDNA do not overlap with the binding site for DnaA (Fig  4), suggesting that the DnaD expression in cells may simultaneously work with DnaA in replication and with PriA in replication restart.