Two oppositely oriented arrays of low-affinity recognition sites in oriC guide progressive binding of DnaA during Escherichia coli pre-RC assembly

The onset of chromosomal DNA replication requires highly precise and reproducible interactions between initiator proteins and replication origins to assemble a pre-replicative complex (pre-RC) that unwinds the DNA duplex. In bacteria, initiator protein DnaA, bound to specific high- and low-affinity recognition sites within the unique oriC locus, comprises the pre-RC, but how complex assembly is choreographed to ensure precise initiation timing during the cell cycle is not well understood. In this study, we present evidence that higher-order DnaA structures are formed at oriC when DnaA monomers are closely positioned on the same face of the DNA helix by interaction with two oppositely oriented essential arrays of closely spaced low-affinity DnaA binding sites. As DnaA levels increase, peripheral high-affinity anchor sites begin cooperative loading of the arrays, which is extended by sequential binding of additional DnaA monomers resulting in growth of the complexes towards the centre of oriC. We suggest that this polarized assembly of unique DnaA oligomers within oriC plays an important role in mediating pre-RC activity and may be a feature found in all bacterial replication origins.     

Characterization of the oriC region of Mycobacterium smegmatis.

A 3.5-kb DNA fragment containing the dnaA region of Mycobacterium smegmatis has been hypothesized to be the chromosomal origin of replication or oriC (M. Rajagopalan et al., J. Bacteriol. 177:6527-6535, 1995). This region included the rpmH gene, the dnaA gene, and a major portion of the dnaN gene as well as the rpmH-dnaA and dnaA-dnaN intergenic regions. Deletion analyses of this region revealed that a 531-bp DNA fragment from the dnaA-dnaN intergenic region was sufficient to exhibit oriC activity, while a 495-bp fragment from the same region failed to exhibit oriC activity. The oriC activities of plasmids containing the 531-bp sequence was less than the activities of those containing the entire dnaA region, suggesting that the regions flanking the 531-bp sequence stimulated oriC activity. The 531-bp region contained several putative nine-nucleotide DnaA-protein recognition sequences [TT(G/C)TCCACA] and a single 11-nucleotide AT-rich cluster. Replacement of adenine with guanine at position 9 in five of the putative DnaA boxes decreased oriC activity. Mutations at other positions in two of the DnaA boxes also decreased oriC activity. Deletion of the 11-nucleotide AT-rich cluster completely abolished oriC activity. These data indicate that the designated DnaA boxes and the AT-rich cluster of the M. smegmatis dnaA-dnaN intergenic region are essential for oriC activity. We suggest that M. smegmatis oriC replication could involve interactions of the DnaA protein with the putative DnaA boxes as well as with the AT-rich cluster.     

Mutant DnaA proteins defective in duplex opening of oriC, the origin of chromosomal DNA replication in Escherichia coli

We characterized three mutant DnaA proteins with an amino acid substitution of R334H, R342H and E361G that renders chromosomal replication cold (20 degrees C) sensitive. Each mutant DnaA protein was highly purified from overproducers, and replication activities were assayed in in vitro oriC replication systems. At 30 degrees C, all three mutant proteins exhibited specific activity similar to that seen with the wild-type protein, whereas at 20 degrees C, there was much less activity in a replication system using a crude replicative extract. Regarding the affinity for ATP, the dissociation rate of bound ATP and binding to oriC DNA, the three mutant DnaA proteins showed a capacity indistinguishable from that of the wild-type DnaA protein. Activity for oriC DNA unwinding of the two mutant DnaA proteins, R334H and R342H, was more sensitive to low temperature than that of the wild-type DnaA protein. We propose that R334H and R342H have a defect in their potential to unwind oriC DNA at low temperatures, the result being the cold-sensitive phenotype in oriC DNA replication. The two amino acid residues of DnaA protein, located in a motif homologous to that of NtrC protein, may play a role in the formation of the open complex. The E361 residue may be related to interaction with another protein present in a crude cell extract.     

The box VII motif of Escherichia coli DnaA protein is required for DnaA oligomerization at the E. coli replication origin

Escherichia coli DnaA protein initiates DNA replication from the chromosomal origin, oriC, and regulates the frequency of this process. Structure-function studies indicate that the replication initiator comprises four domains. Based on the structural similarity of Aquifex aeolicus DnaA to other AAA+ proteins that are oligomeric, it was proposed that Domain III functions in oligomerization at oriC (Erzberger, J. P., Pirruccello, M. M., and Berger, J. M. (2002) EMBO J. 21, 4763-4773). Because the Box VII motif within Domain III is conserved among DnaA homologues and may function in oligomerization, we substituted conserved Box VII amino acids of E. coli DnaA with alanine by site-directed mutagenesis to examine the role of this motif. All mutant proteins are inactive in initiation from oriC in vivo and in vitro, but they support RK2 plasmid DNA replication in vivo. Thus, RK2 requires only a subset of DnaA functions for plasmid DNA replication. Biochemical studies on a mutant DnaA carrying an alanine substitution at arginine 281 (R281A) in Box VII show that it is inactive in in vitro replication of an oriC plasmid, but this defect is not from the failure to bind to ATP, DnaB in the DnaB-DnaC complex, or oriC. Because the mutant DnaA is also active in the strand opening of oriC, whereas DnaB fails to bind to this unwound region, the open structure is insufficient by itself to load DnaB helicase. Our results show that the mutant fails to form a stable oligomeric DnaA-oriC complex, which is required for the loading of DnaB.     

A common mechanism for the ATP-DnaA-dependent formation of open complexes at the replication origin

Initiation of chromosomal replication and its cell cycle-coordinated regulation bear crucial and fundamental mechanisms in most cellular organisms. Escherichia coli DnaA protein forms a homomultimeric complex with the replication origin (oriC). ATP-DnaA multimers unwind the duplex within the oriC unwinding element (DUE). In this study, structural analyses suggested that several residues exposed in the central pore of the putative structure of DnaA multimers could be important for unwinding. Using mutation analyses, we found that, of these candidate residues, DnaA Val-211 and Arg-245 are prerequisites for initiation in vivo and in vitro. Whereas DnaA V211A and R245A proteins retained normal affinities for ATP/ADP and DNA and activity for the ATP-specific conformational change of the initiation complex in vitro, oriC complexes of these mutant proteins were inactive in DUE unwinding and in binding to the single-stranded DUE. Unlike oriC complexes including ADP-DnaA or the mutant DnaA, ATP-DnaA-oriC complexes specifically bound the upper strand of single-stranded DUE. Specific T-rich sequences within the strand were required for binding. The corresponding conserved residues of the DnaA ortholog in Thermotoga maritima, an ancient eubacterium, were also required for DUE unwinding, consistent with the idea that the mechanism and regulation for DUE unwinding can be evolutionarily conserved. These findings provide novel insights into mechanisms for pore-mediated origin unwinding, ATP/ADP-dependent regulation, and helicase loading of the initiation complex.     

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.     

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.     

Drunken-cell footprints: nuclease treatment of ethanol-permeabilized bacteria reveals an initiation-like nucleoprotein complex in stationary phase replication origins.

The nucleoprotein complex formed on oriC, the Escherichia coli replication origin, is dynamic. During the cell cycle, high levels of the initiator DnaA and a bending protein, IHF, bind to oriC at the time of initiation of DNA replication, while binding of Fis, another bending protein, is reduced. In order to probe the structure of nucleoprotein complexes at oriC in more detail, we have developed an in situ footprinting method, termed drunken-cell footprinting, that allows enzymatic DNA modifying reagents access to intracellular nucleoprotein complexes in E.coli, after a brief exposure to ethanol. With this method, we observed in situ binding of Fis to oriC in exponentially growing cells, and binding of IHF to oriC in stationary cells, using DNase I and Bst NI endonuclease, respectively. Increased binding of DnaA to oriC in stationary phase was also noted. Because binding of DnaA and IHF results in unwinding of oriC in vitro, P1 endonuclease was used to probe for intracellular unwinding of oriC. P1 cleavage sites, localized within the 13mer unwinding region of oriC ', were dramatically enhanced in stationary phase on wild-type origins, but not on mutant versions of oriC unable to unwind. These observations suggest that most oriC copies become unwound during stationary phase, forming an initiation-like nucleoprotein complex.     

Formation of an ATP-DnaA-specific initiation complex requires DnaA Arginine 285, a conserved motif in the AAA+ protein family

Escherichia coli DnaA protein, a member of the AAA+ superfamily, initiates replication from the chromosomal origin oriC in an ATP-dependent manner. Nucleoprotein complex formed on oriC with the ATP-DnaA multimer but not the ADP-DnaA multimer is competent to unwind the oriC duplex. The oriC region contains ATP-DnaA-specific binding sites termed I2 and I3, which stimulate ATP-DnaA-dependent oriC unwinding. In this study, we show that the DnaA R285A mutant is inactive for oriC replication in vivo and in vitro and that the mutation is associated with specific defects in oriC unwinding. In contrast, activities of DnaA R285A are sustained in binding to the typical DnaA boxes and to ATP and ADP, formation of multimeric complexes on oriC, and loading of the DnaB helicase onto single-stranded DNA. Footprint analysis of the DnaA-oriC complex reveals that the ATP form of DnaA R285A does not interact with ATP-DnaA-specific binding sites such as the I sites. A subgroup of DnaA molecules in the oriC complex must contain the Arg-285 residue for initiation. Sequence and structural analyses suggest that the DnaA Arg-285 residue is an arginine finger, an AAA+ family-specific motif that recognizes ATP bound to an adjacent subunit in a multimeric complex. In the context of these and previous results, the DnaA Arg-285 residue is proposed to play a unique role in the ATP-dependent conformational activation of an initial complex by recognizing ATP bound to DnaA and by modulating the structure of the DnaA multimer to allow interaction with ATP-DnaA-specific binding sites in the complex.     

The requirement of IHF protein for extrachromosomal replication of the Escherichia coli oriC in a mutant deficient in DNA polymerase I activity

It is shown here that plasmids containing the replication origin of Escherichia coli (oriC) cannot replicate in an extrachromosomal state in E. coli cells with the polA1hip3 double mutation. This E. coli mutant is deficient in the polymerizing function of DNA polymerase I (Pol I) and is unable to produce functional IHF protein. The inability of the oriC minichromosomes to replicate in the absence of IHF is dependent on the absence of Pol I; cells with the polA+himA- or polA+hip- mutation, which are deficient in the alpha and beta subunits of the IHF heterodimer, respectively, can support replication of the oriC replicons. We propose that IHF-deficient cells utilize an alternative pathway of the DNA replication in which Pol I is required. In vitro DNA binding assays revealed that the IHF binding site resides between the oriC coordinates 110 and 122 and is adjacent to the DnaA "box" 1. Within the area protected by IHF we found at least 1 out of 11 GATC methylation sites present in oriC. The consequences of lack of IHF protein binding to the oriC and the indirect effects of the IHF deficiency on the oriC replication are discussed.     

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.     

An essential tryptophan of Escherichia coli DnaA protein functions in oligomerization at the E. coli replication origin

In the initiation of bacterial DNA replication, DnaA protein recruits DnaB helicase to the chromosomal origin, oriC, leading to the assemble of the replication fork machinery at this site. Because a region near the N terminus of DnaA is required for self-oligomerization and the loading of DnaB helicase at oriC, we asked if these functions are separable or interdependent by substituting many conserved amino acids in this region with alanine to identify essential residues. We show that alanine substitutions of leucine 3, phenylalanine 46, and leucine 62 do not affect DnaA function in initiation. In contrast, we find on characterization of a mutant DnaA that tryptophan 6 is essential for DnaA function because its substitution by alanine abrogates self-oligomerization, resulting in the failure to load DnaB at oriC. These results indicate that DnaA bound to oriC forms a specific oligomeric structure, which is required to load DnaB helicase.     

The exceptionally tight affinity of DnaA for ATP/ADP requires a unique aspartic acid residue in the AAA+ sensor 1 motif

Escherichia coli DnaA, an AAA+ superfamily protein, initiates chromosomal replication in an ATP-binding-dependent manner. Although DnaA has conserved Walker A/B motifs, it binds adenine nucleotides 10- to 100-fold more tightly than do many other AAA+ proteins. This study shows that the DnaA Asp-269 residue, located in the sensor 1 motif, plays a specific role in supporting high-affinity ATP/ADP binding. The affinity of the DnaA D269A mutant for ATP/ADP is at least 10- to 100-fold reduced compared with that of the wild-type and DnaA R270A proteins. In contrast, the abilities of DnaA D269A to bind a typical DnaA box, unwind oriC duplex in the presence of elevated concentrations of ATP, load DnaB onto DNA and support minichromosomal replication in a reconstituted system are retained. Whereas the acidic Asp residue is highly conserved among eubacterial DnaA homologues, the corresponding residue in many other AAA+ proteins is Asn/Thr and in some AAA+ proteins these neutral residues are essential for ATP hydrolysis but not ATP binding. As the intrinsic ATPase activity of DnaA is extremely weak, this study reveals a novel and specific function for the sensor 1 motif in tight ATP/ADP binding, one that depends on the alternate key residue Asp.     

Localized DNA melting and structural pertubations in the origin of replication, oriC, of Escherichia coli in vitro and in vivo.

The leftmost region of the Escherichia coli origin of DNA replication (oriC) contains three tandemly repeated AT-rich 13mers which have been shown to become single-stranded during the early stages of initiation in vitro. Melting is induced by the ATP form of DnaA, the initiator protein of DNA replication. KMnO4 was used to probe for single-stranded regions and altered DNA conformation during the initiation of DNA replication at oriC in vitro and in vivo. Unpairing in the AT-rich 13mer region is thermodynamically stable even in the absence of DnaA protein, but only when divalent cations are omitted from the reaction. In the presence of Mg2+, oriC melting is strictly DnaA dependent. The sensitive region is distinct from that detected in the absence of DnaA as it is located further to the left within the minimal origin. In addition, the DNA is severely distorted between the three 13mers and the IHF binding site in oriC. A change of conformation can also be observed during the initiation of DNA replication in vivo. This is the first in vivo evidence for a structural change at the 13mers during initiation complex formation.     

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.     

The bacteriophage lambda DNA replication protein P inhibits the oriC DNA- and ATP-binding functions of the DNA replication initiator protein DnaA of Escherichia coli

Under the condition of expression of lambda P protein at lethal level, the oriC DNA-binding activity is significantly affected in wild-type E. coli but not in the rpl mutant. In purified system, the lambda P protein inhibits the binding of both oriC DNA and ATP to the wild-type DnaA protein but not to the rpl DnaA protein. We conclude that the lambda P protein inhibits the binding of oriC DNA and ATP to the wild-type DnaA protein, which causes the inhibition of host DNA synthesis initiation that ultimately leads to bacterial death. A possible beneficial effect of this interaction of lambda P protein with E. coli DNA initiator protein DnaA for phage DNA replication has been proposed.