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.     

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.     

Overinitiation of chromosome replication in the Escherichia coli dnaAcos mutant depends on activation of oriC function by the dam gene product

The activity of DnaA protein, the initiator of chromosome replication in Escherichia coli , is regulated by adenine nucleotide binding; the ATP-bound form, not the ADP-bound form, is active. DnaAcos is a mutant protein that is insensitive to negative regulation by ADP. Initiation of chromosome replication occurs excessively in the dnaAcos mutant at 30°C, a restrictive temperature for growth. To determine the control factors that act independently of adenine nucleotide binding of DnaA, we analysed suppressors from the dnaAcos mutant isolated by Tn 5 insertion mutagenesis. Three of the suppressors carried Tn 5 in the aroK or aroB gene, the first two cistrons in the dam operon. Complementation tests revealed that the dam gene is responsible for the suppression. Over-replication of the chromosome was inhibited in the dnaAcos aroK ::Tn 5 double mutant, and initiation of chromosome replication in the dnaA ⁺ aroK ::Tn 5 mutant was partially inhibited. The aroK  (or B  )::Tn 5 cells contained DnaA molecules at a level similar to that in the parental aroBK  ⁺ strain. Moreover, dnaAcos suppression depended on the function of the seqA gene. Thus, Dam activity positively regulates initiation of chromosome replication in vivo . SeqA function seems to be distinguished from the control of DnaA protein by adenine nucleotide binding.     

DiaA, a novel DnaA-binding protein, ensures the timely initiation of Escherichia coli chromosome replication

The DnaA protein is the initiator of Escherichia coli chromosomal replication. In this study, we identify a novel DnaA-associating protein, DiaA, that is required for the timely initiation of replication during the cell cycle. DiaA promotes the growth of specific temperature-sensitive dnaA mutants and ensures stable minichromosome maintenance, whereas DiaA does not decrease the cellular DnaA content. A diaA::Tn5 mutation suppresses the cold-sensitive growth of an overinitiation type dnaA mutant independently of SeqA, a negative modulator of initiation. Flow cytometry analyses revealed that the timing of replication initiation is disrupted in the diaA mutant cells as well as wild-type cells with pBR322 expressing the diaA gene. Gel filtration and chemical cross-linking experiments showed that purified DiaA forms a stable homodimer. Immunoblotting analysis indicated that a single cell contains about 280 DiaA dimers. DiaA stimulates minichromosome replication in an in vitro system especially when the level of DnaA included is limited. Moreover, specific and direct binding between DnaA and DiaA was observed, which requires a DnaA N-terminal region. DiaA binds to both ATP- and ADP-bound forms of DnaA with a similar affinity. Thus, we conclude that DiaA is a novel DnaA-associating factor that is crucial to ensure the timely initiation of chromosomal replication.     

Reactivation of DnaA by DNA sequence-specific nucleotide exchange in vitro

In Escherichia coli, ATP-bound DnaA protein can initiate chromosomal replication. After initiation, DnaA-ATP is hydrolyzed by interactions with a complex containing a replicase subunit to yield the inactive ADP-DnaA. However, the mechanisms which regenerate ATP-DnaA from ADP-DnaA are not well understood. We report here that a 70-bp DNA segment promotes exchange of the DnaA-bound nucleotide in a sequence-specific manner, thus reactivating the initiation function of DnaA in vitro. This segment contains a typical DnaA-binding 9-mer motif, the DnaA box, and two DnaA box-like sequences. The presence and precise composition of these three motifs are required for the DnaA-reactivating activity, which suggests that a highly ordered complex which includes multimeric DnaA molecules is formed for isomerization of DnaA. We named this DNA segment DARS, for DnaA-reactivating sequence. The role of DARS in regulation of DnaA function in vivo is discussed.     

Escherichia coli DnaA protein: specific biochemical defects of mutant DnaAs reduce initiation frequency to suppress a temperature-sensitive dnaX mutation

The Escherichia coli dnaA73, dnaA721, and dnaA71 alleles, which encode A213D, R432L, T435K substitutions, respectively, were originally isolated as extragenic suppressors of a temperature-sensitive dnaX mutant. As the A213D substitution resides in a domain that functions in ATP binding and the R432L and T435K substitutions affect residues that recognize the DnaA box motif, they might be expected to reduce ATP and specific DNA binding, respectively. Therefore, a major objective was to quantify the biochemical defects of the mutant DnaAs to understand how the altered proteins suppress the temperature-sensitive phenotype of a dnaX mutant. A second purpose was to address the paradox that mutant proteins with substitutions of amino acids essential for recognition of the DnaA box motifs within the E. coli replication origin (oriC) may well be inactive in initiation, yet chromosomal dnaA mutants expressing DnaA proteins with the R432L and T435K substitutions are viable at temperatures from 30 to 39 degrees C. We show biochemically that mutant DnaAs carrying R432L and T435K substitutions fail to bind to the DnaA box sequence. The A213D mutant is sevenfold reduced in its affinity for ATP compared to wild-type DnaA, and its affinity for the DnaA box sequence is also reduced. However, the reduced activity of the A213D mutant in oriC plasmid replication appears to arise from a defect in DnaA oligomerization. Although the T435K mutant fails to bind to the DnaA box sequence, other results suggest that DnaA oligomerization stabilizes the binding of the mutant DnaA to oriC to support its partial activity in initiation in vitro. These results support a model that suppression of dnaX occurs by reducing the frequency of initiation to a manageable level for the mutant DnaX so that viability is maintained.     

DnaAcos hyperinitiates by circumventing regulatory pathways that control the frequency of initiation in Escherichia coli

Mutants of dnaAcos are inviable at 30°C because DnaAcos hyperinitiates, leading to new replication forks that apparently collide from behind with stalled forks, thereby generating lethal double-strand breaks. By comparison, an elevated level of DnaA also induces extra initiations, but lethality occurs only in strains defective in repairing double-strand breaks. To explore the model that the chromosomal level of DnaAcos, or the increased abundance of DnaA, increases initiation frequency by, escaping or overcoming pathways that control initiation, respectively, we developed a genetic selection and identified seqA , datA , dnaN and hda , which function in pathways that either act at oriC or modulate DnaA activity. To assess each pathway's relative effectiveness, we used genetically inactivated strains, and quantified initiation frequency after elevating the level of DnaA. The results indicate that the hda -dependent pathway has a stronger effect on initiation than pathways involving seqA and datA . Testing the model that DnaAcos overinitiates because it fails to respond to one or more regulatory mechanisms, we show that dnaAcos is unresponsive to hda and dnaN , which encodes the β clamp, and also datA , a locus proposed to titer excess DnaA. These results explain how DnaAcos hyperinitiates to interfere with viability.     

Alteration in the contents of unsaturated fatty acids in dnaA mutants of Escherichia coli

DnaA protein, the initiator of chromosomal DNA replication in Escherichia coli , has a high affinity for acidic phospholipids containing unsaturated fatty acids. We have examined here the fatty acid composition of phospholipids in dnaA mutants. A temperature-sensitive dnaA46 mutant showed a lower level of unsaturation of fatty acids (ratio of unsaturated to saturated fatty acids) at 42°C (non-permissive temperature) and at 37°C (semi-permissive temperature), but not at 28°C (permissive temperature), compared with the wild-type strain. Plasmid complementation analysis revealed that the dnaA46 mutation is responsible for the phenotype. Other temperature-sensitive dnaA mutants showed similar results. On the other hand, a cold-sensitive dnaAcos mutant, in which overinitiation of DNA replication occurs at low temperature (28°C), showed a higher level of unsaturation of fatty acids at 28°C. Based on these observations, we discuss the role of phospholipids in the regulation of the activity of DnaA protein.     

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.     

Site-directed mutational analysis of DnaA protein, the initiator of chromosomal DNA replication in E. coli

DnaA protein, the initiator for chromosomal DNA replication in Escherichia coli, has various activities, such as oligomerization (DnaA-DnaA interaction), ATP-binding, ATPase activity and membrane-binding. Site-directed mutational analyses have revealed not only the amino acid residues that are essential for these activities but also the functions of these activities. Following is a summary of the functions and regulatory mechanisms of DnaA protein in the initiation of chromosomal DNA replication. ATP-bound DnaA protein, but not other forms of the protein binds to the origin of DNA replication and forms oligomers to open-up the duplex DNA. This oligomerization is mediated by a DnaA-DnaA interaction through the N-terminal region of the protein. After initiation of DNA replication, the ATPase activity of DnaA protein is stimulated and DnaA protein is inactivated to the ADP-bound form to suppress the re-initiation of DNA replication. DnaA protein binds to acidic phospholipids through an ionic interaction between basic amino acid residues of the protein and acidic residues of phospholipids. This interaction seems to be involved in the re-activation of DnaA protein (from the ADP-bound form to the ATP-bound form) to initiate DNA replication after the appropriate interval.     

Stable nucleotide binding to DnaA requires a specific glutamic acid residue within the AAA+ box II motif

In complex with ATP, but not ADP, DnaA protein multimers unwind a specific region of duplex DNA within the chromosomal replication origin, oriC, triggering a series of reactions that result in initiation of DNA replication. Following replication initiation, ATP hydrolysis, which is coupled to DNA replication, results in the generation of initiation-incompetent ADP-DnaA. Suppression of overinitiation of replication requires that ADP-DnaA complexes be stably maintained until the next round of replication. Thus, the functional and structural requirements that ensure stable nucleotide binding to DnaA are crucial for proper regulation of replication. Here, we demonstrate that Glu143 of DnaA, located within the AAA+ box II N-linker motif, is a key residue involved in stable nucleotide binding. A Glu143 substitution variant of DnaA (DnaA E143A) bound to ADP on ice with an affinity similar to wild-type DnaA, but the resultant ADP-DnaA E143A complex was more labile at 37 °C than wild-type ADP-DnaA complexes. Consistent with this, conversion of ADP-DnaA E143A to ATP-DnaA E143A was stimulated at 37°C in the presence of ATP, which also stimulated replication of a minichromosome in an in vitro reconstitution reaction. Expression of DnaA E143A in vivo inhibited cell growth in an oriC-dependent manner, suggesting that DnaA E143A caused over-initiation of replication, consistent with the in vitro results. Glu is a highly conserved residue at the corresponding position of γ-proteobacterial DnaA orthologs. Our finding of the novel role for the DnaA N-linker region may represent a conserved function of this motif among those DnaA orthologs.     

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.     

Mutant DnaAs of Escherichia coli that are refractory to negative control

DnaA is the initiator of DNA replication in bacteria. A mutant DnaA named DnaAcos is unusual because it is refractory to negative regulation. We developed a genetic method to isolate other mutant DnaAs that circumvent regulation to extend our understanding of mechanisms that control replication initiation. Like DnaAcos, one mutant bearing a tyrosine substitution for histidine 202 (H202Y) withstands the regulation exerted by datA, hda and dnaN (β clamp), and both DnaAcos and H202Y resist inhibition by the Hda-β clamp complex in vitro. Other mutant DnaAs carrying G79D, E244K, V303M or E445K substitutions are either only partially sensitive or refractory to inhibition by the Hda-β clamp complex in vitro but are responsive to hda expression in vivo. All mutant DnaAs remain able to interact directly with Hda. Of interest, both DnaAcos and DnaAE244K bind more avidly to Hda. These mutants, by sequestrating Hda, may limit its availability to regulate other DnaA molecules, which remain active to induce extra rounds of DNA replication. Other evidence suggests that a mutant bearing a V292M substitution hyperinitiates by escaping the effect of an unknown regulatory factor. Together, our results provide new insight into the mechanisms that regulate replication initiation in Escherichia coli.     

Functional interplay between the Bacillus subtilis DnaD and DnaB proteins essential for initiation and re-initiation of DNA replication

Initiation and re-initiation of chromosomal DNA replication in bacteria rely on divergent multiprotein assemblies, which direct the functional delivery of the replicative helicase on single-stranded DNA (ssDNA) at specific sites. These two processes are triggered either at the single chromosomal origin oriC or at arrested forks by the conserved DnaA and PriA proteins respectively. In Bacillus subtilis, these two pathways further require the three essential proteins DnaB, DnaD and DnaI, restrictively encoded in Gram positive bacteria of low GC content. We have recently shown that DnaI and DnaB act as a pair of loaders of the DnaC replicative helicase. The role of DnaD appeared more enigmatic. It was previously shown to interact with DnaA and to display weak ssDNA binding activity. Here, we report that purified DnaD can interact physically with PriA and with DnaB. We show that the lethality of the temperature-sensitive dnaD23 mutant can be suppressed by different DnaB point mutants, which were found to be identical to the suppressors of priA null mutants. The DnaD23 protein displays lower ssDNA binding activity than DnaD. Conversely, the DnaB75 protein, the main dnaD23 suppressor, has gained affinity for ssDNA. Finally, we observed that this interplay between DnaD and DnaB is crucial for their concerted interaction with SSB-coated ssDNA, which is the expected substrate for the loading of the replicative helicase in vivo. Altogether, these results highlight the need for both DnaD and DnaB to interact individually and together with ssDNA during the early stages of initiation and re-initiation of chromosomal DNA replication. They also point at a main structural role of DnaD in the multiprotein assemblies built during these two essential processes.     

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.     

In vitro roles of Escbericbia coli DnaJ and DnaK heat shock proteins in the replication of oriC plasmids

Summary Heat shock proteins have been shown to be involved in many cellular processes in procaryotic and eucaryotic cells. Using an in vitro DNA replication assay, we show that DNA synthesis initiated at the chromosomal origin of replication of Escherichia coli (oriC) is considerably reduced in enzyme extracts isolated from cells bearing mutations in the dnaK and dnaJ genes, which code for heat shock proteins. Furthermore, unlike DNA synthesis in wild-type extracts, residual DNA synthesis in dnaK and dnaJ extracts is thermosensitive. Although thermosensitivity can be complemented by the addition of DnaK and DnaJ proteins, restoration of near wild-type replication levels requires supplementary quantities of purified DnaA protein. This key DNA synthesis initiator protein is shown to be adsorbed to DnaK affinity columns. These results suggest that at least one of the heat shock proteins, DnaK, exerts an effect on the initiation of DNA synthesis at the level of DnaA protein activity. However, our observation of normal oriC plasmid transformation ratios and concentrations in heat shock mutants at permissive temperatures would suggest that heat shock proteins play a role in DNA replication mainly at high temperatures or under other stressful growth conditions.