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

The DnaA N-terminal domain interacts with Hda to facilitate replicase clamp-mediated inactivation of DnaA

DnaA activity for replication initiation of the Escherichia coli chromosome is negatively regulated by feedback from the DNA-loaded form of the replicase clamp. In this process, called RIDA (regulatory inactivation of DnaA), ATP-bound DnaA transiently assembles into a complex consisting of Hda and the DNA-clamp, which promotes inter-AAA+ domain association between Hda and DnaA and stimulates hydrolysis of DnaA-bound ATP, producing inactive ADP-DnaA. Using a truncated DnaA mutant, we previously demonstrated that the DnaA N-terminal domain is involved in RIDA. However, the precise role of the N-terminal domain in RIDA has remained largely unclear. Here, we used an in vitro reconstituted system to demonstrate that the Asn-44 residue in the N-terminal domain of DnaA is crucial for RIDA but not for replication initiation. Moreover, an assay termed PDAX (pull-down after cross-linking) revealed an unstable interaction between a DnaA-N44A mutant and Hda. In vivo, this mutant exhibited an increase in the cellular level of ATP-bound DnaA. These results establish a model in which interaction between DnaA Asn-44 and Hda stabilizes the association between the AAA+ domains of DnaA and Hda to facilitate DnaA-ATP hydrolysis during RIDA.

Quantitative analysis of the mechanism of DNA binding by Bacillus DnaA protein

DnaA protein has the sole responsibility of initiating a new round of DNA replication in prokaryotic organisms. It recognizes the origin of DNA replication, and initiates chromosomal DNA replication in the bacterial genome. In Gram-negative Escherichia coli, a large number of DnaA molecules bind to specific DNA sequences (known as DnaA boxes) in the origin of DNA replication, oriC, leading to the activation of the origin. We have cloned, expressed, and purified full-length DnaA protein in large quantity from Gram-positive pathogen Bacillus anthracis (DnaA(BA)). DnaA(BA) was a highly soluble monomeric protein making it amenable to quantitative analysis of its origin recognition mechanisms. DnaA(BA) bound DnaA boxes with widely divergent affinities in sequence and ATP-dependent manner. In the presence of ATP, the K(D) ranged from 3.8 × 10(-8) M for a specific DnaA box sequence to 4.1 × 10(-7) M for a non-specific DNA sequence and decreased significantly in the presence of ADP. Thermodynamic analyses of temperature and salt dependence of DNA binding indicated that hydrophobic (entropic) and ionic bonds contributed to the DnaA(BA)·DNA complex formation. DnaA(BA) had a DNA-dependent ATPase activity. DNA sequences acted as positive effectors and modulated the rate (V(max)) of ATP hydrolysis without any significant change in ATP binding affinity.

The intrinsic ATPase activity of Mycobacterium tuberculosis DnaA promotes rapid oligomerization of DnaA on oriC

Oligomerization of the initiator protein, DnaA, on the origin of replication (oriC) is crucial for initiation of DNA replication. Studies in Escherichia coli (Gram-negative) have revealed that binding of DnaA to ATP, but not hydrolysis of ATP, is sufficient to promote DnaA binding, oligomerization and DNA strand separation. To begin understanding the initial events involved in the initiation of DNA replication in Mycobacterium tuberculosis (Gram-positive), we investigated interactions of M. tuberculosis DnaA (DnaA(TB)) with oriC using surface plasmon resonance in the presence of ATP and ADP. We provide evidence that, in contrast to what is observed in E. coli, ATPase activity of DnaA(TB) promoted rapid oligomerization on oriC. In support, we found that a recombinant mutant DnaA(TB) proficient in binding to ATP, but deficient in ATPase activity, did not oligomerize as rapidly. The corresponding mutation in the dnaA gene of M. tuberculosis resulted in non-viability, presumably due to a defect in oriC-DnaA interactions. Dimethy sulphate (DMS) footprinting experiments revealed that DnaA(TB) bound to DnaA boxes similarly with ATP or ADP. DnaA(TB) binding to individual DnaA boxes revealed that rapid oligomerization on oriC is triggered only after the initial interaction of DnaA with individual DnaA boxes. We propose that ATPase activity enables the DnaA protomers on oriC to rapidly form oligomeric complexes competent for replication initiation.

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.

Protein associations in DnaA-ATP hydrolysis mediated by the Hda-replicase clamp complex

In Escherichia coli, the activity of ATP-bound DnaA protein in initiating chromosomal replication is negatively controlled in a replication-coordinated manner. The RIDA (regulatory inactivation of DnaA) system promotes DnaA-ATP hydrolysis to produce the inactivated form DnaA-ADP in a manner depending on the Hda protein and the DNA-loaded form of the beta-sliding clamp, a subunit of the replicase holoenzyme. A highly functional form of Hda was purified and shown to form a homodimer in solution, and two Hda dimers were found to associate with a single clamp molecule. Purified mutant Hda proteins were used in a staged in vitro RIDA system followed by a pull-down assay to show that Hda-clamp binding is a prerequisite for DnaA-ATP hydrolysis and that binding is mediated by an Hda N-terminal motif. Arg(168) in the AAA(+) Box VII motif of Hda plays a role in stable homodimer formation and in DnaA-ATP hydrolysis, but not in clamp binding. Furthermore, the DnaA N-terminal domain is required for the functional interaction of DnaA with the Hda-clamp complex. Single cells contain approximately 50 Hda dimers, consistent with the results of in vitro experiments. These findings and the features of AAA(+) proteins, including DnaA, suggest the following model. DnaA-ATP is hydrolyzed at a binding interface between the AAA(+) domains of DnaA and Hda; the DnaA N-terminal domain supports this interaction; and the interaction of DnaA-ATP with the Hda-clamp complex occurs in a catalytic mode.

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.

New roles for conserved regions within a sigma 54-dependent enhancer-binding protein

23 amino acid substitutions were made in the C7 and C3 regions of pspFDeltaHTH, a protein required to convert sigma(54) closed promoter complexes to open complexes. These mutants were assayed for transcriptional competence, for the ability to hydrolyze ATP, for their multimerization state, and for their ability to interact with sigma(54) and its holoenzyme. C7 region mutants caused the protein to assume a compact form. This property could be mimicked by the addition of ATP, implying that compaction via C7 and ATP is part of the activation process. A number of C3 mutants were important for energy coupling, as indicated previously for several members of this activator family (, ). However, a patch within C3 influenced oligomerization. The C3 region was especially important in interacting with sigma(54) during the transition state but not important in inducing sigma(54) holoenzyme to engage the nontemplate strand of the promoter. It is proposed that both regions contain deterrent functions that prevent premature activation. Overall, the results imply unexpected roles for the C7 and C3 regions of this protein family during promoter activation.

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.

Residues within the N-terminal domain of human topoisomerase I play a direct role in relaxation

All eukaryotic forms of DNA topoisomerase I contain an extensive and highly charged N-terminal domain. This domain contains several nuclear localization sequences and is essential for in vivo function of the enzyme. However, so far no direct function of the N-terminal domain in the in vitro topoisomerase I reaction has been reported. In this study we have compared the in vitro activities of a truncated form of human topoisomerase I lacking amino acids 1-206 (p67) with the full-length enzyme (p91). Using these enzyme forms, we have identified for the first time a direct role of residues within the N-terminal domain in modulating topoisomerase I catalysis, as revealed by significant differences between p67 and p91 in DNA binding, cleavage, strand rotation, and ligation. A comparison with previously published studies showing no effect of deleting the first 174 or 190 amino acids of topoisomerase I (Stewart, L., Ireton, G. C., and Champoux, J. J. (1999) J. Biol. Chem. 274, 32950-32960; Bronstein, I. B., Wynne-Jones, A., Sukhanova, A., Fleury, F., Ianoul, A., Holden, J. A., Alix, A. J., Dodson, G. G., Jardillier, J. C., Nabiev, I., and Wilkinson, A. J. (1999) Anticancer Res. 19, 317-327) suggests a pivotal role of amino acids 191-206 in catalysis. Taken together the presented data indicate that at least part(s) of the N-terminal domain regulate(s) enzyme/DNA dynamics during relaxation most probably by controlling non-covalent DNA binding downstream of the cleavage site either directly or by coordinating DNA contacts by other parts of the enzyme.

DNA replication-coupled inactivation of DnaA protein in vitro: a role for DnaA arginine-334 of the AAA+ Box VIII motif in ATP hydrolysis

The DnaA protein, which initiates chromosomal replication in Escherichia coli, is negatively regulated by both the sliding clamp of DNA polymerase III holoenzyme and the IdaB protein. We have found that, when the amount of minichromosome is limited in an in vitro replication system, minichromosomal replication-stimulated hydrolysis of DnaA-bound ATP yields the ADP-bound inactive form. The number of sliding clamps formed during replication was at least five per minichromosome, which is 2.7-fold higher than the number formed during incubation without replication. These results support the notion that coupling of DnaA-ATP hydrolysis to DNA replication is the outcome of enhanced clamp formation. We have also found that the amino acid substitution R334H in DnaA severely inhibits the hydrolysis of bound ATP in vitro. Whereas ATP bound to wild-type DnaA is hydrolysed in a DNA-dependent intrinsic manner or in a sliding clamp-dependent manner, ATP bound to DnaA R334H protein was resistant to hydrolysis under the same conditions. This arginine residue may be located in the vicinity where ATP binds, and therefore may play an essential role in ATP hydrolysis. This residue is highly conserved among DnaA homologues and also in the Box VIII motif of the AAA+ protein family.