DNA gyrase activity regulates DnaA‐dependent replication initiation in Bacillus subtilis

In bacteria, initiation of DNA replication requires the DnaA protein. Regulation of DnaA association and activity at the origin of replication, oriC, is the predominant mechanism of replication initiation control. One key feature known to be generally important for replication is DNA topology. Although there have been some suggestions that topology may impact replication initiation, whether this mechanism regulates DnaA‐mediated replication initiation is unclear. We found that the essential topoisomerase, DNA gyrase, is required for both proper binding of DnaA to oriC as well as control of initiation frequency in Bacillus subtilis. Furthermore, we found that the regulatory activity of gyrase in initiation is specific to DnaA and oriC. Cells initiating replication from a DnaA‐independent origin, oriN, are largely resistant to gyrase inhibition by novobiocin, even at concentrations that compromise survival by up to four orders of magnitude in oriC cells. Furthermore, inhibition of gyrase does not impact initiation frequency in oriN cells. Additionally, deletion or overexpression of the DnaA regulator, YabA, significantly modulates sensitivity to gyrase inhibition, but only in oriC and not oriN cells. We propose that gyrase is a negative regulator of DnaA‐dependent replication initiation from oriC, and that this regulatory mechanism is required for cell survival.     

YabA and DnaD inhibit helix assembly of the DNA replication initiation protein DnaA

Control of DNA replication initiation is essential for cell growth. A unifying characteristic of DNA replication initiator proteins 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 to form an active initiation complex. Recently we developed a unique cross‐linking assay that specifically detects ATP‐dependent DnaA helix assembly. Here we have utilized this assay to show that two DnaA regulatory proteins in Bacillus subtilis, YabA and DnaD, inhibit DnaA helix formation. These results, in combination with our previous finding that the regulatory factor Soj/ParA also targets DnaA filament formation, highlight the critical importance of regulating DnaA helix formation during the initiation reaction. Moreover, these observations lead us to suggest that DnaA oligomerization may be the main regulatory step of the initiator assembly pathway in B. subtilis, in contrast to the prevailing model of bacterial DNA replication based on Escherichia coli DnaA where ATP binding appears to be the targeted activity.     

Two types of cold sensitivity associated with the A184-->V change in the DnaA protein

Multicopy dnaA(Ts) strains carrying the dnaA5 or dnaA46 allele are high-temperature resistant but are cold sensitive for colony formation. The DnaA5 and DnaA46 proteins both have an A184-->V change in the ATP binding motif of the protein, but they also have one additional mutation. The mutations were separated, and it was found that a plasmid carrying exclusively the A184-->V mutation conferred a phenotype virtually identical to that of the dnaA5 plasmid. Strains carrying plasmids with either of the additional mutations behaved like a strain carrying the dnaA+ plasmid. In temperature downshifts from 42 degrees C to 30 degrees C, chromosome replication was stimulated in the multicopy dnaA46 strain. The DNA per mass ratio increased threefold, and exponential growth was maintained for more than four mass doublings. Strains carrying plasmids with the dnaA(A184-->V) or the dnaA5 gene behaved differently. The temperature downshift resulted in run out of DNA synthesis and the strains eventually ceased growth. The arrest of DNA synthesis was not due to the inability to initiate chromosome replication because marker frequency analysis showed high initiation activity after temperature downshift. However, the marker frequencies indicated that most, if not all, of the newly initiated replication forks were stalled soon after the onset of chromosome replication. Thus, it appears that the multicopy dnaA(A184-->V) strains are cold sensitive because of an inability to elongate replication at low temperature. The multicopy dnaA46 strains, on the contrary, exhibit productive initiation and normal fork movement. In this case, the cold-sensitive phenotype may be due to DNA overproduction.     

Replication arrest is a major threat to growth at low temperature in Antarctic Pseudomonas syringae Lz4W

Chromosomal damage was detected previously in the recBCD mutants of the Antarctic bacterium Pseudomonas syringae Lz4W, which accumulated linear chromosomal DNA leading to cell death and growth inhibition at 4°C. RecBCD protein generally repairs DNA double‐strand breaks by RecA‐dependent homologous recombination pathway. Here we show that ΔrecA mutant of P. syringae is not cold‐sensitive. Significantly, inactivation of additional DNA repair genes ruvAB rescued the cold‐sensitive phenotype of ΔrecBCD mutant. The ΔrecA and ΔruvAB mutants were UV‐sensitive as expected. We propose that, at low temperature DNA replication encounters barriers leading to frequent replication fork (RF) arrest and fork reversal. RuvAB binds to the reversed RFs (RRFs) having Holliday junction‐like structures and resolves them upon association with RuvC nuclease to cause linearization of the chromosome, a threat to cell survival. RecBCD prevents this by degrading the RRFs, and facilitates replication re‐initiation. This model is consistent with our observation that low temperature‐induced DNA lesions do not evoke SOS response in P. syringae. Additional studies show that two other repair genes, radA (encoding a RecA paralogue) and recF are not involved in providing cold resistance to the Antarctic bacterium.     

The atypical response regulator HP1021 controls formation of the Helicobacter pylori replication initiation complex

The replication of a bacterial chromosome is initiated by the DnaA protein, which binds to the specific chromosomal region oriC and unwinds duplex DNA within the DNA‐unwinding element (DUE). The initiation is tightly regulated by many factors, which control either DnaA or oriC activity and ensure that the chromosome is duplicated only when the conditions favor the survival of daughter cells. The factors controlling oriC activity often belong to the protein families of two‐component systems. Here, we found that Helicobacter pylori oriC activity is controlled by HP1021, a member of the atypical response regulator family. HP1021 protein specifically interacts with H. pylori oriC at HP1021 boxes (5′‐TGTT[TA]C[TA]‐3′), which overlap with three modules important for oriC function: DnaA boxes, the hypersensitivity (hs) region and the DUE. Consequently, HP1021 binding to oriC precludes DnaA‐oriC interactions and inhibits DNA unwinding at the DUE. Thus, HP1021 constitutes a negative regulator of the H. pylori orisome assembly in vitro. Furthermore, HP1021 boxes were found upstream of at least 70 genes, including those encoding CagA and Fur proteins. We postulate that HP1021 might coordinate chromosome replication, and thus bacterial growth, with other cellular processes and conditions in the human stomach.     

The DnaA inhibitor SirA acts in the same pathway as Soj (ParA) to facilitate oriC segregation during Bacillus subtilis sporulation

DNA replication and chromosome segregation must be carefully regulated to ensure reproductive success. During Bacillus subtilis sporulation, chromosome copy number is reduced to two, and cells divide asymmetrically to produce the future spore (forespore) compartment. For successful sporulation, oriC must be captured in the forespore. New rounds of DNA replication are prevented in part by SirA, a protein that utilizes residues in its N‐terminus to directly target Domain I of the bacterial initiator, DnaA. Using a quantitative forespore chromosome organization assay, we show that SirA also acts in the same pathway as another DnaA regulator, Soj, to promote oriC capture in the forespore. By analyzing loss‐of‐function variants of both SirA and DnaA, we observe that SirA's ability to inhibit DNA replication can be genetically separated from its role in oriC capture. In addition, we identify substitutions near the C‐terminus of SirA and in DnaA Domain III that enhance interaction between the two proteins. One such variant, SirA_P141T, remained functional in regard to inhibiting replication, but was unable to support oriC capture. Collectively, our results support a model in which SirA targets DnaA Domain I to inhibit DNA replication, and DnaA Domain III to facilitate Soj‐dependent oriC capture in the forespore.     

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.     

Structure and interactions of the Bacillus subtilis sporulation inhibitor of DNA replication,SirA, with domain I of DnaA

Chromosome copy number in cells is controlled so that the frequency of initiation of DNA replication matches that of cell division. In bacteria, this is achieved through regulation of the interaction between the initiator protein DnaA and specific DNA elements arrayed at the origin of replication. DnaA assembles at the origin and promotes DNA unwinding and the assembly of a replication initiation complex. SirA is a DnaA‐interacting protein that inhibits initiation of replication in diploid Bacillus subtilis cells committed to the developmental pathway leading to formation of a dormant spore. Here we present the crystal structure of SirA in complex with the N‐terminal domain of DnaA revealing a heterodimeric complex. The interacting surfaces of both proteins are α‐helical with predominantly apolar side‐chains packing in a hydrophobic interface. Site‐directed mutagenesis experiments confirm the importance of this interface for the interaction of the two proteins in vitro and in vivo. Localization of GFP–SirA indicates that the protein accumulates at the replisome in sporulating cells, likely through a direct interaction with DnaA. The SirA interacting surface of DnaA corresponds closely to the HobA‐interacting surface of DnaA from Helicobacter pylori even though HobA is an activator of DnaA and SirA is an inhibitor.     

Novel essential residues of Hda for interaction with DnaA in the regulatory inactivation of DnaA: unique roles for Hda AAA+ Box VI and VII motifs

Escherichia coli ATP–DnaA initiates chromosomal replication. For preventing extra‐initiations, a complex of ADP–Hda and the DNA‐loaded replicase clamp promotes DnaA‐ATP hydrolysis, yielding inactive ADP–DnaA. However, the Hda–DnaA interaction mode remains unclear except that the Hda Box VII Arg finger (Arg‐153) and DnaA sensor II Arg‐334 within each AAA⁺ domain are crucial for the DnaA‐ATP hydrolysis. Here, we demonstrate that direct and functional interaction of ADP–Hda with DnaA requires the Hda residues Ser‐152, Phe‐118 and Asn‐122 as well as Hda Arg‐153 and DnaA Arg‐334. Structural analyses suggest intermolecular interactions between Hda Ser‐152 and DnaA Arg‐334 and between Hda Phe‐118 and the DnaA Walker B motif region, in addition to an intramolecular interaction between Hda Asn‐122 and Arg‐153. These interactions likely sustain a specific association of ADP–Hda and DnaA, promoting DnaA‐ATP hydrolysis. Consistently, ATP–DnaA and ADP–DnaA interact with the ADP–Hda‐DNA–clamp complex with similar affinities. Hda Phe‐118 and Asn‐122 are contained in the Box VI region, and their hydrophobic and electrostatic features are basically conserved in the corresponding residues of other AAA⁺ proteins, suggesting a conserved role for Box VI. These findings indicate novel interaction mechanisms for Hda–DnaA as well as a potentially fundamental mechanism in AAA⁺ protein interactions.     

Role of DnaA protein during replication of plasmid pBR322 in Escherichia coli

Summary The in vivo role of the Escherichia coli protein DnaA in the replication of plasmid pBR322 was investigated, using a plasmid derivative carrying an inducible dnaA ⁺ gene. In LB medium without inducer, the replication of this plasmid, like that of pBR322, was inhibited by heat inactivation of chromosomal DnaA46 protein so that plasmid accumulation ceased 1 to 2 h after the temperature shift. This inhibition did not occur when the plasmid dnaA ⁺ gene was expressed in the presence of the inducer isopropyl-1-thin--d-galactopyranoside (IPTG). Inhibition was also not observed in glycerol minimal medium or in the presence of low concentrations of rifampicin or chloramphenicol. Deletion of the DnaA binding site and the primosome assembly sites (pas, rri) downstream of the replication origin did not affect the plasmid copy number during exponential growth at 30° C, or after inactivation of DnaA by a shift to 42° C in a dnaA46 host, or after oversupply of DnaA, indicating that these sites are not involved in a rate-limiting step for replication in vivo. The accumulation of the replication inhibitor, RNAI, was independent of DnaA activity, ruling out the possibility that DnaA acts as a repressor of RNAI synthesis, as has been suggested in the literature. Changes in the rate of plasmid replication in response to changes in DnaA activity (in LB medium) could be resolved into an early, rom-dependent, and a late, rom-independent component. Rom ^– plasmids show only the late effect. After heat inactivation of DnaC, plasmid replication ceased immediately. These results, together with previously published reports, suggest that DnaA plays no specific role during in vivo replication of ColE1 plasmids and that the gradual cessation of plasmid replication after heat inactivation of DnaA in LB medium results from indirect effects of the inhibition of chromosome replication and the ensuing saturation of promoters with RNA polymerase under nonpermissive growth conditions.     

Initiation of chromosomal DNA replication which is stimulated without oversupply of DnaA protein in Escherichia coli

Summary The temperature-sensitive dnaA46 mutation in Escherichia coli can be phenotypically suppressed at 42° C by oversupply of GroELS proteins, and the suppressed cells grow extremely slowly at 30° C. We found that the phenotype of dnaA46 showing this cold sensitivity was dominant over the phenotype of dnaA ⁺, and could not be rescued by introduction of oriC-independent replication systems. These results suggest that the cold sensitivity was not caused by a simple defect in replication. When a growing culture of a dnaA46 strain with a GroELS-overproducing plasmid was shifted from 42° to 30° C in the presence of chloramphenicol, the chromosomal DNA replicated excessively. Initiation of replication occurred at the site of oriC repeatedly four or five times during a 4 h incubation period without concomitant protein synthesis, indicating an excessive capacity for initiation. Such overreplication did not take place at 42° C in the suppressed dnaA46 strain, or at either temperature in GroELS-oversupplied dnaA ⁺ cells. No significant difference was detected between the cellular content of DnaA protein in suppressed cells where the initiation capacity was abnormally high, and that in wild-type cells in which the initiation capacity was normal. Thus, DnaA protein might function in vivo through some phase control mechanism for initiation, apart from a simple regulation by its total amount. A possible mechanism is proposed based on the participation of GroELS proteins in protein folding.A preliminary account of this work was presented at the Annual Meeting of the Molecular Biology Society of Japan in 1989.     

The localized melting of mini-F origin by the combined action of the mini-F initiator protein (RepE) and HU and DnaA of Escherichia coli

 Replication of mini-F plasmids requires the initiator protein RepE, which binds specifically to four iterons within the origin (ori2), as well as some host factors that are involved in chromosomal DNA replication. To understand the role of host factors and RepE in the early steps of mini-F DNA replication, we examined the effects of RepE and the Escherichia coli proteins DnaA and HU on the localized melting of ori2 DNA in a purified in vitro system. We found that the binding of RepE to an iteron causes a 50^° bend at or around the site of binding. RepE and HU exhibited synergistic effects on the localized melting within the ori2 region, as detected by sensitivity to the single-strand specific P1 endonuclease. This opening of duplex DNA occurred around the 13mer of ori2, whose sequence closely resembles the set of 13mers found in the chromosomal origin oriC. Further addition of DnaA to the reaction mixture increased the efficiency of melting and appeared to extend melting to the adjacent AT-rich region. Moreover, DNA melting with appreciably higher efficiencies was observed with mutant forms of RepE that were previously shown to be hyperactive both in DNA binding in vitro and in initiator activity in vivo. We propose that the binding of RepE to four iterons of ori2 causes bending at the sites of RepE binding and, with the assistance of HU, induces a localized melting in the 13mer region. The addition of DnaA extends melting to the AT-rich region, which could then serve as the entry site for the DnaB-DnaC complex, much as has been documented for oriC- dependent replication. Received: 15 May 1996/Accepted: 11 July 1996