Unique organization of the dnaA region from Prochlorococcus marinus CCMP1375, a marine cyanobacterium

In order to study DNA replication control elements in cyanobacteria we cloned and sequenced the dnaA gene from the marine cyanobacterium Prochlorococcus marinus. The dnaA gene is ubiquitous among bacteria and encodes the DNA replication initiation factor DnaA. The deduced amino acid sequence of the P. marinus DnaA protein shows highest similarity to the DnaA protein from the freshwater cyanobacterium Synechocystis sp. PCC6803. Using a solid-phase DNA binding assay we demonstrated that both cyanobacterial DnaA proteins specifically recognize chromosomal origins, oriC, of Escherichia coli and Bacillus subtilis in vitro. The genetic environment of dnaA is not conserved between the two cyanobacteria. Upstream of the P. marinusdnaA gene we identified a gene encoding a putative ATP-binding cassette (ABC) transport protein. The gor gene encoding glutathione reductase lies downstream of dnaA. Comparison of the genetic structure of dnaA regions from 15 representative bacteria shows that the pattern of genes flanking dnaA is not universally conserved among them.     

DNA lesions that block DNA replication are responsible for the dnaA induction caused by DNA damage

Summary The initiation protein DnaA of Escherichia coli regulates its own expression autogenously by binding to a 9 by consensus sequence, the dnaA box, between the promoters dnaAP1 and dnaAP2. In this study, we analysed dnaA regulation in relation to DNA damage and found dnaA expression to be inducible by DNA lesions that inhibit DNA replication. On the other hand, coding DNA lesions were not able to induce dnaA expression. These results suggest that an additional regulatory mechanism is involved in dnaA gene expression and that DnaA protein may play a role in cellular responses to DNA damage. Furthermore, they strongly suggest that in response to DNA replication inhibition by DNA damage, and enhanced (re)initiation capacity is induced by oriC.     

Phenotypes ofdnaA mutants ofEscherichia coli sensitive to phenothiazine derivatives

The activation of DnaA protein by cardiolipin is inhibited by fluphenazinein vitro. We therefore examined the sensitivity of temperature-sensitivednaA mutants ofEscherichia coli to fluphenazine and other phenothiazine derivatives. Among the eightdnaA mutants tested,dnaA5, dnaA46 dnaA602, anddnaA604, mutants with mutations in the putative ATP binding site of DnaA protein, showed higher sensitivities to phenothiazine derivatives than did the wild-type strain. ThednaA508 anddnaA167 mutants, which have mutations in the N-terminal region of DnaA protein, also showed higher sensitivities to phenothiazine derivatives. On the other hand, thednaA204 anddnaA205 mutants, with lesions in the C-terminal region of the DnaA protein, showed the same sensitivity to phenothiazine derivatives as the wild-type strain. Complementation analysis with a plasmid containing the wild-typednaA gene and phage P1-mediated transduction confirmed thatdnaA mutations are responsible for these sensitivity phenotypes.     

Assembly of Helicobacter pylori Initiation Complex Is Determined by Sequence-Specific and Topology-Sensitive DnaA–oriC Interactions

In bacteria, chromosome replication is initiated by binding of the DnaA initiator protein to DnaA boxes located in the origin of chromosomal replication (oriC). This leads to DNA helix opening within the DNA-unwinding element. Helicobacter pylori oriC, the first bipartite origin identified in Gram-negative bacteria, contains two subregions, oriC1 and oriC2, flanking the dnaA gene. The DNA-unwinding element region is localized in the oriC2 subregion downstream of dnaA. Surprisingly, oriC2–DnaA interactions were shown to depend on DNA topology, which is unusual in bacteria but is similar to initiator–origin interactions observed in higher organisms. In this work, we identified three DnaA boxes in the oriC2 subregion, two of which were bound only as supercoiled DNA. We found that all three DnaA boxes play important roles in orisome assembly and subsequent DNA unwinding, but different functions can be assigned to individual boxes. This suggests that the H. pylori oriC may be functionally divided, similar to what was described recently for Escherichia coli oriC. On the basis of these results, we propose a model of initiation complex formation in H. pylori.     

Structure and regulation of the dnaA promoter region in three Streptomyces species

 The regulatory region of the Streptomyces dnaA gene comprises a single promoter and two DnaA boxes that are located upstream of the promoter. Comparative analysis of the dnaA promoter region from S. chrysomallus, S. lividans and S. reticuli revealed that the location, spacing and orientation of the DnaA boxes are conserved. In vitro studies demonstrated that efficient binding of the Streptomyces DnaA protein to DNA requires the presence of two DnaA boxes. In vivo analysis of dnaA promoter mutants deleted for one or both DnaA boxes indicated that the dnaA gene is autoregulated. However, the degree of derepression observed is relatively modest. Received: 12 July 1999 / Accepted: 19 October 1999     

Identification of a putative chromosomal replication origin from Helicobacter pylori and its interaction with the initiator protein DnaA

The key elements of the initiation of Helicobacter pylori chromosome replication, DnaA protein and putative oriC region, have been characterized. The gene arrangement in the H.pylori dnaA region differs from that found in many other eubacterial dnaA regions (rnpA-rmpH-dnaA-dnaN-recF-gyrB). Helicobacter pylori dnaA is flanked by two open reading frames with unknown function, while dnaN-gyrB and rnpA-rmpH loci are separated from the dnaA gene by 600 and 90 kb, respectively. We show that the dnaA gene encoding initiator protein DnaA is expressed in H.pylori cells. The H.pylori DnaA protein, like other DnaA proteins, can be divided into four domains. Here we demonstrate that the C-terminal domain of H.pylori DnaA protein is responsible for DNA binding. Using in silico and in vitro studies, the putative oriC region containing five DnaA boxes has been located upstream of the dnaA gene. DNase I and gel retardation analyses show that the C-terminal domain of H.pylori DnaA protein specifically binds each of five DnaA boxes.     

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.     

Integrative suppression of dnaA(Ts) mutations mediated by plasmid F in Escherichia coli is a DnaA-dependent process

Summary The thermosensitivity of dnaA(Ts) mutations can be suppressed by integration of plasmid F (integrative suppression). In the light of the recent finding that F requires DnaA protein for both establishment and maintenance, integrative suppression of 11 dnaA(Ts) mutations by a mini-F, pML31, integrated near oriC was examined. The plating efficiency of integratively suppressed strains was dnaA(Ts) allele-dependent and medium-dependent. The initiation capability of suppressed dnaA(Ts) strains lacking the oriC site and their F^- counterparts was determined at various temperatures between 30°C and 42°C. The degree of integrative suppression measured by the initiation capability varied in a dnaA(Ts) allele-dependent manner. F-directed DNA replication was most affected by the dnaA(Ts) mutations mapping in the middle of the gene whereas oriC-dependent replication was most thermosensitive in strains carrying mutations mapping in the carboxy-terminal half of the gene. The results indicated that the integrative suppression by F plasmid is a DnaA-dependent process and suggested that the requirements for DnaA protein in the oriC-dependent replication and F replication processes are qualitatively different.     

Mutations in dnaA and a cryptic interaction site increase drug resistance in Mycobacterium tuberculosis

Genomic dissection of antibiotic resistance in bacterial pathogens has largely focused on genetic changes conferring growth above a single critical concentration of drug. However, reduced susceptibility to antibiotics—even below this breakpoint—is associated with poor treatment outcomes in the clinic, including in tuberculosis. Clinical strains of Mycobacterium tuberculosis exhibit extensive quantitative variation in antibiotic susceptibility but the genetic basis behind this spectrum of drug susceptibility remains ill-defined. Through a genome wide association study, we show that non-synonymous mutations in dnaA, which encodes an essential and highly conserved regulator of DNA replication, are associated with drug resistance in clinical M. tuberculosis strains. We demonstrate that these dnaA mutations specifically enhance M. tuberculosis survival during isoniazid treatment via reduced expression of katG, the activator of isoniazid. To identify DnaA interactors relevant to this phenotype, we perform the first genome-wide biochemical mapping of DnaA binding sites in mycobacteria which reveals a DnaA interaction site that is the target of recurrent mutation in clinical strains. Reconstructing clinically prevalent mutations in this DnaA interaction site reproduces the phenotypes of dnaA mutants, suggesting that clinical strains of M. tuberculosis have evolved mutations in a previously uncharacterized DnaA pathway that quantitatively increases resistance to the key first-line antibiotic isoniazid. Discovering genetic mechanisms that reduce drug susceptibility and support the evolution of high-level drug resistance will guide development of biomarkers capable of prospectively identifying patients at risk of treatment failure in the clinic.     

Cloning and nucleotide sequence determination of twelve mutant dnaA genes of Escherichia coli

Summary Plasmids carrying different regions of the wild-type dnaA gene were used for marker rescue analysis of the temperature sensitivity of twelve strains carrying dnaA mutations. The different dnaA(Ts) mutations could be unambiguously located within specific regions of the dnaA gene. The mutant dnaA genes were cloned on pBR322-derived plasmids and on nucleotide sequencing by dideoxy chain termination the respective mutations were determined using M13 clones carrying the relevant parts of the mutant dnaA gene. Several of the mutant dnaA genes were found to have two mutations. The dnaA5, dnaA46, dnaA601, dnaA602, dnaA604, and dnaA606 genes all had identical mutations corresponding to an amino acid change from alanine to valine at amino acid 184 in the DnaA protein, close to the proposed ATP binding site, but all carried one further mutation giving rise to an amino acid substitution. The dnaA508 gene also had two mutations, whereas dnaA167, dnaA203, dnaA204, dnaA205, and dnaA211 each had only one. The pairs dnaA601/602, dnaA604/606, and dnaA203/204 were each found to have identical mutations. Plasmids carrying the different dnaA mutant genes intact were introduced into the respective dnaA mutant strains. Surprisingly, these homopolyploid mutant strains were found to be temperature resistant in most cases, indicating that a high intracellular concentration of the mutant DnaA protein can compensate for the decreased activity of the protein.     

Overproduction of DnaA protein stimulates initiation of chromosome and minichromosome replication in Escherichia coli

Summary Increased synthesis of DnaA protein, obtained with plasmids carrying the dnaA gene controlled by the heat inducible pL promoter, stimulated initiation of replication from oriC about threefold. The overinitiation was determined both as an increase in copy number of a minichromosome and as an increase in chromosomal gene dosage of oriC proximal DNA. The additional replication forks which were initiated on the chromosome did not lead to an overall increase in DNA content. DNA/DNA hybridization showed an amplification encompassing less than a few hundred kilobases on each side of oriC. Kinetic studies showed that the overinitiation occurred very rapidly after the induction, and that the initiation frequency then decreased to a near normal frequency per oriC. The results indicate that the DnaA protein is one important factor in regulation of initiation of DNA replication from oriC.     

Replication of a Bacillus subtilis oriC plasmid in vitro

We constructed an in vitro replication system specific for a Bacillus subtilis oriC plasmid using a soluble fraction derived from cell extracts of B. subtilis. DNA polymerase III and two initiation proteins, DnaA and DnaB, were required for in vitro replication as observed in vivo. Both upstream and downstream DnaA box regions of the dnaA gene were required as cis-elements for in vitro synthesis of the B. subtilis oriC plasmid as well as for in vivo activity. The replication was semi-conservative and only one round of replication occurred within 15min. These results indicate that in vitro replication faithfully reproduced in vivo replication. To elucidate the site of initiation and the direction of replication, we analysed replicative intermediates generated in vitro in the presence of various concentrations of ddGTP by two methods. First, analysis of restriction fragments around the dnaA gene showed a high level of incorporation of the radioactive substrate, indicating that replication began within the vicinity of the dnaA gene. Second, using 2-dimensional gel electrophoresis, bubble arcs were detected only on fragments containing the DnaA box region downstream of the dnaA gene, indicating that the initiation site resided within this region. The distribution of the bubble arcs suggested that both bidirectional and unidirectional replication occurred in vitro.     

Initiation of DNA replication in Escherichia coli after overproduction of the DnaA protein

Summary Flow cytometry was used to study initiation of DNA replication in Escherichia coli K12 after induced expression of a plasmid-borne dnaA ⁺ gene. When the dnaA gene was induced from either the plac or the pL promoter initiation was stimulated, as evidenced by an increase in the number of origins and in DNA content per mass unit. During prolonged growth under inducing conditions the origin and DNA content per mass unit were stabilized at levels significantly higher than those found before induction or in similarly treated control cells. The largest increase was observed when using the stronger promoter pL compared to plac. Synchrony of initiation was reasonably well maintained with elevated DnaA protein concentrations, indicating that simultaneous initiation of all origins was still preferred under these conditions. A reduced rate of replication fork movement was found in the presence of rifampin when the DnaA protein was overproduced. We conclude that increased synthesis levels or increased concentrations of the DnaA protein stimulate initiation of DNA replication. The data suggest that the DnaA protein may be the limiting factor for initiation under normal physiological conditions.     

dnaA suppressor (dasF) mutants of Escherichia coli are stable DNA replication (sdrA/rnh) mutants

Summary The possible allelic relationship between dasF (dnaA suppressor) and sdrA/rnh (stable DNA replication/RNase H) mutations was examined. dasF mutations could not only suppress various dnaA(ts) mutations, but also the insertional inactivation of the dnaA gene or deletion of the oriC sequence, as could sdrA mutations. dasF mutants were found to exhibit the stable DNA replication phenotype, and the sensitivity to rich media, of sdrA mutants. The dasF and sdrA mutations were mapped very closely between metD and proA on the E. coli genetic map. The mutations were recessive to the wild-type allele for all the above phenotypes. It was concluded that dasF is allelic to sdrA/mh.