E. coli SeqA protein binds oriC in two different methyl-modulated reactions appropriate to its roles in DNA replication initiation and origin sequestration

The seqA gene negatively modulates replication initiation at the E. coli origin, oriC. seqA is also essential for sequestration, which acts at oriC and the dnaA promoter to ensure that replication initiation occurs exactly once per chromosome per cell cycle. Initiation is promoted by full methylation of GATC sites clustered in oriC; sequestration is specific to the hemimethylated forms generated by replication. SeqA protein purification and DNA binding are described. SeqA interacts with fully methylated oriC strongly and specifically. This reaction requires multiple molecules of SeqA and determinants throughout oriC, including segments involved in open complex formation. SeqA interacts more strongly with hemimethylated DNA; in this case, oriC and non-oriC sequences are bound similarly. Also, binding of hemimethylated oriC by membrane fractions is due to SeqA. Direct interaction of SeqA protein with the replication origin is likely to be involved in both replication initiation and sequestration.     

The FIS protein fails to block the binding of DnaA protein to oriC, the Escherichia coli chromosomal origin

The Escherichia coli chromosomal origin contains several bindings sites for factor for inversion stimulation (FIS), a protein originally identified to be required for DNA inversion by the Hin and Gin recombinases. The primary FIS binding site is close to two central DnaA boxes that are bound by DnaA protein to initiate chromosomal replication. Because of the close proximity of this FIS site to the two DnaA boxes, we performed in situ footprinting with 1, 10-phenanthroline-copper of complexes formed with FIS and DnaA protein that were separated by native gel electrophoresis. These studies show that the binding of FIS to the primary FIS site did not block the binding of DnaA protein to DnaA boxes R2 and R3. Also, FIS appeared to be bound more stably to oriC than DnaA protein, as deduced by its reduced rate of dissociation from a restriction fragment containing oriC . Under conditions in which FIS was stably bound to the primary FIS site, it did not inhibit oriC plasmid replication in reconstituted replication systems. Inhibition, observed only at high levels of FIS, was due to absorption by FIS binding of the negative superhelicity of the oriC plasmid that is essential for the initiation process.     

Chromosomal replication incompatibility in Dam methyltransferase deficient Escherichia coli cells

Dam methyltransferase deficient Escherichia coli cells containing minichromosomes were constructed. Free plasmid DNA could not be detected in these cells and the minichromosomes were found to be integrated in multiple copies in the origin of replication (oriC) region of the host chromosome. The absence of the initiation cascade in Dam- cells is proposed to account for this observation of apparent incompatibility between plasmid and chromosomal copies of oriC. Studies using oriC-pBR322 chimeric plasmids and their deletion derivatives indicated that the incompatibility determinant is an intact and functional oriC sequence. The seqA2 mutation was found to overcome the incompatability phenotype by increasing the cellular oriC copy number 3-fold thereby allowing minichromosomes to coexist with the chromosome. The replication pattern of a wild-type strain with multiple integrated minichromosomes in the oriC region of the chromosome, led to the conclusion that initiation of DNA replication commences at a fixed cell mass, irrespective of the number of origins contained on the chromosome.     

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DnaA protein and the Escherichia coli chromosomal origin (oriC) form an initial complex at an early stage in the initiation of DNA replication. We have used electron microscopy to determine which structure among the several formed in the reconstitution of this multicomponent system is the replicatively active complex. One distinctive structure could be correlated with activity and localized to oriC, whilst several others could not. Formation of an open complex in the next stage of initiation was accompanied by the presence of a structure similar in size and shape to that of the functional initial complex. Whereas the initial complex was observed with either ATP or the ADP-forms of DnaA protein, only the ATP-form was effective in producing the open complex. Mutagenesis of several DNA sequence elements in oriC, known to be important for replication, was employed to determine the effects of these alterations on formation of the initial complex. As judged by electron microscopy and by functional assays, the region containing the four 9-mer dnaA boxes proved to be essential for the formation of the initial complex, while the three contiguous AT-rich 13-mers, known sites for opening of oriC, were not.     

The Escherichia coli Fis protein prevents initiation of DNA replication from oriC in vitro

Fis protein participates in the normal control of chromosomal replication in Escherichia coli. However, the mechanism by which it executes its effect is largely unknown. We demonstrate an inhibitory influence of purified Fis protein on replication from oriC in vitro. Fis inhibits DNA synthesis equally well in replication systems either dependent upon or independent of RNA polymerase, even when the latter is stimulated by the presence of HU or IHF. The extent of inhibition by Fis is modulated by the concentrations of DnaA protein and RNA polymerase; the more limiting the amounts of these, the more severe the inhibition by Fis. Thus, the level of inhibition seems to depend on the ease with which the open complex can be formed. Fis-mediated inhibition of DNA replication does not depend on a functional primary Fis binding site between DnaA boxes R2 and R3 in oriC, as mutations that cause reduced binding of Fis to this site do not affect the degree of inhibition. The data presented suggest that Fis prevents formation of an initiation-proficient structure at oriC by forming an alternative, initiation-preventive complex. This indicates a negative role for Fis in the regulation of replication initiation.     

Stationary phase induction of dnaN and recF, two genes of Escherichia coli involved in DNA replication and repair

The beta subunit of DNA polymerase III holoenzyme, the Escherichia coli chromosomal replicase, is a sliding DNA clamp responsible for tethering the polymerase to DNA and endowing it with high processivity. The gene encoding beta, dnaN, maps between dnaA and recF, which are involved in initiation of DNA replication at oriC and resumption of DNA replication at disrupted replication forks, respectively. In exponentially growing cells, dnaN and recF are expressed predominantly from the dnaA promoters. However, we have found that stationary phase induction of the dnaN promoters drastically changes the expression pattern of the dnaA operon genes. As a striking consequence, synthesis of the beta subunit and RecF protein increases when cell metabolism is slowing down. Such an induction is dependent on the stationary phase sigma factor, RpoS, although the accumulation of this factor alone is not sufficient to activate the dnaN promoters. These promoters are located in DNA regions without static bending, and the -35 hexamer element is essential for their RpoS-dependent induction. Our results suggest that stationary phase-dependent mechanisms have evolved in order to coordinate expression of dnaN and recF independently of the dnaA regulatory region. These mechanisms might be part of a developmental programme aimed at maintaining DNA integrity under stress conditions.     

A fixed distance for separation of newly replicated copies of oriC in Bacillus subtilis: implications for co-ordination of chromosome segregation and cell division

The Spo0J protein of Bacillus subtilis is required for normal chromosome segregation and forms discrete subcellular assemblies closely associated with the oriC region of the chromosome. Here we show that duplication of Spo0J foci occurs early in the DNA replication cycle and that this requires the initiation of DNA replication at oriC but not elongation beyond the nearby STer sites. Soon after duplication, sister oriC/Spo0J foci move rapidly apart to achieve a fixed separation of about 0.7 microm, reminiscent of the segregation of eukaryotic chromosomes on the mitotic spindle. The magnitude of the fixed separation distance may explain how chromosome segregation is kept in close register with cell growth and the initiation mass for DNA replication. It could also explain how segregation can proceed accurately in the absence of cell division. The kinetics of focal separation suggest that one role of Spo0J protein may be to facilitate formation of separate sister oriC complexes that can be segregated.     

Primase couples leading- and lagging-strand DNA synthesis from oriC

Coupling of leading- and lagging-strand DNA synthesis at replication forks formed at Escherichia coli oriC has been studied in vitro using a replication system reconstituted with purified proteins. At low concentrations of primase (8 nM), the major replication products were multigenome-length molecules, generated by a rolling circle-type mechanism, and unit-length molecules. Rolling circle DNA replication was inhibited at high concentrations of primase (80 nM) and the major replication products were half-unit-length leading strands and a distinct population of short Okazaki fragments. At low primase concentrations, an asymmetric mode of DNA synthesis occurred. Each strand was made independently and initiation could occur outside of oriC. At high primase concentrations, initiation occurred exclusively at oriC and two coupled replication forks proceeded bidirectionally around the plasmid. Presumably, at low concentrations of primase, DnaB (the replication fork helicase) unwound the plasmid DNA before replication forks could form, leading to initiation at sites other than oriC. On the other hand, high concentrations of primase resulted in successful capture of the helicase leading to the formation at oriC of coupled replication forks capable of coordinated leading- and lagging-strand synthesis.     

In vivo evidence for the involvement of anionic phospholipids in initiation of DNA replication in Escherichia coli

In vitro, anionic phospholipids can reactivate inactivated DnaA protein, which is essential for initiation of DNA replication at the oriC site of Escherichia coli [Sekimizu, K. & Kornberg, A. (1988) J. Biol. Chem. 263, 7131-7135]. Mutations in the pgsA gene (encoding phosphatidylglycerophosphate synthase) limit the synthesis of the major anionic phospholipids and lead to arrest of cell growth. We report herein that a mutation in the rnhA gene (encoding RNase H) that bypasses the need for the DnaA protein through induction of constitutive stable DNA replication [Kogoma, T. & von Meyenburg, K. (1983) EMBO J. 2, 463-468] also suppressed the growth arrest phenotype of a pgsA mutant. The maintenance of plasmids dependent on an oriC site for replication, and therefore DnaA protein, was also compromised under conditions of limiting anionic phospholipid synthesis. These results provide support for the involvement of anionic phospholipids in normal initiation of DNA replication at oriC in vivo by the DnaA protein.     

Identification of DNA gyrase inhibitor (GyrI) in Escherichia coli

DNA gyrase is an essential enzyme in DNA replication in Escherichia coli. It mediates the introduction of negative supercoils near oriC, removal of positive supercoils ahead of the growing DNA fork, and separation of the two daughter duplexes. In the course of purifying DNA gyrase from E. coli KL16, we found an 18-kDa protein that inhibited the supercoiling activity of DNA gyrase, and we coined it DNA gyrase inhibitory protein (GyrI). Its NH2-terminal amino acid sequence of 16 residues was determined to be identical to that of a putative gene product (a polypeptide of 157 amino acids) encoded by yeeB (EMBL accession no. U00009) and sbmC (Baquero, M. R., Bouzon, M., Varea, J., and Moreno, F. (1995) Mol. Microbiol. 18, 301-311) of E. coli. Assuming the identity of the gene (gyrI) encoding GyrI with the previously reported genes yeeB and sbmC, we cloned the gene after amplification by polymerase chain reaction and purified the 18-kDa protein from an E. coli strain overexpressing it. The purified 18-kDa protein was confirmed to inhibit the supercoiling activity of DNA gyrase in vitro. In vivo, both overexpression and antisense expression of the gyrI gene induced filamentous growth of cells and suppressed cell proliferation. GyrI protein is the first identified chromosomally nucleoid-encoded regulatory factor of DNA gyrase in E. coli.     

Effects of purified SeqA protein on oriC-dependent DNA replication in vitro

In vivo studies suggest that the Escherichia coli SeqA protein modulates replication initiation in two ways: by delaying initiation and by sequestering newly replicated origins from undergoing re-replication. As a first approach towards understanding the biochemical bases for these effects, we have examined the effects of purified SeqA protein on replication reactions performed in vitro on an oriC plasmid. Our results demonstrate that SeqA directly affects the biochemical events occurring at oriC. First, SeqA inhibits formation of the pre-priming complex. Secondly, SeqA can inhibit replication from an established pre-priming complex, without disrupting the complex. Thirdly, SeqA alters the dependence of the replication system on DnaA protein concentration, stimulating replication at low concentrations of DnaA. Our data suggest that SeqA participates in the assembly of initiation-competent complexes at oriC and, at a later stage, influences the behaviour of these complexes.     

GTP hydrolysis controls stringent selection of the AUG start codon during translation initiation in Saccharomyces cerevisiae

We have isolated and characterized two suppressor genes, SUI4 and SUI5, that can initiate translation in the absence of an AUG start codon at the HIS4 locus in Saccharomyces cerevisiae. Both suppressor genes are dominant in diploid cells and lethal in haploid cells. The SUI4 suppressor gene is identical to the GCD11 gene, which encodes the gamma subunit of the eIF-2 complex and contains a mutation in the G2 motif, one of the four signature motifs that characterizes this subunit to be a G-protein. The SUI5 suppressor gene is identical to the TIF5 gene that encodes eIF-5, a translation initiation factor known to stimulate the hydrolysis of GTP bound to eIF-2 as part of the 43S preinitiation complex. Purified mutant eIF-5 is more active in stimulating GTP hydrolysis in vitro than wild-type eIF-5, suggesting that an alteration of the hydrolysis rate of GTP bound to the 43S preinitiation complex during ribosomal scanning allows translation initiation at a non-AUG codon. Purified mutant eIF-2gamma complex is defective in ternary complex formation and this defect correlates with a higher rate of dissociation from charged initiator-tRNA in the absence of GTP hydrolysis. Biochemical characterization of SUI3 suppressor alleles that encode mutant forms of the beta subunit of eIF-2 revealed that these mutant eIF-2 complexes have a higher intrinsic rate of GTP hydrolysis, which is eIF-5 independent. All of these biochemical defects result in initiation at a UUG codon at the his4 gene in yeast. These studies in light of other analyses indicate that GTP hydrolysis that leads to dissociation of eIF-2 x GDP from the initiator-tRNA in the 43S preinitiation complex serves as a checkpoint for a 3-bp codon/anticodon interaction between the AUG start codon and the initiator-tRNA during the ribosomal scanning process.     

Increased expression of a hemimethylated oriC binding protein, SeqA, in an aphA mutant

In Escherichia coli, the origin of DNA replication, oriC, becomes transiently hemimethylated at the GATC sequences immediately after initiation of replication and this hemimethylated state is prolonged because of its sequestration by a fraction of outer membrane. This sequestration is dependent on a hemimethylated oriC binding protein such as SeqA. We previously isolated a clone of phage lambda gt11 called hobH, producing a LacZ fusion protein which recognizes hemimethylated oriC DNA. Very recently, Thaller et al. (FEMS Microbiol. Lett. 146 (1997) 191-198) found that the same DNA segment encodes a non-specific acid phosphatase, and named the gene aphA. We show here that the interruption of the aphA reading frame by kanamycin resistance gene insertion, abolishes acid phosphatase (NAP) activity. Interestingly, in the membrane of the null mutant, the amount of SeqA protein is about six times higher than that in the parental strain, suggesting the existence of a regulatory mechanism between SeqA and NAP expression.     

Domains of DnaA protein involved in interaction with DnaB protein, and in unwinding the Escherichia coli chromosomal origin

DnaA protein of Escherichia coli is a sequence-specific DNA-binding protein required for the initiation of DNA replication from the chromosomal origin, oriC. It is also required for replication of several plasmids including pSC101, F, P-1, and R6K. A collection of monoclonal antibodies to DnaA protein has been produced and the primary epitopes recognized by them have been determined. These antibodies have also been examined for the ability to inhibit activities of DNA binding, ATP binding, unwinding of oriC, and replication of both an oriC plasmid, and an M13 single-stranded DNA with a proposed hairpin structure containing a DnaA protein-binding site. Replication of the latter DNA is dependent on DnaA protein by a mechanism termed ABC priming. These studies suggest regions of DnaA protein involved in interaction with DnaB protein, and in unwinding of oriC, or low-affinity binding of ATP.     

Differential effects of myeloperoxidase-derived oxidants on Escherichia coli DNA replication

The microbicidal myeloperoxidase (MPO)-H2O2-chloride system strongly inhibits Escherichia coli DNA synthesis. Also, cell envelopes from MPO-treated E. coli cells lose their ability to interact with hemimethylated DNA sequences of oriC, the chromosomal origin of replication, raising the prospect that suppression of DNA synthesis involves impairment of oriC-related functions (H. Rosen, et al. Proc. Natl. Acad. Sci. USA, 87:10048-10052, 1990). To evaluate whether origin-specific DNA sequences play a role in the MPO effect on E. coli DNA synthesis, plasmid DNA replication was compared to total (chromosomal) DNA replication for six plasmids with three distinct origins of replication. Plasmid pCM700 replication, replicating from oriC, was as sensitive to MPO-mediated inhibition as was total (chromosomal) DNA replication. A regression line describing this relationship had a slope of 0.90, and the r2 was 0.89. In contrast, the replication activities of three of four non-oriC plasmids, pUC19, pACYC184, and pSC101, demonstrated significant early resistance to inhibition by MPO-derived oxidants. The exception to this resistance pattern was plasmid pSP102, which has an origin derived from P1 phage. pSP102 replication declined similarly to that of total DNA synthesis. The regression line for pSP102 replication versus total DNA synthesis had a slope of 0.95, and the r2 was 0.92. The biochemical requirements for P1-mediated replication are strikingly similar to those for oriC-mediated replication. It is proposed that one of these requirements, common to oriC and the P1 origin but not critical to the replication of the other non-oriC plasmids, is an important target for MPO-mediated oxidations that mediate the initial decline in E. coli chromosomal DNA synthesis.     

acrB mutation located at carboxyl-terminal region of gyrase B subunit reduces DNA binding of DNA gyrase

Mutations that exhibit susceptibility to acriflavine have been isolated and classified as acr mutations in Escherichia coli. We cloned the acrB gene, which has been identified as a mutation of the gyrB gene, and found a double point mutation altering two consecutive amino acids (S759R/R760C) in the COOH-terminal region of the gyrase B subunit. The mutant B subunit was found to associate with the A subunit to make the quaternary structure, and the reconstituted gyrase showed an 80-fold reduction of specific activity in DNA supercoiling assay; the sensitivity to acriflavine was not different in the same unit of wild-type and mutant gyrases. The mutant enzyme retained intrinsic ATPase activity, but DNA-dependent stimulation was observed infrequently. A gel shift assay showed that acriflavine inhibited the DNA binding of gyrase. The acrB mutation also reduced significantly the DNA binding of gyrase but did not change the sensitivity to acriflavine. These results revealed that the acrB mutation is related to the inhibitory mechanism of acriflavine; and the acriflavine sensitivity of the mutant, at least in vitro, is caused mainly by reduction of the enzyme activity. Further, our findings suggest that the COOH-terminal region of the B subunit is essential for the initial binding of gyrase to the substrate DNA.