The sequence requirements for a functional Escherichia coli replication origin are different for the chromosome and a minichromosome

We have developed a simple three-step method for transferring oriC mutations from plasmids to the Escherichia coli chromosome. Ten oriC mutations were used to replace the wild-type chromosomal origin of a recBCsbcB host by recombination. The mutations were subsequently transferred to a wild-type host by transduction. oriC mutants with a mutated DnaA box R1 were not obtained, suggesting that R1 is essential for chromosomal origin function. The other mutant strains showed the same growth rates, DNA contents and cell mass as wild-type cells. Mutations in the left half of oriC, in DnaA boxes M, R2 or R3 or in the Fis or IHF binding sites caused moderate asynchrony of the initiation of chromosome replication, as measured by flow cytometry. In mutants with a scrambled DnaA box R4 or with a modified distance between DnaA boxes R3 and R4, initiations were severely asynchronous. Except for oriC14 and oriC21, mutated oriCs could not, or could only poorly, support minichromosome replication, whereas most of them supported chromosome replication, showing that the classical definition of a minimal oriC is not valid for chromosome replication. We present evidence that the functionality of certain mutated oriCs is far better on the chromosome than on a minichromosome.     

Subcellular localization of plasmids containing the oriC region of the Escherichia coli chromosome, with or without the sopABC partitioning system

Fluorescence in situ hybridization (FISH) analysis has revealed the subcellular localization of specific chromosomal segments and plasmid molecules during the cell division cycle in Escherichia coli: the replication origin (oriC) segments on the chromosome are localized at nucleoid borders, and actively partitioning mini-F plasmid molecules are localized at the 1/4 and 3/4 positions of the cell. In contrast, mini-F plasmid molecules lacking the sopABC segment are randomly localized in cytoplasmic areas at cell poles. In this study, we analysed the subcellular localization of an oriC plasmid that contains the minimum E. coli chromosomal replication origin and its flanking regions. These oriC plasmid molecules were mainly localized in cytosolic areas at cell poles. On the other hand, oriC plasmid DNA molecules carrying the sopABC segment of F plasmid were localized at cell quarter sites, as were actively partitioning mini-F plasmid DNA molecules. Therefore, we conclude that oriC itself and its flanking regions are not sufficient for positioning the replication origin domain of the E. coli chromosome within the cell.     

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.     

Isolation and characterization of plasmids carrying a partially defective Escherichia coli replication origin

The replication origin (oriC) of the Escherichia coli chromosome has been cloned and the region essential for chromosomal replication has been delimited to 245 base pairs. In previous studies the ability of recombinants between oriC and ColE1-type vectors, to transform E. coli polA- strains was used to determine which nucleotides in oriC are essential for replication. In this paper we have used a different approach by isolating partial defective replication mutants of a minichromosome (pCM959) that contains oriC as the single replication origin. Our results demonstrate that many mutations are allowed within oriC that do not affect oriC function as measured by the ability to transform E. coli polA- strains. In the minimal oriC region we detected 8 mutations at positions that are conserved in the sequence of six bacterial origins. The implications of these results on previous work will be discussed. Our data also demonstrate that a mutation producing an oriC- phenotype may be suppressed by secondary mutations. An E. coli strain was found that facilitates the isolation of partially defective minichromosomes. The results with this strain indicate a specific function of the sequence surrounding the base pair at position 138.     

Mapping of the in vivo start site for leading strand DNA synthesis in plasmid R1.

We have previously constructed Escherichia coli strains in which an R1 plasmid is integrated into the origin of chromosome replication, oriC. In such intR1 strains, oriC is inactive and initiation of chromosome replication instead takes place at the integrated R1 origin. Due to the large size of the chromosome, replication intermediates generated at the R1 origin in these strains are considerably more long-lived than those in unintegrated R1 plasmids. We have taken advantage of this and performed primer extensions on total DNA isolated from intR1 strains, and mapped the free 5' DNA ends that were generated as replication intermediates during R1 replication in vivo. The sensitivity of the mapping was considerably improved by the use of a repeated primer extension method (RPE). The free DNA ends were assumed to represent normal in vivo start sites for leading strand DNA synthesis in plasmid R1. The ends were mapped to a short region approximately 380 bp away from the R1 minimal origin, and the positions agreed well with previous in vitro mappings. The same start positions were also utilized in the absence of the DnaA protein, indicating that DnaA is not required for determination of the position at which DNA synthesis starts during initiation of replication at the R1 origin.     

Subcellular positioning of the origin region of the Bacillus subtilis chromosome is independent of sequences within oriC, the site of replication initiation, and the replication initiator DnaA

Regions of bacterial chromosomes occupy characteristic locations within the cell. In Bacillus subtilis, the origin of replication, oriC, is located at 0 degrees /360 degrees on the circular chromosome. After duplication, sister 0 degrees regions rapidly move to and then reside near the cell quarters. It has been hypothesized that origin function or oriC sequences contribute to positioning and movement of the 0 degrees region. We found that the position of a given chromosomal region does not depend on initiation of replication from the 0 degrees region. In an oriC mutant strain that replicates from a heterologous origin (oriN) at 257 degrees , the position of both the 0 degrees and 257 degrees regions was similar to that in wild-type cells. Thus, positioning of chromosomal regions appears to be independent of which region is replicated first. Furthermore, we found that neither oriC sequences nor the replication initiator DnaA is required or sufficient for positioning a region near the cell quarters. A sequence within oriC previously proposed to play a critical role in chromosome positioning and partitioning was found to make little, if any, contribution. We propose that uncharacterized sites outside of oriC are involved in moving and/or maintaining the 0 degrees region near the cell quarters.     

Regulation of the initiation of chromosomal replication in bacteria

The initiation of chromosomal replication occurs only once during the cell cycle in both prokaryotes and eukaryotes. Initiation of chromosome replication is the first and tightly controlled step of a DNA synthesis. Bacterial chromosome replication is initiated at a single origin, oriC, by the initiator protein DnaA, which specifically interacts with 9-bp non-palindromic sequences (DnaA boxes) at oriC. In Escherichia coli, a model organism used to study the mechanism of DNA replication and its regulation, the control of initiation relies on a reduction of the availability and/or activity of the two key elements, DnaA and the oriC region. This review summarizes recent research into the regulatory mechanisms of the initiation of chromosomal replication in bacteria, with emphasis on organisms other than E. coli.     

Two separate DNA sequences within oriC participate in accurate chromosome segregation in Bacillus subtilis

Current views of bacterial chromosome segregation vary in respect of the likely presence or absence of an active segregation mechanism involving a mitotic-like apparatus. Furthermore, little is known about cis-acting elements for chromosome segregation in bacteria. In this report, we show that two separate DNA regions, a 3' coding region of dnaA and the AT-rich sequence between dnaA and dnaN (the initial opening site of duplex DNA during replication), are necessary for efficient segregation of the chromosome in Bacillus subtilis. When a plasmid replicon was integrated into argG, far from oriC, on the chromosome and then the oriC function was disrupted, the oriC-deleted mutant formed anucleate cells at 5% possibly because of defects in chromosome segregation. However, when the two DNA sequences were added near oriN, frequency of anucleate cells decreased to 1%. In these cells, the origin (argG) regions were localized near cell poles, whereas they were randomly distributed in cells without the two DNA sequences. These results suggest that the two DNA sequences in and downstream of the dnaA gene participate in correct positioning of the replication origin region within the cell and that this function is associated with accurate chromosome segregation in B. subtilis.     

Replication of M13 oriC bacteriophages in Escherichia coli rep mutant is dependent on the cloned Escherichia coli replication origin.

The involvement of the Escherichia coli rep protein in the replication of M13 chimeric deoxyribonucleic acids (DNAs) carrying the E. coli chromosomal DNA replication origin (oriC) has been examined. Previous studies indicate that the cloning of a 3,550-base-pair sequence of chromosomal DNA containing oriC into an M13 vector allows extensive replication of the M13 oriC chimeric DNA in an E. coli rep-3 mutant. We have extended these studies by preparing a 330-base-pair deletion that specifically deletes the oriC sequence in the M13 oriC DNAs, to demonstrate that the replication observed in the rep-3 host is dependent on the cloned origin. Thus, a DNA-unwinding enzyme other than the rep protein may be involved in the strand separation process accompanying replication which initiates at oriC in the M13 oriC chimeric DNAs and in the E. coli chromosome. The rep assay used for assessing the functionality of the cloned oriC is useful for analysis of any rep-independent origin of replication functional in E. coli. A direct selection for a cloned origin of replication is possible in the rep-3 recA56 host. Since the cloned origin is nonessential for propagation of the M13 chimeric phage in a rep+ host, mutations in the cloned origin may be constructed, and the mutant phage may be examined by a simple transductional analysis of the rep-3 recA56 mutant strain.     

Conversion to bidirectional replication after unidirectional initiation from R1 plasmid origin integrated at oriC in Escherichia coli

The cell division phenotypes of Escherichia coli with its chromosome replication driven by oriR (from plasmid R1) were examined by fluorescence microscopy and flow cytometry. Chromosome replication patterns in these strains were followed by marker frequency analyses. In one of the strains, the unidirectional oriR was integrated so that the replication fork moved clockwise from the oriC region, and bacterial growth and division were similar to those of the wild-type parent. The bacteria were able to convert the unidirectional initiation from oriR into bidirectional replication. The site for conversion of uni- to bidirectional replication seemed to be localized and could be mapped genetically within 6 min to the immediate right of the minimal oriC . Replication starting in the counterclockwise direction from the R1 replicon integrated at the same site in the opposite orientation could not be described as either bi- or unidirectional, as no single predominant origin could be discerned from the more or less flat marker frequency pattern. These strains also showed extensive filamentation, irregular nucleoid distribution and the presence of anucleate cells, indicative of segregation and division defects. Comparison among intR1 derivatives differing in the position of the integrated oriR relative to the chromosome origin suggested that the oriC sequence itself was dispensable for the conversion to bidirectionality. However, passage of the replication fork over the 6 min region to the right of oriC seemed important for the bidirectional replication pattern and normal cell division phenotype.     

The 245 base-pair oriC sequence of the E. coli chromosome directs bidirectional replication at an adjacent region

The replication origin of the E. coli K-12 chromosome has been isolated as autonomously replicating molecules(oriC plasmid), and the DNA region essential for replicating function(oriC) has been localized to a sequence of 232-245 base-pairs(bp) by deletion analysis. In this report, the functional role of oriC was analysed by using an in vitro replication system and various OriC+ and OriC- plasmids previously constructed. The results obtained were summarized as follows: (1) The oriC sequence contained information enough to direct bidirectional replication. (2) The actual DNA replication began at a region near, but outside, oriC and progressed bidirectionally. (3) Initiation of DNA synthesis at the specific region required the dnaA-complementing fraction from cells harboring a dnaA-carrying plasmid.     

migS, a cis-acting site that affects bipolar positioning of oriC on the Escherichia coli chromosome

During replication of the Escherichia coli chromosome, the replicated Ori domains migrate towards opposite cell poles, suggesting that a cis-acting site for bipolar migration is located in this region. To identify this cis-acting site, a series of mutants was constructed by splitting subchromosomes from the original chromosome. One mutant, containing a 720 kb subchromosome, was found to be defective in the bipolar positioning of oriC. The creation of deletion mutants allowed the identification of migS, a 25 bp sequence, as the cis-acting site for the bipolar positioning of oriC. When migS was located at the replication terminus, the chromosomal segment showed bipolar positioning. migS was able to rescue bipolar migration of plasmid DNA containing a mutation in the SopABC partitioning system. Interestingly, multiple copies of the migS sequence on a plasmid in trans inhibited the bipolar positioning of oriC. Taken together, these findings indicate that migS plays a crucial role in the bipolar positioning of oriC. In addition, real-time analysis of the dynamic morphological changes of nucleoids in wild-type and migS mutants suggests that bipolar positioning of the replicated oriC contributes to nucleoid organization.     

Periodic formation of the oriC complex of Escherichia coli.

We examined formation of an oriC-membrane complex through the chromosome replication cycle by dot-blot hybridization using an oriC plasmid as a probe. In a wild-type culture synchronized for chromosome replication, oriC complex formation was observed periodically and transiently corresponding to the replication initiation event. Prior to initiation of replication the oriC complex was recovered in the outer membrane fraction as well as at the time of initiation of replication. Moreover, periodic formation of the oriC complex was observed even when further initiation of replication was suppressed by culturing an initiation ts mutant at the restrictive temperature. Similar periodic formation of the oriC complex was also observed when DNA elongation was inhibited by addition of nalidixic acid to the culture. However, the second periodic peak did not appear when rifampicin or chloramphenicol was added. Cells which formed the oriC complex at the restrictive temperature could immediately initiate chromosome replication when the cells were transferred to the permissive temperature. We conclude that the oriC region of Escherichia coli forms a specific complex periodically just before and at the time of initiation of chromosome replication and that oriC complex formation is a prerequisite for initiation of chromosome replication.     

MukB colocalizes with the oriC region and is required for organization of the two Escherichia coli chromosome arms into separate cell halves

The circular Escherichia coli chromosome is organized by bidirectional replication into two equal left and right arms (replichores). Each arm occupies a separate cell half, with the origin of replication (oriC) at mid-cell. E. coli MukBEF belongs to the ubiquitous family of SMC protein complexes that play key roles in chromosome organization and processing. In mukBEF mutants, viability is restricted to low temperature with production of anucleate cells, reflecting chromosome segregation defects. We show that in mukB mutant cells, the two chromosome arms do not separate into distinct cell halves, but extend from pole to pole with the oriC region located at the old pole. Mutations in topA, encoding topoisomerase I, do not suppress the aberrant positioning of chromosomal loci in mukB cells, despite suppressing the temperature-sensitivity and production of anucleate cells. Furthermore, we show that MukB and the oriC region generally colocalize throughout the cell cycle, even when oriC localization is aberrant. We propose that MukBEF initiates the normal bidirectional organization of the chromosome from the oriC region.     

Initiation signals for complementary strand DNA synthesis in the region of the replication origin of the Escherichia coli chromosome.

We have used an in vivo plasmid-phi X174 packaging system to detect replication initiation signals in the region of the replication origin (oriC) of the Escherichia coli chromosome. The results obtained are summarized as follows: (i) Neither within nor close to oriC effective signals for initiating complementary strand synthesis could be detected. We conclude that initiation mechanisms for leading and lagging strand synthesis at oriC are not identical to any known priming mechanism of DNA synthesis. (ii) At least five signals that can function as complementary strand origins on ss-plasmid DNA are located in a region about 2000-3300 base pairs away from oriC in the clockwise direction on the chromosome. We suggest that these signals are protein n' like recognition sequences since they are dependent for their activity on dnaB protein and show sequence similarities to other putative n' recognition sequences. Surprisingly, some of the signals are located on the template for leading strand synthesis.     

Effect of dam methylation on the activity of the E. coli replication origin, oriC.

Methylation of GATC sites by the dam methylase is required for efficient initiation of DNA replication at the replication origin, oriC, of Escherichia coli. This is demonstrated by the inability of minichromosomes to be maintained in dam mutant strains. The requirement for methylated GATC sites is less stringent in vitro than in vivo. The time required for complete methylation of the origin region apparently determines the minimal spacing of replication forks on the chromosome.     

Genetic mapping of the chromosomal replication origin of Salmonella typhimurium.

Two hundred strains of Escherichia coli harboring Filv+ plasmids which carry a segment of the Salmonella typhimurium chromosome were isolated independently. Among them, two strains were found to harbor F' plasmids that are able to replicate in Hfr cells of E. coli; i.e., they carry a site designated poh (permissive on Hfr) of the S. typhimurium chromosome. The poh site is presumably identical with the replication origin (oriC) of the bacterial chromosome. These two plasmids carry the dnaA-uncA-rbs-ilv-cya-metE region of the chromosome of S. typhimurium. Other F' plasmids which only carried the ilv-cya-metE region were unable to be maintained in Hfr cells. The poh site (= oriC) of S. typhimurium thus is located in the uhp-ilv region of the chromosome. The two plasmids carrying the poh site of S. typhimurium can suppress the temperature-sensitive character of an E. coli mutant that carries the temperature-sensitive dnaA46 allele, when the plasmids exist in the mutant cells. This suggests that the dnaA chromosome in place of the dnaA gene product of E. coli itself. The ability of the plasmids carrying the poh site of S. typhimurium to replicate in Hfr cells of E. coli suggests that the replication system of E. coli can recognize the Salmonella replication origin.     

Affinity of two different regions of the chromosome to the outer membrane of Escherichia coli.

It was found that DNA associated with the outer membrane of Escherichia coli K-12 is enriched for two different regions of the chromosome, which are both on the 5.9-megadalton EcoRI fragment containing the replication origin, oriC. One region overlaps oriC, whereas the other region was found to be associated with a 1-megadalton EcoRI-BamHI fragment located within the atp operon.     

Chromosomal insertions localized around oriC affect the cell cycle in Escherichia coli

The present work reports the effects of localized insertions around the origin of Escherichia coli chromosome, oriC, on cell cycle parameters. These insertions cause an increase of the C period with an inverse correlation to the distance from oriC. In addition, Omega insertion near oriC causes an increase in the number of replication forks per chromosome, n, and Tn10 insertion causes a decrease in growth rate. We found that the same insertion positioned in another region of the chromosome, outside of oriC, has a negligible effect on the C period. Marker frequency analysis suggests a slower replication velocity along the whole chromosome. We propose that the insertions positioned at less than 2 kbp from oriC could create a structural alteration in the origin of replication that would result in a longer C period. Flow cytometry reveals that asynchrony is not associated with these alterations.     

Host controlled plasmid replication: Escherichia coli minichromosomes

Escherichia coli minichromosomes are plasmids replicating exclusively from a cloned copy of oriC, the chromosomal origin of replication. They are therefore subject to the same types of replication control as imposed on the chromosome. Unlike natural plasmid replicons, minichromosomes do not adjust their replication rate to the cellular copy number and they do not contain information for active partitioning at cell division. Analysis of mutant strains where minichromosomes cannot be established suggest that their mere existence is dependent on the factors that ensure timely once per cell cycle initiation of replication. These observations indicate that replication initiation in E. coli is normally controlled in such a way that all copies of oriC contained within the cell, chromosomal and minichromosomal, are initiated within a fairly short time interval of the cell cycle. Furthermore, both replication and segregation of the bacterial chromosome seem to be controlled by sequences outside the origin itself.