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.     

Analysis of a model for minichromosome segregation in Escherichia coli

The present article contains a theoretical, quantitative analysis of the implications of the Helmstetter-Leonard model (1987, J. molec. Biol. 197, 195-204.) for the segregation of chromosomal DNA in Escherichia coli, on the expected copy-number distribution of minichromosomes in a culture in steady-state exponential growth. According to the model, two determinants are involved in the mechanism of chromosome segregation: a partition system that assures the equal allotment of chromosomes between daughter cells at cell division, and a locus within the minimal oriC region that specifies the attachment site of the chromosomes to the cell envelope at initiation of replication. There are many parameters that must be taken into account in such a study, and since some of them are probabilistic in nature, a strictly analytical approach is not feasible and we had to resort to computer simulation. A wide range of parameter values was tested, in all combinations. The minichromosome copy-number distributions obtained all had a prominent mode equal to the number of oriC binding sites and their main features were determined essentially by that and very little by any of the other parameters of the model. In order to avoid the unrealistic situation in which this one feature completely dominates the results, the original model was modified so that each individual minichromosome is no longer required to replicate during every cell generation, by introducing a limit to the number of unsuccessful attempts to locate a suitable binding site. The copy-number distributions predicted by this version of the model are quantitatively and qualitatively very different and depend on all the components of the model. The simulation results are sufficiently well-behaved to allow consideration as to whether a particular empirical minichromosome copy-number distribution--when such data become available--could in fact be governed by the proposed model; it may even be possible to get a rough estimate for the different parameters involved.     

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.     

Coordinate initiation of chromosome and minichromosome replication in Escherichia coli.

Escherichia coli minichromosomes harboring as little as 327 base pairs of DNA from the chromosomal origin of replication (oriC) were found to replicate in a discrete burst during the division cycle of cells growing with generation times between 25 and 60 min at 37 degrees C. The mean cell age at minichromosome replication coincided with the mean age at initiation of chromosome replication at all growth rates, and furthermore, the age distributions of the two events were indistinguishable. It is concluded that initiation of replication from oriC is controlled in the same manner on minichromosomes and chromosomes over the entire range of growth rates and that the timing mechanism acts within the minimal oriC nucleotide sequence required for replication.     

Polar localization of the Escherichia coli oriC region is independent of the site of replication initiation

The location of the origin-linked region of the Escherichia coli chromosome was analysed in strains lacking the core origin locus, oriC. In these strains, which initiate replication from F factors integrated at different locations around the chromosome, origin-linked DNA remains localized near the cell poles, as in wild-type cells. In contrast, minichromosomes containing 7 kb of chromosomal DNA including oriC are generally excluded from the ends of the cell. Thus, we propose that positioning of the wild-type origins at the poles is not a function of their order of replication but a sequence-specific phenomenon. It is proposed that there are centromere-like sequences, bordering the wild-type origin of replication, which are used by host mechanisms to direct the proper placement of the origin region of the chromosome. This function, combined with other host processes, may assure efficient segregation of the E. coli chromosome.     

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 μm, 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.     

Distribution of minichromosomes in individual Escherichia coli cells: implications for replication control

A novel method was devised to measure the number of plasmids in individual Escherichia coli cells. With this method, involving measurement of plasmid-driven expression of the green fluorescent protein gene by flow cytometry, the copy number distribution of a number of different plasmids was measured. Whereas natural plasmids had fairly narrow distributions, minichromosomes, which are plasmids replicating only from a cloned oriC copy, have a wide distribution, suggesting that there is no copy number control for minichromosomes. When the selection pressure (kanamycin concentration) for minichromosomes was increased, the copy number of minichromosomes was also increased. At up to 30 minichromosomes per host chromosome, replication and growth of the host cell was unaffected. This is evidence that there is no negative element for initiation control in oriC and that there is no incompatibility between oriC located on the chromosome and minichromosome. However, higher copy numbers led to integration of the minichromosomes at the chromosomal oriC and to initiation asynchrony of the host chromosome. At a minichromosome copy number of approximately 30, the cell's capacity for synchronous initiation is exceeded and free minichromosomes will compete out the chromosome to yield inviable cells, unless the minichromosomes are incorporated into the chromosome.     

Different effects of mioC transcription on initiation of chromosomal and minichromosomal replication in Escherichia coli.

The mioC gene, which neighbors the chromosomal origin of replication (oriC) in Escherichia coli, has in a number of studies been implicated in the control of oriC initiation on minichromosomes. The present work reports on the construction of cells carrying different mioC mutations on the chromosome itself. Flow cytometry was employed to study the DNA replication control and growth pattern of the resulting mioC mutants. All parameters measured (growth rate, cell size, DNA/cell, number of origins per cell, timing of initiation) were the same for the wild type and all the mioC mutant cells under steady state growth and after different shifts in growth medium and after induction of the stringent response. It may be concluded that the dramatic effects of mioC mutations reported for minichromosomes are not observed for chromosomal replication and that the mioC gene and gene product is of little importance for the control of initiation. The data demonstrate that a minichromosome is not necessarily a valid model for chromosomal replication.     

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.     

Re-replication from non-sequesterable origins generates three-nucleoid cells which divide asymmetrically

In rapidly growing Escherichia coli cells replication cycles overlap and initiation occurs at multiple replication origins (oriCs). All origins within a cell are initiated essentially in synchrony and only once per cell cycle. Immediate re-initiation of new origins is avoided by sequestration, a mechanism dependent on the SeqA protein and Dam methylation of GATC sites in oriC. Here, GATC sites in oriC were changed to GTTC. This reduced the sequestration to essentially the level found in SeqA-less cells. The mutant origins underwent re-initiation, showing that the GATC sites in oriC are required for sequestration. Each re-initiation eventually gave rise to a cell containing an extra nucleoid. The three-nucleoid cells displayed one asymmetrically placed FtsZ-ring and divided into a two-nucleoid cell and a one-nucleoid cell. The three nucleoid-cells thus divided into three daughters by two consecutive divisions. The results show that extra rounds of replication cause extra daughter cells to be formed prematurely. The fairly normal mutant growth rate and size distribution show, however, that premature rounds of replication, chromosome segregation, and cell division are flexibly accommodated by the existing cell cycle controls.     

The requirement of IHF protein for extrachromosomal replication of the Escherichia coli oriC in a mutant deficient in DNA polymerase I activity

It is shown here that plasmids containing the replication origin of Escherichia coli (oriC) cannot replicate in an extrachromosomal state in E. coli cells with the polA1hip3 double mutation. This E. coli mutant is deficient in the polymerizing function of DNA polymerase I (Pol I) and is unable to produce functional IHF protein. The inability of the oriC minichromosomes to replicate in the absence of IHF is dependent on the absence of Pol I; cells with the polA+himA- or polA+hip- mutation, which are deficient in the alpha and beta subunits of the IHF heterodimer, respectively, can support replication of the oriC replicons. We propose that IHF-deficient cells utilize an alternative pathway of the DNA replication in which Pol I is required. In vitro DNA binding assays revealed that the IHF binding site resides between the oriC coordinates 110 and 122 and is adjacent to the DnaA "box" 1. Within the area protected by IHF we found at least 1 out of 11 GATC methylation sites present in oriC. The consequences of lack of IHF protein binding to the oriC and the indirect effects of the IHF deficiency on the oriC replication are discussed.     

The segregation of Escherichia coli minichromosomes constructed in vivo by recombineering

Circularized regions of the chromosome containing the origin of replication, oriC, can be maintained as autonomous minichromosomes, oriC plasmids. We show that oriC plasmids containing precise, pre-determined segments of the chromosome can be generated by a simple in vivo recombineering technique. We generated two such plasmids carrying fluorescent markers. These were transferred to a recipient strain with a different fluorescent marker near the chromosomal copy of oriC. Thus the fates of the oriC plasmid and chromosomal origins could be followed independently in living cells by fluorescence microscopy. In contrast to a previous report, we show that there is a strong tendency of oriC plasmid copies to accumulate at the cell center as a single or double focus at the plane of cell division. This is not simply due to exclusion from the nucleoid space but rather appears to be a specific recognition and retention of the plasmid by some central-located cell site.     

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.     

Independent segregation of the two arms of the Escherichia coli ori region requires neither RNA synthesis nor MreB dynamics

The mechanism of Escherichia coli chromosome segregation remains elusive. We present results on the simultaneous tracking of segregation of multiple loci in the ori region of the chromosome in cells growing under conditions in which a single round of replication is initiated and completed in the same generation. Loci segregated as expected for progressive replication-segregation from oriC, with markers placed symmetrically on either side of oriC segregating to opposite cell halves at the same time, showing that sister locus cohesion in the origin region is local rather than extensive. We were unable to observe any influence on segregation of the proposed centromeric site, migS, or indeed any other potential cis-acting element on either replication arm (replichore) in the AB1157 genetic background. Site-specific inhibition of replication close to oriC on one replichore did not prevent segregation of loci on the other replichore. Inhibition of RNA synthesis and inhibition of the dynamic polymerization of the actin homolog MreB did not affect ori and bulk chromosome segregation.     

Functional analysis of minichromosome replication: bidirectional and unidirectional replication from the Escherichia coli replication origin, oriC.

Replicating molecules of minichromosomes pCM959 and pOC24 were analyzed by electron microscopy. Replication of pCM959 proceeded bidirectionally from the replication origin, oriC, in about 60% of the molecules; the rest of the molecules replicated unidirectionally in either direction. pOC24, in which deoxyribonucleic acid to the right (clockwise) of the oriC segment is deleted, seemed to replicate predominantly unidirectionally counterclockwise from oriC.     

A large dispersed chromosomal region required for chromosome segregation in sporulating cells of Bacillus subtilis

The cis-acting sequences required for chromosome segregation are poorly understood in most organisms, including bacteria. Sporulating cells of Bacillus subtilis undergo an unusual asymmetric cell division during which the origin of DNA replication (oriC) region of the chromosome migrates to an extreme polar position. We have now characterized the sequences required for this migration. We show that the previously characterized soj-spo0J chromosome segregation system is not essential for chromosome movement to the cell pole, so this must be driven by an additional segregation mechanism. Observations on a large set of precisely engineered chromosomal inversions and translocations have identified a polar localization region (PLR), which lies approximately 150-300 kbp to the left of oriC. Surprisingly, oriC itself has no involvement in this chromosome segregation system. Dissection of the PLR showed that it has internal functional redundancy, reminiscent of the large diffuse centromeres of most eukaryotic cells.     

Initiation of Escherichia coli minichromosome replication at oriC and at protein n'' recognition sites. Two modes for initiating DNA synthesis in vitro.

The start sites for leading and lagging DNA strands were determined in vitro with minichromosomes as templates. Fragments from replication intermediates were analyzed by hybridization to single-stranded probes. Leading strand synthesis in the counterclockwise direction was found to originate in or close to (position 248 to -44) the minimal origin. Complementary lagging strand synthesis started several positions to the left outside of oriC. The results suggest in addition a concerted synthesis of leading and lagging strands following the dnaA directed assembly of initiation proteins at double-stranded oricC DNA (pre-replisome). In addition, DNA synthesis could initiate at protein n' recognition sequences located within and clockwise to the asnA gene. Initiation at n' sites was dependent on protein i activity, whereas leading and lagging strand initiation in the oriC region was not affected by protein i. Our results argue against an involvement of the phi X174-type primosome in the initiation of discontinuous DNA synthesis at oriC. An alternative function is suggested.     

Stable co-existence of separate replicons in Escherichia coli is dependent on once-per-cell-cycle initiation

DNA replication in most organisms is regulated such that all chromosomes are replicated once, and only once, per cell cycle. In rapidly growing Escherichia coli, replication of eight identical chromosomes is initiated essentially simultanously, each from the same origin, oriC. Plasmid-borne oriC sequences (minichromosomes) are also initiated in synchrony with the eight chromosomal origins. We demonstrate that specific inactivation of newly formed, hemimethylated origins (sequestration) was required for the stable co-existence of oriC-dependent replicons. Cells in which initiations were not confined to a short interval in the cell cycle (carrying mutations in sequestration or initiation genes or expressing excess initiator protein) could not support stable co-existence of several oriC-dependent replicons. The results show that such stable co-existence of oriC-dependent replicons is dependent on both a period of sequestration that is longer than the initiation interval and a reduction of the initiation potential during the sequestration period. These regulatory requirements are the same as those required to confine initiation of each replicon to once, and only once, per cell cycle.