Anders Løbner-Olesen

The role of dam methyltransferase in the control of DNA replication in E. coli

The timing and control of initiation of DNA replication in E. coli was studied under conditions where the cellular level of dam methyltransferase was controlled by a temperature-inducible promoter. Flow cytometry was used to demonstrate that the synchrony of initiation at the several origins within each cell was critically dependent on the level of dam methyltransferase. Initiations were shown to be synchronous only in a narrow temperature range. The data are explained by a model where a newly replicated and therefore hemimethylated oriC is inert for reinitiation. Such a model may be applicable to eukaryotic cells, where classes of origins are initiated in synchrony and only once per cell cycle.

Limiting DNA replication to once and only once.

In Escherichia coli cells, the origin of chromosomal replication is temporarily inactivated after initiation has occurred. Origin sequestration is the first line of defence against over‐initiation, providing a time window during which the initiation potential can be reduced by: (i) titration of DnaA proteins to newly replicated chromosomal elements; (ii) regulation of the activity of the DnaA initiator protein; and (iii) sequestration of the dnaA gene promoter. This review represents the first attempt to consider together older and more recent data on such inactivation mechanisms in order to analyze their contributions to the overall tight replication control observed in vivo. All cells have developed mechanisms for origin inactivation, but those of other bacteria and eukaryotic cells are clearly distinct from those of E. coli. Possible differences and similarities are discussed.

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

SummaryIncreased synthesis of DnaA protein, obtained with plasmids carrying the dnaA gene controlled by the heat inducible λpL 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.

The eclipse period of Escherichia coli

The minimal time between successive initiations on the same origin (the eclipse) in Escherichia coli was determined to be ∼25–30 min. An inverse relationship was found between the length of the eclipse and the amount of Dam methyltransferase in the cell, indicating that the eclipse corresponds to the period of origin hemimethylation. The SeqA protein was absolutely required for the eclipse, and DnaA titration studies suggested that the SeqA protein prevented the binding of multiple DnaA molecules on oriC (initial complex formation). No correlation between the amount of SeqA and eclipse length was revealed, but increased SeqA levels affected chromosome partitioning and/or cell division. This was corroborated further by an aberrant nucleoid distribution in SeqA‐deficient cells. We suggest that the SeqA proteins role in maintaining the eclipse is tied to a function in chromosome organization.

The Escherichia coli SeqA protein destabilizes mutant DnaA204 protein

In wild‐type Escherichia coli cells, initiation of DNA replication is tightly coupled to cell growth. In slowly growing dnaA204 (Ts) mutant cells, the cell mass at initiation and its variability is increased two‐ to threefold relative to wild type. Here, we show that the DnaA protein concentration was two‐ to threefold lower in the dnaA204 mutant compared with the wild‐type strain. The reason for the DnaA protein deficiency was found to be a rapid degradation of the mutant protein. Absence of SeqA protein stabilized the DnaA204 protein, increased the DnaA protein concentration and normalized the initiation mass in the dnaA204 mutant cells. During rapid growth, the dnaA204 mutant displayed cell cycle parameters similar to wild‐type cells as well as a normal DnaA protein concentration, even though the DnaA204 protein was highly unstable. Apparently, the increased DnaA protein synthesis compensated for the protein degradation under these growth conditions, in which the doubling time was of the same order of magnitude as the half‐life of the protein. Our results suggest that the DnaA204 protein has essentially wild‐type activity at permissive temperature but, as a result of instability, the protein is present at lower concentration under certain growth conditions. The basis for the stabilization in the absence of SeqA is not known. We suggest that the formation of stable DnaA–DNA complexes is enhanced in the absence of SeqA, thereby protecting the DnaA protein from degradation.

Translational control and differential RNA decay are key elements regulating postsegregational expression of the killer protein encoded by the parB locus of plasmid R1

The parB locus of plasmid R1, which mediates plasmid stability via postsegregational killing of plasmid-free cells, encodes two genes, hok and sok. The hok gene product is a potent cell-killing protein. The hok gene is regulated at the translational level by the sok gene-encoded repressor, a small anti-sense RNA complementary to the hok mRNA. The hok mRNA is extraordinarily stable, while the sok RNA decays rapidly. The mechanism of postsegregational killing is explained by the following model; the sok RNA molecule rapidly disappears in cells that have lost a parB-carrying plasmid, leading to translation of the stable hok mRNA. Consequently, the Hok protein is synthesized and killing of the plasmid-free cell follows.

Regulation of chromosomal replication by DnaA protein availability in Escherichia coli: effects of the datA region.

Initiation of chromosomal replication in Escherichia coli is dependent on availability of the initiator protein DnaA. We have introduced into E. coli cells plasmids carrying the chromosomal locus datA, which has a high affinity for DnaA. To be able to monitor oriC initiation as a function of datA copy number, we introduced a minichromosome which only replicates from oriC, using a host cell which replicates its chromosome independently of oriC. Our data show that a moderate increase in datA copy number is accompanied by increased DnaA protein synthesis that allows oriC initiation to occur normally, as measured by minichromosome copy number. As datA gene dosage is increased dnaA expression cannot be further derepressed, and the minichromosome copy number is dramatically reduced. Under these conditions the minichromosome was maintained by integration into the chromosome. These findings suggest that the datA locus plays a significant role in regulating oriC initiation, by its capacity to bind DnaA. They also suggest that auto regulation of the dnaA gene is of minor importance in regulation of chromosome initiation.

Expression of the Escherichia coli dam gene

The Escherichia coli dam gene and upstream sequences were cloned from the Kohara phage 4D4. Five promoters were found to contribute to dam gene transcription. PI and P2 (the major promoter) were situated approximately 3.5 kb upstream of the structural gene, P3 was within the aroB gene, P4 was within the urf74.3 gene, and P5 was in the urf74.3‐dam intergenic region. The nucleotide sequence of 2280 bp of DNA containing P1 and P2, was determined and shown to have the potential to encode a protein of approximately 16 kDa between P1, P2, and the aroB gene. This 16 kDa open reading frame has been Identified as aroK, the gene for shikimic acid kinase I. Thus the dam gene is part of an operon containing aroK, aroB, urf74.3, and dam. The transcriptional start points of the promoters were determined. A comparison of their nucleotide sequences suggested that P1‐P4 were all recognized by the σ70 subunit of the RNA polymerase.

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.

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.