Initiation of DNA replication in Escherichia coli

Fundamental principles in bacterial physiology-history, recent progress, and the future with focus on cell size control: a review

Bacterial physiology is a branch of biology that aims to understand overarching principles of cellular reproduction. Many important issues in bacterial physiology are inherently quantitative, and major contributors to the field have often brought together tools and ways of thinking from multiple disciplines. This article presents a comprehensive overview of major ideas and approaches developed since the early 20th century for anyone who is interested in the fundamental problems in bacterial physiology. This article is divided into two parts. In the first part (sections 1-3), we review the first 'golden era' of bacterial physiology from the 1940s to early 1970s and provide a complete list of major references from that period. In the second part (sections 4-7), we explain how the pioneering work from the first golden era has influenced various rediscoveries of general quantitative principles and significant further development in modern bacterial physiology. Specifically, section 4 presents the history and current progress of the 'adder' principle of cell size homeostasis. Section 5 discusses the implications of coarse-graining the cellular protein composition, and how the coarse-grained proteome 'sectors' re-balance under different growth conditions. Section 6 focuses on physiological invariants, and explains how they are the key to understanding the coordination between growth and the cell cycle underlying cell size control in steady-state growth. Section 7 overviews how the temporal organization of all the internal processes enables balanced growth. In the final section 8, we conclude by discussing the remaining challenges for the future in the field.

Escherichia coli DnaA protein--phospholipid interactions: in vitro and in vivo

DNA replication in Escherichia coli is controlled at the initiation stage, possibly by regulation of the essential activity of DnaA protein. The cellular membrane has long been hypothesized to be involved in chromosomal replication. Accumulating evidence, both in vitro and in vivo, that supports the importance of membrane phospholipids influencing the initiation activity of DnaA is reviewed.

Characterization of the oriC region of Mycobacterium smegmatis

A 3.5-kb DNA fragment containing the dnaA region of Mycobacterium smegmatis has been hypothesized to be the chromosomal origin of replication or oriC (M. Rajagopalan et al., J. Bacteriol. 177:6527-6535, 1995). This region included the rpmH gene, the dnaA gene, and a major portion of the dnaN gene as well as the rpmH-dnaA and dnaA-dnaN intergenic regions. Deletion analyses of this region revealed that a 531-bp DNA fragment from the dnaA-dnaN intergenic region was sufficient to exhibit oriC activity, while a 495-bp fragment from the same region failed to exhibit oriC activity. The oriC activities of plasmids containing the 531-bp sequence was less than the activities of those containing the entire dnaA region, suggesting that the regions flanking the 531-bp sequence stimulated oriC activity. The 531-bp region contained several putative nine-nucleotide DnaA-protein recognition sequences [TT(G/C)TCCACA] and a single 11-nucleotide AT-rich cluster. Replacement of adenine with guanine at position 9 in five of the putative DnaA boxes decreased oriC activity. Mutations at other positions in two of the DnaA boxes also decreased oriC activity. Deletion of the 11-nucleotide AT-rich cluster completely abolished oriC activity. These data indicate that the designated DnaA boxes and the AT-rich cluster of the M. smegmatis dnaA-dnaN intergenic region are essential for oriC activity. We suggest that M. smegmatis oriC replication could involve interactions of the DnaA protein with the putative DnaA boxes as well as with the AT-rich cluster.

Control of cyclic chromosome replication in Escherichia coli

The biochemical basis for cyclic initiation of bacterial chromosome replication is reviewed to define the processes involved and to focus on the putative oscillator mechanism which generates the replication clock. The properties required for a functional oscillator are defined, and their implications are discussed. We show that positive control models, but not negative ones, can explain cyclic initiation. In particular, the widely accepted idea that DnaA protein controls the timing of initiation is examined in detail. Our analysis indicates that DnaA protein is not involved in the oscillator mechanism. We conclude that the generations of a single leading to cyclic initiation is separate from the initiation process itself and propose a heuristic model to focus attention on possible oscillator mechanisms.

The stringent response blocks DNA replication outside the ori region in Bacillus subtilis and at the origin in Escherichia coli

When the Bacillus subtilis dnaB37 mutant, defective in initiation, is returned to permissive temperature after growth at 45 degrees C, DNA replication is synchronized. Under these conditions, we have shown previously that DNA replication is inhibited when the Stringent Response is induced by the amino acid analogue, arginine hydroxamate. We have now shown, using DNA-DNA hybridization analysis, that substantial replication of the oriC region nevertheless occurs during the Stringent Response, and that replication inhibition is therefore implemented downstream from the origin. On the left arm, replication continues for at least 190 x 10(3) base-pairs to the gnt gene and for a similar distance on the right arm to the gerD gene. When the Stringent Response is lifted, DNA replication resumed downstream from oriC on both arms, confirming that DNA replication is regulated at a post-initiation level during the Stringent Response in B. subtilis. Resumption of DNA synthesis following the lifting of the Stringent Response did not require protein or RNA synthesis or the initiation protein DnaB. We suggest, therefore, that a specific control region, involving Stringent Control sites, facilitate reversible inhibition of fork movement downstream from the origin via modifications of a replisome component during the Stringent Response. In contrast, in Escherichia coli, induction of the Stringent Response appears to block initiation of DNA replication at oriC itself. No DNA synthesis was detected in the oriC region and, upon lifting the Stringent Response, replication occurred from oriC. Post-initiation control in B. subtilis therefore results in duplication of many key genes involved in growth and sporulation. We discuss the possibility that such a control might be linked to differentiation in this organism.

Replication of plasmids in gram-negative bacteria

Replication of plasmid deoxyribonucleic acid (DNA) is dependent on three stages: initiation, elongation, and termination. The first stage, initiation, depends on plasmid-encoded properties such as the replication origin and, in most cases, the replication initiation protein (Rep protein). In recent years the understanding of initiation and regulation of plasmid replication in Escherichia coli has increased considerably, but it is only for the ColE1-type plasmids that significant biochemical data about the initial priming reaction of DNA synthesis exist. Detailed models have been developed for the initiation and regulation of ColE1 replication. For other plasmids, such as pSC101, some hypotheses for priming mechanisms and replication initiation are presented. These hypotheses are based on experimental evidence and speculative comparisons with other systems, e.g., the chromosomal origin of E. coli. In most cases, knowledge concerning plasmid replication is limited to regulation mechanisms. These mechanisms coordinate plasmid replication to the host cell cycle, and they also seem to determine the host range of a plasmid. Most plasmids studied exhibit a narrow host range, limited to E. coli and related bacteria. In contrast, some others, such as the IncP plasmid RK2 and the IncQ plasmid RSF1010, are able to replicate in nearly all gram-negative bacteria. This broad host range may depend on the correct expression of the essential rep genes, which may be mediated by a complex regulatory mechanism (RK2) or by the use of different promoters (RSF1010). Alternatively or additionally, owing to the structure of their origin and/or to different forms of their replication initiation proteins, broad-host-range plasmids may adapt better to the host enzymes that participate in initiation. Furthermore, a broad host range can result when replication initiation is independent of host proteins, as is found in the priming reaction of RSF1010.

DnaA protein overproduction abolishes cell cycle specificity of DNA replication from oriC in Escherichia coli

Initiation of DNA replication from oriC in Escherichia coli takes place at a specific time in the cell division cycle, whether the origin is located on a chromosome or a minichromosome, and requires participation of the product of the dnaA gene. The effects of overproduction of DnaA protein on the cell cycle specificity of the initiation event were determined by using minichromosome replication as the assay system. DnaA protein was overproduced by inducing the expression of plasmid-encoded dnaA genes under control of either the ptac or lambda pL promoter. Induction of DnaA protein synthesis caused a burst of minichromosome replication in cells at all ages in the division cycle. The magnitude of the burst was consistent with the initiation of one round of replication per minichromosome in all cells. The replication burst was followed by a period of reduced minichromosome replication, with the reduction being greater at 30 than at 41 degrees C. The results support the idea that the DnaA protein participates in oriC replication at a stage that is limiting for initiation. Excess DnaA protein enabled all cells to achieve the state required for initiation of DNA polymerization by either effecting or overriding the normal limiting process.

Rate, origin, and bidirectionality of Caulobacter chromosome replication as determined by pulsed-field gel electrophoresis

Cell division in Caulobacter crescentus yields progeny cells that differ with respect to cell structure and developmental program. Chromosome replication initiates in the daughter stalked cell but is repressed in the daughter swarmer cell until later in the cell cycle. To study cell-type-specific DNA initiation, chromosome replication was directly analyzed by pulsed-field gel electrophoresis. Analysis of Dra I restriction fragments of DNA taken at various times from synchronized cell cultures labeled with 2'-deoxy[3H]guanosine has allowed us to determine the origin of DNA replication, the rate and direction of fork movement, and the order of gene replication. The first labeled Dra I fragment to appear contains the site of replication initiation. Based on the correlation of the physical and genetic maps derived by Ely and Gerardot [Ely, B. & Gerardot, C. J. (1988) Gene 68, 323-333], the origin was localized to a 305-kilobase fragment containing the rrnA gene. Furthermore, the sequential replication through unmapped Dra I fragments has enabled us to localize their positions on the genome. The order of appearance of labeled restriction fragments revealed that the chromosome replicates bidirectionally at a fork movement rate of 21 kilobases per minute.

Functions of the DnaA protein of Escherichia coli in replication and transcription

The function of DnaA protein as a replisome organizer in the initiation of DNA replication is reviewed. A model is presented showing the construction of two basic types of DnaA-dependent replication origin. New data demonstrate that the dnaA box-DnaA protein complex is a transcription terminator. Only one orientation of the dnaA box results in termination of transcription. Mutation of the dnaA box within the dnaA reading frame shows that DnaA-mediated transcription termination has a role in the autoregulation of the dnaA gene.

Termination of the Escherichia coli asnC transcript. The DnaA protein/dnaA box complex blocks transcribing RNA polymerase

Genes clockwise of oriC, the Escherichia coli replication origin (oriC-mioC-asnC), show anticlockwise transcription. The intergenic region between mioC and asnC contains both a terminator and a consensus DnaA-protein-binding site (dnaA box). We analysed termination in this region using galK expression to monitor for transcription. About 50% of the asnC transcripts were not terminated, and about 25% terminated at the asnC terminator. We found that the DnaA protein/dnaA box complex acts as a terminator of transcription for about 25% of the transcripts. Its efficiency could be increased by raising the level of DnaA protein, or it could be inactivated by deletion in the dnaA box or by thermal denaturation of the DnaA protein.

Transcription in the region of the replication origin, oriC, of Escherichia coli: termination of asnC transcripts

Transcription from the asnC promoter was found to proceed through the replication origin, oriC, into the gidA gene of Escherichia coli. Between 10% and 20% of asnC transcripts reached oriC in vivo. Termination sites in the intergenic region between asnC and mioC and within mioC were determined in vivo and in vitro using S1 mapping. Only about 10% of the transcripts terminated at the asnC terminator in vivo. DnaA protein dependent termination was observed close to the binding site, dnaA box, for DnaA protein. In the in vitro replication system asnC transcripts did not reach oriC, suggesting that asnC transcripts are not involved in the initiation of replication, contrary to mioC transcripts. We suggest that oriC and mioC might have been transposed during evolution into an asnC regulation.