Expression of accumulated capacity for initiation of chromosome and minichromosome replication in dnaA mutants of Escherichia coli

mioC transcription, initiation of replication, and the eclipse in Escherichia coli

The potential role of mioC transcription as a negative regulator of initiation of chromosome replication in Escherichia coli was evaluated. When initiation was aligned by a shift of dnaC2(Ts) mutants to nonpermissive temperature (40 degrees C), mioC transcript levels measured at the 5' end or reading through oriC disappeared within one mass doubling. Upon return to permissive temperature (30 degrees C), the transcripts reappeared coordinately about 15 min after the first synchronized initiation and then declined sharply again 10 min later, just before the second initiation. Although these observations were consistent with the idea that mioC transcription might have to be terminated prior to initiation, it was found that the interval between initiations at permissive temperature, i.e., the eclipse period, was not influenced by the time required to shut down mioC transcription, since the eclipse was the same for chromosomes and minichromosomes which lacked mioC transcription. This finding did not, in itself, rule out the possibility that mioC transcription must be terminated prior to initiation of replication, since it might normally be shut off before initiation, and never be limiting, even during the eclipse. Therefore, experiments were performed to determine whether the continued presence of mioC transcription during the process of initiation altered the timing of initiation. It was found that minichromosomes possessing a deletion in the DnaA box upstream of the promoter transcribed mioC continuously and replicated with the same timing as those that either shut down expression prior to initiation or lacked expression entirely. It was further shown that mioC transcription was present throughout the induction of initiation by addition of chloramphenicol to a dnaA5(Ts) mutant growing at a semipermissive temperature. Thus, transcription through oriC emanating from the mioC gene promoter is normally inhibited prior to initiation of replication by the binding of DnaA protein, but replication can initiate with the proper timing even when transcription is not shut down; i.e., mioC does not serve as a negative regulator of initiation. It is proposed, however, that the reappearance and subsequent disappearance of mioC transcription during a 10-min interval at the end of the eclipse serves as an index of the minimum time required for the establishment of active protein-DNA complexes at the DnaA boxes in the fully methylated origin region of the chromosome. On this basis, the eclipse constitutes the time for methylation of the newly formed DNA strands (15 to 20 min at 30 degrees C) followed by the time for DnaA protein to bind and activate oriC for replication (10 min).

Inhibition of protein synthesis transiently stimulates initiation of minichromosome replication in Escherichia coli

Replication of oriC-dependent minichromosomes was found to be transiently stimulated when protein synthesis was inhibited by the addition of chloramphenicol. Initiation of replication was also induced by amino acid starvation of relA mutant strains and a nutritional upshift. The results are explained on the basis that these treatments rendered RNA polymerase more available for participation in the initiation process. As a consequence, the oriC duplex may be transcriptionally activated to an open form, a necessary prerequisite for DNA polymerization.

Regulation of transcription of the chromosomal dnaA gene of Escherichia coli

By comparative S1 analysis we investigated the in vivo regulation of transcription of the chromosomal dnaA gene coding for a protein essential for the initiation of replication at the chromosomal origin. Inactivation of the protein in dnaA mutants results in derepression, whereas excess DnaA protein (presence of a DnaA overproducing plasmid) leads to repression of dnaA transcription. Both dnaA promoters are subject to autoregulation allowing modulation of transcriptional efficiency by at least 20-fold. Increasing the number of oriC sequences (number of DnaA binding sites) in the cell by introducing oriC plasmids leads to a derepression of transcription. Autoregulation and binding to oriC suggest that the DnaA protein exerts a major role in the regulation of the frequency of initiation at oriC. The efficiency of transcription of the dnaA2 promoter is reduced in the absence of dam methylation, which is involved in the regulation of oriC replication.

Discontinuity in DNA replication during expression of accumulated initiation potential in dnaA mutants of Escherichia coli

Potential for initiation of chromosome replication present in temperature-sensitive, initiation-defective dnaA5 mutants of Escherichia coli B/r incubated at nonpermissive temperature was expressed by shifting to a more permissive temperature (25 degrees C). Upon expression of initiation potential, the rate of [3H]thymidine incorporation varied in a bimodal fashion, i.e., there was an initial burst of incorporation, which lasted 10 to 20 min, then a sudden decrease in incorporation, and finally a second rapid increase in incorporation. Analyses of this incorporation pattern indicated that a round of replication initiated upon expression of initiation potential, but DNA polymerization stopped after replication of 5 to 10% of the chromosome. This round of replication appeared to resume about 30 min later coincident with initiation of a second round of replication. The second initiation was unusually sensitive to low concentrations of novobiocin (ca. 1 microgram/ml) when this inhibitor was added in the presence of chloramphenicol. In the absence of chloramphenicol, novobiocin at this concentration had no detectable effect on DNA replication. It is suggested that cis-acting inhibition, attributable to an attempted second initiation immediately after the first, caused the first round to stall until both it and the second round could resume simultaneously. This DNA replication inhibition, probably caused by overinitiation, could be a consequence of restraints on replication in the vicinity of oriC, possibly topological in nature, which limit the minimum interinitiation interval in E. coli.

Initiation of chromosome replication in Escherichia coli after induction of dnaA gene expression from a lac promoter

Escherichia coli HB282 carries a dnaA46(Ts) allele on the chromosome, a wild-type dnaA allele under the control of the lacUV5 promoter on the multicopy plasmid pBC32, and an overproducing lac repressor allele on an F' factor. When the plasmid dnaA gene is repressed, the strain is thermosensitive. After a temporary deficiency in active dnaA protein at nonpermissive temperature, the addition of isopropyl-beta-D-thiogalactopyranoside to the culture was found to produce a burst of initiations within 5 to 10 min at 30% of the origins in 90% of the cells. Initiations then continued at a rate slightly faster than the mass-doubling time such that after 2 h the origin-to-mass ratio of the control culture was restored.

dnaA protein-regulated transcription: effects on the in vitro replication of Escherichia coli minichromosomes

Both initiation of replication and initiation of transcription are influenced by dnaA protein, when minichromosomes are assayed in vitro for dnaA protein complementation. This dnaA protein effect is seen only if minichromosomes are used containing the 16-kd promoter, from which transcription is directed into the minimal origin. Determination of the 16-kd promoter activity both in vivo and in vitro showed that this strong promoter is specifically repressed by dnaA protein. The 16-kd promoter is thus an integral regulatory region of oriC.

Autoregulation of the DNA replication gene dnaA in E. coli K-12

The dnaA gene in E. coli K-12 is required for the initiation of DNA replication. Although the specific function of the dnaA protein is unknown, it has been suggested that it is a regulator of the frequency of initiation. In this paper we report that the expression of both a dnaA-lacZ translational fusion and a dnaA-trpA-lacZ transcriptional fusion in vivo are sensitive to changes in the level of functional dnaA protein. Overproduction of the dnaA gene product leads to a reduction in expression from both fusions while introduction of dnaA- alleles results in an increased expression. Results from a deletion analysis of the dnaA promoter/regulatory region suggest that both dnaA promoters are regulated by the dnaA gene product and that a site between the two promoters is responsible for the regulation. DNAase protection experiments showed that the dnaA protein binds to DNA in the region of the two dnaA promoters. Our results indicate that the dnaA gene product regulates its own synthesis by inhibiting transcription from both of its promoters.