Evidence for the involvement of the 16kD gene promoter in initiation of chromosomal replication of Escherichia coli strains carrying a B/r-derived replication origin

Mutational analysis reveals Escherichia coli oriC interacts with both DnaA-ATP and DnaA-ADP during pre-RC assembly

Prior to initiating DNA synthesis, Escherichia coli oriC switches from ORC, comprising initiator DnaA bound at three high-affinity sites, to pre-RC, when additional DnaA molecules interact with low-affinity sites. Two types of low-affinity sites exist: R boxes that bind DnaA-ATP and DnaA-ADP with equal affinity, and I-sites with a three- to fourfold preference for DnaA-ATP. To assess the regulatory role of weak DnaA interactions during pre-RC assembly in vivo, we compared the behaviour of plasmid-borne wild-type oriC with mutants having an increased or decreased number of DnaA-ATP discriminatory I-sites. Increasing the number of discriminatory sites by replacing R5M with I2 inactivated extrachromosomal oriC function. Mutants with no discriminatory sites perturbed host growth and rapidly replaced wild-type chromosomal oriC, but normal function returned if one I-site was restored at either the I2, I3 or R5M position. These observations are consistent with assembly of E. coli pre-RC in vivo from mixtures of DnaA-ATP and DnaA-ADP, with I-site interactions coupling pre-RC assembly to DnaA-ATP levels.

Sequence characteristics required for cooperative binding and efficient in vivo titration of the replication initiator protein DnaA in E. coli

Plasmids carrying the mioC promoter region, which contains two DnaA boxes, R5 and R6 with one misfit to the consensus TT(A)/(T)TNCACA, are as efficient in in vivo titration of the DnaA protein as plasmids carrying a replication-inactivated oriC region with its eight DnaA boxes. Three additional DnaA boxes around the promoter proximal R5 DnaA box were identified and shown by mutational analysis to be necessary for the cooperative binding of DnaA required for titration. These four DnaA boxes are located in the same orientation and with a spacing of two or three base-pairs. The cooperative binding was eliminated by insertion of half a helical turn between any of the DnaA boxes. Titration strongly depends on the presence and orientation of the promoter distal R6 DnaA box located 104 bp upstream of the R5 box as well as neighbouring sequences downstream of R6. Titration depends on the integrity of a 43 bp region containing the R5 DnaA box, while repression of mioC transcription by DnaA, which is dependent on the R5 DnaA box, was independent of the two DnaA boxes downstream of R5. Repression was also independent of the spacing between the two upstream DnaA boxes and the promoter as long as a DnaA box was located less than 20 bp upstream of the -35 sequence. Thus, the architectural requirements for titration and for repression of transcription are different. A new set of rules for identifying efficiently titrating DnaA box regions was formulated and used to analyse sequences for which good titration data are available.

Negative control of replication initiation by a novel chromosomal locus exhibiting exceptional affinity for Escherichia coli DnaA protein

Replication of the Escherichia coli chromosome is initiated at a unique site, oriC. Concurrent initiation occurs at all oriC sites present in a cell once, and only once, per cell cycle. A mechanism to ensure cyclic initiation events was found operating through the chromosomal site, datA, a 1-kb segment located at 94.7 min on the genetic map that titrates exceptionally large amounts of the bacterial initiator protein, DnaA. A strain lacking datA grew normally but exhibited an asynchronous initiation phenotype as a result of extra initiation events. This mutant phenotype was suppressed by DnaA-titrating plasmids. Furthermore, mutations in a 9-bp DnaA-binding sequence (the DnaA box) in datA were enough to induce the mutant phenotype. Thus, datA is a novel chromosomal element that appears to adjust a balance between free and bound DnaA for a single initiation event at a fixed time in the bacterial cell cycle. Titration of DnaA to newly duplicated datA during oriC sequestration, which is mediated by hemimethylated GATC sequences in oriC and the SeqA protein, would contribute to prevention of reinitiations when oriC is desequestered.

Six new candidate members of the alpha/beta twisted open-sheet family detected by sequence similarity to flavodoxin

Strong sequence similarity has been reported among WrbA (the Trp repressor-binding protein of Escherichia coli); Ycp4, a protein of unknown function from the budding yeast Saccharomyces cerevisiae; P25, the pap1-dependent protein of the fission yeast Schizosaccharomyces pombe; and the translation product of a partial cDNA sequence from rice seedling root (Oryza sativa, locus Ricr02421a; here referred to as RicR). Further homology search with the profile method indicates that all the above sequences are related to the flavodoxin family and, in turn, allows detection of the recently proposed flavodoxin-like proteins from E. coli, MioC and the hypothetical protein YihB. We discuss sequence conservation with reference to the known 3-dimensional structures of flavodoxins. Conserved sequence and hydrophobicity patterns, as well as residue-pair interaction potentials, strongly support the hypothesis that these proteins share the alpha/beta twisted open-sheet fold typical of flavodoxins, with an additional alpha/beta unit in the WrbA family. On the basis of the proposed structural homology, we discuss the details of the putative FMN-binding sites. Our analysis also suggests that the helix-turn-helix motif we identified previously in the C-terminal region of the WrbA family is unlikely to reflect a DNA-binding function of this new protein family.

Cell cycle-dependent transcription from the gid and mioC promoters of Escherichia coli

Transcription from the gid and mioC promoters, which neighbor the origin of replication of the Escherichia coli chromosome (oriC), has been implicated in the control of initiation of replication of minichromosomes. The amounts of transcripts from these two promoters on the chromosome were quantified at various times in a synchronized culture of a temperature-sensitive dnaC mutant strain. Transcription from the gid promoter was most active before the initiation of replication and was inhibited after initiation, during the time corresponding to the period of sequestration of the oriC region from the dam methyltransferase. On the other hand, transcription from the mioC promoter was inhibited before initiation and the inhibition was relieved after initiation prior to the recovery of gid transcription. The strict regulation of transcription from the gid and mioC promoters may be involved in positive and negative control of chromosomal replication, respectively, as has been suggested for minichromosome replication. The DnaA protein was involved in repression of mioC transcription, indicating that the activity of the DnaA protein changes during the cell cycle.

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.

Participation of the histone-like protein HU and of IHF in minichromosomal maintenance in Escherichia coli

The closely related Escherichia coli genes, hupA, hupB, himA and himD (hip), encode the bacterial histone-like protein subunits, HU-2, HU-1, IHF chi and IHF beta, respectively. We report here that E. coli minichromosomes [plasmids (2.7-12.2 kb) with oriC] carrying the intact mioC region were unable to transform mutants deficient in both HU and integration host factor (IHF), whereas they could transform mutants deficient in either HU or IHF as efficiently as the wild-type strain. Minichromosomes carrying a deletion of the proximal part of mioC or a DnaA box just upstream from mioC could not transform cells deficient in IHF, but could transform cells deficient in HU. These results suggested that HU and IHF participate in minichromosomal replication from oriC in E. coli.

DNA replication in Escherichia coli mutants that lack protein HU

DNA replication in Escherichia coli cells lacking protein HU was studied. HU has been suggested to be involved in the initiation of replication from in vitro studies. The isolated HU mutants, however, are viable under normal growth conditions (M. Wada, Y. Kano, T. Ogawa, T. Okazaki, and F. Imamoto, J. Mol. Biol. 204:581-591, 1988). Chromosomal replication in the mutants appeared to be normal with respect to bidirectional replication from oriC and to its dependence on dnaA and some other dna gene products. No significant defect was observed in DNA synthesis in vitro with a crude enzyme fraction prepared from the mutant cells. These results, along with the earlier in vitro studies, suggest that other histonelike protein(s) may substitute for HU in the initiation of replication in the mutant cells. Minichromosomes were more unstable in the mutants. In the absence of either the mioC promoter, from which transcription enters oriC, or the DnaA box (DnaA protein-binding site) just upstream of the mioC promoter, the minichromosomes were especially unstable in the HU mutant and were integrated into the chromosomal oriC region under conditions selective for the plasmid-harboring cells.

Expression of Escherichia coli dnaA and mioC genes as a function of growth rate

The synthesis of specific cellular components related to the initiation process of DNA replication was correlated with changes in growth rate. The concentrations of DnaA protein and mioC mRNA were determined for cells grown at six different growth rates; both increased relative to either total protein or total RNA, respectively, as the growth rate increased. Expression from the chromosomal mioC promoter, which contains a DnaA protein-binding site, was not repressed when the DnaA protein concentration was increased and was not derepressed in a dnaA46 mutant at 42 degrees C. The mioC transcript had a characteristic mRNA-type half-life of 1.51 min.

Timing of chromosomal replication in Escherichia coli

We have previously shown that certain mutations in the dnaA and recA genes of Escherichia coli perturb initiation of chromosomal replication so that all origins present are not initiated simultaneously. In this work, several genes whose protein products are involved in initiation of replication have been investigated for their effects on the synchrony of initiation. Some of the mutants (dnaC2, rpoC907, dam3) were found to have the asynchrony phenotype. Also, dnaA(Ts) mutations were shown to be dominant over dnaA+ in terms of initiation synchrony. The mechanism leading to the asynchronous phenotype is discussed.

Transcriptional activation of initiation of replication from the E. coli chromosomal origin: an RNA-DNA hybrid near oriC

Transcription by RNA polymerase preceding the initiation of replication from the E. coli chromosomal origin (oriC) in vitro enables dnaA protein to open the DNA duplex under conditions when its action alone is insufficient. The RNA polymerases of phages T7 and T3 are as effective as the E. coli enzyme in activating initiation. The persistent RNA transcript hybridized to the template creates an R-loop that is responsible for activation. The activating RNA need not cross oriC, but must be less then 500 bp away. Transcripts lacking a 3' OH group are effective, proving that priming of DNA synthesis is not involved in the activation. Thus, transcription activates the origin of an otherwise inert plasmid by altering the local DNA structure, facilitating its opening by dnaA protein during the assembly of replication forks.