L. Caro

Origin and sequence of chromosome replication in Escherichia coli

Two methods have been used to determine the origin and direction of chromosome replication in Escherichia coli: gradient of marker frequency and sequence of replication in synchronized cultures. In both cases, DNA-DNA hybridization was used to assay for gene dosage. A series of isogenic strains were made lysogenic for phage λ and for phage Mu-1, with phage Mu-1 in a different chromosomal location in each strain. In a first group of experiments, DNA from exponential cultures of the various strains was extracted, denatured, immobilized on filters and hybridized against a mixture of differentially labeled phage λ and phage Mu-1 DNA. This was done for several culture conditions. The ratio of hybridization Mu-1/λ gives a measurement of the dosage of the chromosome region where phage Mu-1 is integrated. A plot of this ratio versus map position reflects the marker frequency distribution. In another group of experiments, several of the strains were synchronized by amino-acid starvation, then restitution of essential amino acids. The cultures thus synchronized were density labeled with bromouracil and their DNA extracted at various times, separated by density on a CsCl gradient, and the amount of phage Mu-1 specific DNA present in each band was measured by DNA-DNA hybridization. The following conclusions have been reached. 1. (1) The origin of replication in near ilv, at 74 minutes on the standard genetic map of Escherichia coli. 2. (2) Replication proceeds simultaneously in the two opposite directions, at approximately the same velocity in both directions. 3. (3) This velocity is influenced, in a thymineless mutant, by the concentration of exogenous thymine. 4. (4) The two growing forks meet at a point diametrically opposed to the origin, near trp (25 min).

A cold sensitive dnaA mutant of E. coli which overinitiates chromosome replication at low temperature.

SummaryA heat resistant mutant of E. coli dnaAts46 was isolated, which grows normally only at temperatures above 39°. After a temperature shift from 42° to 32° the mutant overproduces DNA relative to protein. This is due to overinitiation of rounds of chromosome replication at low temperature, as indicated by hybridization and other experiments. The mutation is cotransduced by Pl with ilv and could not be separated from dnaAts46 by transduction.

Replication of the prophage P1 during the cell cycle of Escherichia coli

SummaryWe have followed, by DNA-DNA hybridization, the variation in the number of copies of prophage P1 relative to two chromosomal markers when the doubling time of the host cells is modified by a change in carbon source. The ratio of P1/chromosome terminus undergoes a twofold decrease when the cell doubling time increases from 24 to 215 min, whereas the ratio of P1/chromosome origin increases 1.4 fold; both ratios tend towards unity at slow growth rates. This suggests that the replication of prophage P1 is not simultaneous with chromosome initiation or chromosome termination. The chromosome replication time is unaffected by the presence of P1, and remains constant over the range of doubling times studied, with a value of about 40 min. Following amino acid starvation, the P1/chromosome origin ratio increases from 0.7 to 0.9, suggesting that P1 retains the ability to replicate after chromosome initiation has stopped and in the absence of essential amino acids. The results are discussed with reference to similar studies done on F and R1.

Replication of pSC101: effects of mutations in the E. coli DNA binding protein IHF

SummaryWe have shown that the plasmid pSC101 is unable to be maintained in strains of E. coli carrying deletions in the genes himA and hip which specify the pleitropic heterodimeric DNA binding protein, IHF. We show that this effect is not due to a modulation of the expression of the pSC101 RepA protein, required for replication of the plasmid. Inspection of the DNA sequence of the essential replication region of pSC101 reveals the presence of a site, located between the DnaA binding-site and that of RepA, which shows extensive homology with the consensus IHF binding site. The proximity of the sites suggests that these three proteins, IHF, DnaA, and RepA may interact in generating a specific DNA structure required for initiation of pSC101 replication.

The effects of an Escherichia coli dnaAts mutation on the replication of the plasmids colE1 pSC101, R100.1 and RTF-TC.

SummaryThe rate of replication of the plasmids colE1, pSC101, R100.1 and pAR132 (an RTF-TC derivative of the drug resistance factor R100.1) has been investigated directly by DNA: DNA hybridization. These rates have been compared, in a dnaAts strain, to that of various markers of the host chromosome at permissive and non-permissive temperatures. Chromosome initiation in the dnaAts strain stops rapidly after a shift to the non-permissive temperature, but plasmids R100.1 and pAR132 do not seem to be affected directly and continue replication for some time. The colE1 replication rate undergoes a large increase after the temperature shift, followed by a rapid decrease to a very low level 25 min after the shift. In contrast pSC101 replication stops immediately after the shift. ColE1 is able to replicate in an integratively suppressed dnaAts strain at 42° C whereas pSC101 stops replication immediately under these conditions. We conclude that R100.1 and its derivative RTF-TC can replicate without a functional dnaA product; that colE1, while affected by a shift in temperature in a dnaAts strain, does not directly require dnaA; and that the plasmid pSC101 has an absolute requirement for dnaA. The absolute requirement of pSC101 for dnaA in the integratively suppressed Hfr strain provides a useful system for further investigations of the dnaA function.

The replication time of the Escherichia coli K12 chromosome as a function of cell doubling time.

Abstract The relative frequency of two chromosomal markers in a strain of Escherichia coli K12 has been measured as a function of cell doubling time by DNA:DNA hybridization. The results indicate that the replication time of the chromosome is constant and independent of the doubling time of the cells.

Involvement of IS1 in the dissociation of the r-determinant and RTF components of the plasmid R100.1.

SummaryThe formation of the r-determinant pLCl and of the RTF pAR132 from the composite plasmid R100.1 was investigated. The general location of IS1 sequences on the three plasmids was established by hybridization of λr14 CII::IS1 DNA to EcoRI generated fragments of the various plasmids separated by agarose gel electrophoresis and transferred directly to nitrocellulose filters. The position of IS1 sequences on these fragments and the homologies between fragments were analyzed by electron microscopy of heteroduplex molecules. The results show that the excision of both pLCl and pAR132 occurred by an exchange between the two IS1 sequences present on R100.1.

An essential replication gene, repA, of plasmid pSC101 is autoregulated

Measurements of the rate of replication of a mutant pSC101 plasmid, cloned into a ColE1 vector, showed that insertions of the transposon Tn1000 into the repA gene of pSC101 abolished replication activity, but could be complemented in trans, albeit at a low level. The promoter of the repA gene was mapped by the construction of repA-lacZ gene fusions, and one of the fusions was used to demonstrate that repA protein, provided in trans, could repress expression of beta-galactosidase activity. This repression was primarily due to reduction of transcription of the repA-lacZ fusion. The sequence analysis of mutants of the repA-lacZ fusion gene which were no longer sensitive to the presence of repA protein showed that the site of action of repA was a 22 base-pair sequence, present as an inverted repeat, overlapping the repA promoter. The repA gene is thus autoregulated.

The replication of plasmid pSC101

The origin of replication of plasmid pSC101 presents features reminiscent of those found in a number of plasmids. As for those plasmids, many details about the way it initiates its replication are beginning to be known, but the regulation of this process will not be easily understood.

Tn10 mediated integration of the plasmid R100.1 into the bacterial chromosome: inverse transposition.

SummaryUpon integration into the bacterial chromosome the drug resistance plasmid R100.1 often loses its tetracycline resistance character. We have analyzed an Hfr strain formed by such an integration and an R-prime plasmid derived from it. We find that integration took place within the Tn10 transposon, that the two IS10 sequences were retained, but that at least 80% of the transposon segment located between them, and carrying the tetracycline resistance genes, had been lost. We suggest that integration of R100.1 was mediated by an inverse transposition using the IS10 sequences.