The function of recombinations occurring in the process of DNA replication in Escherichia coli

In a number of works dealing with the relationship between replication and recombination in bacteria, it is assumed that recombinations permit the replication forks to resume moving after having stopped at the damage sites of the template DNA. As an evidence for recombination occurring during DNA replication, the involvement in this process of proteins RuvABC and RecG, providing processing of the Holliday junctions after recombination, is considered. However, it has been shown that these proteins are not essential for resuming DNA synthesis after an exposure of bacteria to UV light. These data cast doubt on the necessity of recombination for reactivation of replication initiated in the oriC region. Studying recombination in tandem duplications in Escherichia coli showed that during replication, unequal crossing over occurs between direct DNA repeats of sister chromosomes. In wild strains, this crossing over results in tandem duplications, thereby enhancing the expression of certain genes. Thus, recombination of two types occurs during DNA replication: unequal crossing over leading to duplications and homologous exchange, responsible for post-replication DNA repair. The unequal exchange constitutes a component of SOS response of the cell to deterioration of the environment.     

Intermediates of chromosomal DNA replication in Escherichia coli

The product of bacteriophage T4 gene 63 has two activities, one which catalyzes the attachment of tail fibers to base plates during morphogenesis (TFA) and one which catalyzes the joining of single-stranded polynucleotides (RNA ligase). The only phenotype attributed to mutations in gene 63 is a defect in attachment of tail fibers leading to fiberless T4 particles. However, it is suspected that TFA and RNA ligase are unrelated activities of the same protein since they have very different requirements in vitro.We have isolated new mutants which have lost the RNA ligase but have retained the TFA activity of the product of gene 63. These mutants exhibit defects in T4 DNA replication and late gene expression in some strains of Escherichia coli. This work allows us to draw three conclusions: (1) the TFA and RNA ligase activities are unrelated functions of the gene 63 product making this the prototype for a protein which has more than one unrelated function; (2) the RNA ligase is probably involved in DNA metabolism rather than RNA processing as has been proposed: (3) the RNA ligase and polynucleotide 5′ kinase 3′ phosphatase of T4 perform intimately related functions.     

Alternate pathways of DNA replication in Escherichia coli

We have described the pcbA1 mutation which enables E. coli cells to replicate DNA in the absence of a functional dnaE gene product if DNA polymerase I (the polA gene product) is present. The pcbA1 mutation phenotypically suppresses multiple dnaEts and dnaEam alleles. The pcbA1/PolI replication pathway differs from normal in sensitivity to certain DNA-damaging agents such as methylmethane sulfonate (MMS) and a lack of damage-directed mutagenesis. We report here cloning of the pcbA1 gene in a multicopy plasmid. The pcbA1 mutation is detected only in cis; therefore, cloning necessitated gene eviction. The pcbA1 gene lies closely- linked to gyrB. We have demonstrated the physical presence of DNA polymerase I in the replicating holoenzyme complex by immunoblotting using dnaEam strains. We conclude that E. coli has two alternate replisome structures: REP-A, in which DNA polymerase I is the functional synthetic subunit; and REP-E, in which the alpha-subunit, product of the dnaE gene, is functional. To investigate further the role of individual DNA polymerases in replication, we have isolated the polB gene on multicopy plasmids.     

Plasmid ColE1 DNA replication in Escherichia coli strains temperature-sensitive for DNA replication

Mutants of the dnaA, dnaC, dnaD, polC, dnaF and dnaG gene loci were tested for their capacity for colicinogenic plasmid E1 (ColE1) replication at a non-permissive temperature. It was found that ColE1 replication was independent of the dnaA gene function and dependent on dnaC, D, F and G. ColE1 replication in the polC mutant E486 continued for several hours but at a greatly reduced rate. No effect was found of the dnaG mutation on thymine-deprivation-induced "priming" of ColE1 replication at the non-permissive temperature. The mutants also were tested for aberrant replication intermediates of plasmid DNA as well as a temperature sensitive supercoiled DNA-protein relaxation complex. RNA-containing supercoils were found to accumulate in a poIC mutant also blocked for protein synthesis.     

X-irradiation sensitivity in Escherichia coli defective in DNA replication

Summary A mutant of Escherichia coli with a temperature sensitive defect in DNA replication is sensitive to X-irradiation but not to UV-irradiation. After UV-irradiation, dark-repair processes—dimer excision, DNA breakdown, repair synthesis and DNA strand joining—appear normal at the restrictive temperature. After X-irradiation, DNA degradation exceeds that in the wild type, and irradiation-dependent DNA synthesis does not occur. Single-strand breaks introduced into the DNA by the irradiation are nor repaired. The data indicate that the mutation results in a defect in repair of X-ray induced single-strand breaks as well as a defect in DNA replication. They provide evidence for the existence of a repair pathway for X-irradiated DNA similar to, but at least partially independent from, that postulated for the dark-repair of UV-irradiated DNA, viz., degradation at the site of the lesion, resynthesis of the degraded DNA complement and ligation of the DNA strand.This material has been published as an abstract in Genetics 64, p. 18 (1970).     

Autoradiographic evidence for bidirectional DNA replication in Escherichia coli

Autoradiographic evidence is presented that demonstrates bidirectional DNA replication during a synchronous round of DNA synthesis in a culture of a reversible temperature sensitive DNA initiation mutant of Escherichia coli K12. High specific activity [³H]thymine was incorporated into the origins and termini of chromosomes which were otherwise uniformly labeled with low specific activity [³H]thymine. Autoradiographs of such differentially labeled chromosomes show two regions of high grain density symmetrically disposed on the circular chromosomes. This demonstrates that the origins and termini of replication are not contiguous; therefore replication must have proceeded in two directions.     

DNA replication in Escherichia coli: physical and kinetic studies of the replication point

DNA replication in Escherichia coli was followed using analytical composite agarose-acrylamide gel electrophoresis of native and denatured DNA samples from cells that had been pulse-labeled in vivo. The results obtained with samples of native DNA, combined with the different sensitivities of the various electrophoretic fractions of native DNA to enzymatic attack, led us to conclude that a significant amount of single-strandedness exists in the region of the replication site. Data obtained from kinetic analyses of the labeling of both the high molecular weight DNA and the fragments formed on denaturation of native DNA samples were consistent with the Okazaki model (Okazaki et al., 1968a,b) of DNA replication. Furthermore, the data indicated that eight to ten precursor fragments are present per fork during bacterial growth at both 20 and 37 °C, under the conditions used in this study.     

Characterization of the replication of Escherichia coli DNA in the absence of protein synthesis: Stable DNA replication

After inhibiting DNA synthesis in Escherichia coli, repeated cycles of chromosome replication can occur in the absence of protein synthesis. This “stable” replication requires the products of all of the known dna genes.Stable replication results from inhibiting DNA synthesis by treatment with naladixic acid, cytosine arabinoside or hydroxyurea; or by placing dnaB, dnaE or dnaG mutants at non-permissive temperatures. It also follows a “shift-up” into rich medium in which RNA and protein are synthesized more rapidly than DNA. Paradoxically, stable replication is induced also by treatment with concentrations of streptolydigin which do not inhibit DNA replication but temporarily and partially inhibit RNA and protein synthesis. During all of these treatments, some protein synthesis must occur.Stable replication is not immediately expressed after a short period of thymine starvation or streptolydigin treatment, but requires a subsequent period of protein synthesis. Once established, however, the stable replication state is permanent and will persist in the absence of protein synthesis or during normal growth.After stable replication has been determined by a period of DNA inhibition, it is possible to inactivate replication by heating dnaA, B, C, E and G temperature-sensitive mutants. However, resynthesis of these gene products in the presence of thymine and at the permissive temperature restores stable replication activity. Since restoration of activity can occur under normal growth conditions which do not induce stable replication, it was concluded that the dnaA, B, C, E and G gene products do not directly determine the stabilized character of the replication fork.A model is presented which attempts to explain the ability of different treatments to induce stable replication.     

Role of Escherichia coli DNA polymerase I in chromosomal DNA replication fidelity

We have investigated the possible role of Escherichia coli DNA polymerase (Pol) I in chromosomal replication fidelity. This was done by substituting the chromosomal polA gene by the polAexo variant containing an inactivated 3′→5′ exonuclease, which serves as a proofreader for this enzyme's misinsertion errors. Using this strain, activities of Pol I during DNA replication might be detectable as increases in the bacterial mutation rate. Using a series of defined lacZ reversion alleles in two orientations on the chromosome as markers for mutagenesis, 1.5‐ to 4‐fold increases in mutant frequencies were observed. In general, these increases were largest for lac orientations favouring events during lagging strand DNA replication. Further analysis of these effects in strains affected in other E. coli DNA replication functions indicated that this polAexo mutator effect is best explained by an effect that is additive compared with other error‐producing events at the replication fork. No evidence was found that Pol I participates in the polymerase switching between Pol II, III and IV at the fork. Instead, our data suggest that the additional errors produced by polAexo are created during the maturation of Okazaki fragments in the lagging strand.     

On the termination of the DNA replication cycle in Escherichia coli.

The initiation of the DNA replication cycle in Escherichia coli requires protein synthesis. Marunouchi &; Messer (1973) have hypothesized that an additional protein synthesis step is required for the replication of the terminal segment of the chromosome, and that replication of this segment is a prerequisite for subsequent cell division. We have not confirmed the existence of a unique terminal segment using a protocol designed to label the hypothesized segment with [³H]dThd². Our protocol avoids the increased incorporation of [³H]dThd into DNA caused by abrupt increases in temperature, a complication implicit in the technique of Marunouchi &; Messer (1973).Treatment with nalidixic acid (an inhibitor of semiconservative DNA synthesis) in sufficient concentration to prevent replication of the postulated terminal segment prevents cell division but also causes loss of viability. This makes it difficult to correlate the effect of nalidixic acid on cell division with DNA synthesis inhibition alone.