Chromosome replication in an Hfr strain of Escherichia coli

The pattern of chromosome replication in an exponentially growing culture of an Hfr strain of Escherichia coli has been compared to that obtained with the same Hfr following a procedure which synchronizes rounds of DNA replication. The results indicate that there is significant replication from the integrated plasmid following the synchronization procedure, whereas in the exponentially growing culture replication starts most frequently from the normal origin with little, if any, replication from the sex factor, F.     

DNA elongation rates and growing point distributions of wild-type phage T4 and a DNA-delay amber mutant

The rates of DNA elongation by wild-type phage T4 and a gene 52 DNA-delay am mutant were estimated by pulse-labeling infected cells with tritiated thymidine and visualizing the gently extracted DNA by autoradiography. The estimated rate of chain elongation of wild-type DNA was 749 nucleotides/second early in synthesis and 516 to 581 nucleotides/second at a later time. The rate of DNA elongation by the am mutant was measured to be 693, 758 and 829 nucleotides/second during successive stages of synthesis, indicating that elongation was not slower than in wild-type. The kinetics of DNA increase after infection of host cells by wild-type phage T4 or by the gene 52 DNA-delay am mutant was followed using [methyl-³H]thymidine uptake into acid-insoluble material. It was found that DNA increase in both wild-type and am infections could be represented as exponential during early times and linear during late times of DNA synthesis. From the rates of DNA increase and the rates of DNA elongation we were able to estimate the number of growing points per chromosome equivalent of template DNA during the exponential and linear phases. Our estimates for wild-type phage were 0.55 and 0.71 to 0.80 growing points per chromosome equivalent of template DNA in the exponential and linear phases, respectively. For the am mutant we found 0.14 and 0.12 to 0.13 growing points per chromosome equivalent of template DNA during the exponential and linear phases, respectively. The apparent lower incidence of growing points in the am mutant infections suggests that the mutant may be defective in the initiation of growing points.     

The RHC21 gene of budding yeast, a homologue of the fission yeast rad21 +gene, is essential for chromosome segregation

The Saccharomyces cerevisiae gene RHC21 is a homologue of the fission yeast rad21 ⁺gene, which affects the sensitivity of cells to γ-irradiation and is essential for cell growth in S. pombe. Disruption of the RHC21 gene showed that it is also essential in S. cerevisiae. To examine its function in cell growth further, we have isolated temperature-sensitive mutants for the RHC21 gene and characterized one of them, termed rhc21-sk16. When this mutant was incubated at 36°?C, the percentage of large-budded cells was increased. Most of the large-budded cells had aberrant nuclear structures, such as unequally extended nuclear DNA with incompletely elongated spindles across the mother-daughter neck or only in a mother cell. Furthermore, a circular minichromosome is more unstable in the mutant than in the wild-type, even at 25°?C. Flow cytometry showed that the bulk of DNA replication takes place normally at the restrictive temperature in the mutant. These results indicated that the RHC21 gene is required for proper segregation of the chromosomes. In addition, we found that the mutant is sensitive not only to UV radiation and γ-rays but also to the antimicrotubule agent nocodazole at 25°?C. This suggests that the RHC21 gene is involved in the microtubule function. We discuss how the RHC21 gene product may be involved in chromosome segregation and microtubule function.     

A novel Escherichia coli mutant capable of DNA replication in the absence of protein synthesis.

An Escherichia coli mutant capable of continued DNA synthesis in the presence of chloramphenicol has been isolated by an autoradiographic technique. The DNA synthesis represents semiconservative replication of E. coli DNA. It can occur in the presence of chloramphenicol or in the absence of essential amino acids, but not in the presence of an RNA synthesis inhibitor, rifampin. The mutant, termed constitutive stable DNA replication (Sdr^c) mutant, appears to grow normally at 37 °C with a slightly slower growth rate than that of the parental strain. DNA replication in the mutant occurs at a reduced rate after 60 minutes in the absence of protein synthesis and continues linearly for several hours thereafter. This distinct slowdown in the DNA replication rate is due to a reduced rate of DNA synthesis in all the cells in the population. Constitutive stable DNA replication appears to require the dnaA and dnaC gene products. The sdr^c mutation has been mapped near the pro-lac region of the E. coli chromosome. The mutation is recessive. Autoradiographic experiments have ruled out the possibility of multiple initiations during a cell cycle. The implication of the above findings is discussed in terms of the regulation of chromosome replication in E. coli.     

Genetic control of DNA initiation in Escherichia coli

We describe the isolation, and properties of a mutant (CT28) of Escherichia coli with a temperature-sensitive defect in DNA initiation that is reversible. The mutation (dna-28) responsible for this defect is shown to be located in the same region of the map as the dnaC group of DNA initiation mutants.A terminalized culture of CT28 initiates DNA synthesis synchronously immediately upon lowering the temperature, and will do so in the presence of chloram-phenicol.During prolonged incubation at the non-permissive temperature, the cells accumulate a capacity to initiate multiple rounds of replication per chromosome.The variation in the susceptibility of the argH^? and thyA^? alleles to reversion by pulse mutagenesis with nitrosoguanidine during a synchronous round of DNA replication, suggests that this round of replication is bidirectional and commences from an origin in the vicinity of 60 to 65 minutes.CT28 contains two temperature-sensitive mutations. These have been mapped and separated into two derivative strains. One of these, CT28-3b, carries the dna-28 mutation of the C locus, and like the parental double mutant is reversibly temperature-sensitive for an initiation function; but it is more temperature-sensitive than either the double mutant or the other single mutant derivative, CT28-1. The other, CT28-1, is not defective in DNA replication or initiation of replication at the non-permissive temperature.     

Properties of membrane-associated folded chromosomes of E. coli related to initiation and termination of DNA replication

Analysis of folded chromosomes prepared from amino acid-starved E. coli cells or from a dnaC initiation mutant indicates that a unique structure is associated with completion or near completion of rounds of chromosome replication in E. coli. Chromosomes remain associated with portions of the bacterial cell envelope throughout the DNA replication cycle, but become more rapidly sedimenting as replication proceeds in the absence of reinitiation. Before reinitiation of chromosome replication occurs after restoring required amino acids to amino acid-starved cells or after lowering the temperature in a thermosensitive dnaC mutant, sedimentation velocities of the membrane-associated folded chromosomes decrease substantially. The decrease in sedimentation velocity does not depend on renewed DNA synthesis, but does require the activity of at least the dnaC gene product.     

Circularity of the Bacillus subtilis chromosome and further studies on its bidirectional replication

Replicating, circular chromosomes of Bacillus subtilis have been displayed by autoradiography of samples obtained from thymine-requiring spores germinating in the presence of [³H]thymine and proceeding into the second round of replication. The observed chromosomes have the expected Cairns-type configuration, and the measured length of a completed (non-replicating) chromosome is 900 to 1100 μm.The extent to which bidirectional replication can proceed following initiation of a round has been investigated further. Thymine-requiring spores germinating in the presence of [³H]thymidine were diluted into higher specific activity medium during the first round of replication and autoradiographs prepared from samples obtained shortly afterwards. From the pattern of labelling within individual loops that become visible, it is clear that replication can proceed in a bidirectional manner up to a stage that would account for replication of at least 50% of the whole chromosome. And, until this stage, the replication rates in both directions are approximately equal.     

Studies on the regulation of initiation of chromosome replication in Escherichia coli.

The total initiation frequency of chromosome replication in Escherichia coli is dependent on two factors; the timing or time interval between successive initiations on an individual chromosome (initiation pace) and the number of individual chromosomes which are being replicated per cell. We have examined these parameters in a dnaA^ts, conditionally-lethal, “initiation mutant” of an E. coli K12 strain growing at different permissive temperatures. Our results indicate that at temperatures between 30 and 35 °C the gene product of the dnaA167 allele becomes limiting with respect to the number of replicating chromosomes per cell, which decreases from two at 30 °C to one at 35 °C. However, over this same temperature range it is clear that cell growth is balanced and the initiation pace, as determined from the growth rate, increases with temperature and is indistinguishable from that of the dnaA⁺ parent. These results demonstrate that one can alter the total initiation frequency independently of the initiation pace, indicating the involvement of at least two cellular components in the regulation of initiation. They also suggest that while the dnaA product may be involved in determining the total number of initiation events which can occur per cell per doubling time it does not control the timing or pace at which successive initiation events are triggered on each chromosome, i.e. it is not the “pace-maker” for initiation.     

oriX: A new replication origin in E. coli

Replication of the chromosome of E. coli at 42°C in an integratively suppressed dnaA mutant (dnaA46 Sin Hfr) occurs predominantly from the origin of replication of the integrated plasmid (oriV). We have carried out a detailed marker frequency analysis on such Hfrs. This analysis indicates that replication at 42°C occurs not only from oriV, but also from an origin, oriX, located in the terminal region of the chromosome close to, but distinct from, the prophage rac (oriJ). In an oxal mutant of one of these Hfrs, we have shown that replication proceeds at 42°C from all three origins: oriV, oriX, and oriC. Loss of the integrated plasmid results in a temperature- and rich-medium-sensitive strain that replicates the chromosome from oriC and oriX. Replication from oriX proceeds slowly and bidirectionally. We suggest that oriX may be involved in the coupling between replication and cell division.     

Discontinuous replication of colicin E1 plasmid DNA in a cell extract containing thermolabile DNA ligase.

A cell extract prepared from the lig-ts7 mutant of Escherichia coli is able to carry out a complete round of DNA replication of colicin E1 plasmid at 25 °C. However, the apparent rate of elongation of the progeny strands at this temperature is much smaller than in an extract from the thermoresistant revertant cells. Chain elongation in the lig-ts extract is depressed by raising the incubation temperature from 25 °C to 32 °C, whereas that in the lig⁺ revertant extract is not. The rate of closure of the progeny strands of newly formed open circular molecules is also reduced in the lig-ts extract, even at 25 °C.The DNA pulse-labelled with the lig-ts extract for 30 seconds at 32 °C contains a large amount of short DNA fragments of approximately 7 S, in addition to DNA chains of various sizes between 7 S and 17 S (unit length). Most of these replicating molecules are converted to completely replicated closed circular molecules upon chasing with a lig⁺ extract. DNA-DNA hybridization experiments show that molecules replicated to various extents contain 7 S DNA fragments of both strands, but more of the L-strand component, whose 5′-to-3′ direction corresponds to the overall direction of unidirectional replication. The longer DNA chains are enriched in the H-strand component.The cell extracts used for the plasmid DNA replication have an activity which converts alkali-labile closed circular plasmid DNA containing apurinic sites to alkali-stable closed circular molecules. Addition of nicotinamide mononucleotide leads to conversion of the alkali-labile DNA to open circular molecules. In the replication system with the cell extract, however, the compound does not interfere with elongation of progeny strands. Chain elongation in the lig-ts extract at 25 °C is not significantly affected by nicotinamide mononucleotide. Thus, the 7 S DNA fragments formed with the lig-ts extract are unlikely to be generated as a result of incomplete repair of misincorporated nucleotides. We conclude that both strands of colicin E1 plasmid DNA replicate discontinuously.     

Changes in Cell Size and Shape Associated with Changes in the Replication Time of the Chromosome of Escherichia coli

Average cell mass is shown to be inversely related to the concentration of thymine in the growth medium of a thy⁻ strain of Escherichia coli. The kinetics of the transition from one steady-state average cell mass to another was followed in an attempt to determine the relationship between the chromosome replication time and the time between completion of a round of chromosome replication and the subsequent cell division. Differences in average cell mass are shown to be associated with similar differences in average cell volume. Changes in volume associated with changes in thymine concentration are shown to be due primarily to differences in the width of cells. It is proposed that extension in length of the cell envelope occurs at a linear rate which is proportional to the growth rate and which doubles at the time of termination of rounds of replication. Changes in volume not associated with a change in growth rate are therefore accommodated by a change in cell width. Conditions are described under which average cell mass can continue to increase in successive generations and no steady-state average cell mass is achieved.     

Specific chromosomal sites enhancing homologous recombination in Escherichia coli mutants defective in RNase H

To clone new replication origin(s) activated under RNase H-defective (rnh ^?) conditions in Escherichia coli cells, whole chromosomal DNA digested with EcoRI was to with a Km^r DNA fragment and transformed into an rnh^? derivative host. From the Kmr transformants, we obtained eight kinds of plasmid-like DNA, each of which contained a specific DNA fragment, termed “Hot”, derived from the E. coli genome. Seven of the Hot DNAs (HotA-G) mapped to various sites within a narrow DNA replication termination region (about 280 kb), without any particular selection. Because Hot DNA could not be transformed into a mutant strain in which the corresponding Hot region had been deleted from the chromosome, the Hot DNA, though obtained as covalently closed circular (ccc) DNA, must have arisen by excision from the host chromosome into which it had initially integrated, rather than by autonomous replication of the transformed species. While Hot DNA does not have a weak replication origin it does have a strong recombinational hotspot active in the absence of RNase H. This notion is supported by the finding that Chi activity was present on all Hot DNAs tested and no Hot-positive clone without Chi activity was obtained, with the exception of a DNA clone carrying the dif site.     

The Myxococcus xanthus developmental program can be delayed by inhibition of DNA replication

Under conditions of nutrient deprivation, Myxococcus xanthus undergoes a developmental process that results in the formation of a fruiting body containing environmentally resistant myxospores. We have shown that myxospores contain two copies of the genome, suggesting that cells must replicate the genome prior to or during development. To further investigate the role of DNA replication in development, a temperature-sensitive dnaB mutant, DnaB^A116V, was isolated from M. xanthus. Unlike what happens in Escherichia coli dnaB mutants, where DNA replication immediately halts upon a shift to a nonpermissive temperature, growth and DNA replication of the M. xanthus mutant ceased after one cell doubling at a nonpermissive temperature, 37°C. We demonstrated that at the nonpermissive temperature the DnaB^A116V mutant arrested as a population of 1n cells, implying that these cells could complete one round of the cell cycle but did not initiate new rounds of DNA replication. In developmental assays, the DnaB^A116V mutant was unable to develop into fruiting bodies and produced fewer myxospores than the wild type at the nonpermissive temperature. However, the mutant was able to undergo development when it was shifted to a permissive temperature, suggesting that cells had the capacity to undergo DNA replication during development and to allow the formation of myxospores.     

Isolation and Characterization of a Composite Plasmid Rms201 Mutant Temperature Sensitive for Replication

A mutant temperature-sensitive for R-plasmid replication, Rms201ts14, was isolated from composite plasmid Rms201 after mutagenesis of P1 transducing lysate with 100 mM hydroxylamine for 40 h at 37°C. When Escherichia coli ML1410(Rms201ts14)⁺ was grown at temperatures between 40 and 42°C in L broth, antibiotic-sensitive cells were segregated. When the incubation temperature of ML1410(Rms201ts14)⁺ in L-broth was shifted to 42 from 30°C, the increase in the number of antibiotic-resistant cells ceased 90 min after the temperature shift. However, the total number of cells continuously increased, and only 3% of the cells retained the plasmid at 5 h after the temperature shift to 42°C. At 30°C the amounts of covalently closed circular deoxyribonucleic acid per chromosome of Rms201ts14 and Rms201 were 3.8 and 6.3%, respectively. Incorporation of radioactive thymidine into the covalently closed circular deoxyribonucleic acid of Rms201ts14 did not take place at 42°C, whereas radioactive thymidine was incorporated into the covalently closed circular deoxyribonucleic acid of Rms201 at a rate of 4%/chromosome even at 42°C. The synthesis of plasmid covalently closed circular deoxyribonucleic acid in a cell harboring Rms201ts14 was almost completely blocked at 42°C. These results indicated that the gene(s) responsible for plasmid deoxyribonucleic acid replication was affected in the mutant Rms201ts14. Temperature-sensitive miniplasmid pMSts214, which has a molecular weight of 5.3 × 10⁶ and encodes ampicillin resistance, was isolated from Rms201ts14. Similarly, miniplasmid pMS201, which encodes single ampicillin resistance, was isolated from its parent, Rms201, and its molecular weight was 4.7 × 10⁶. These results indicate that the gene(s) causing temperature sensitivity for replication of Rms201 resides on the miniplasmid.     

Relationship between chromosome replication and F'lac episome replication in Escherichia coli

The amount of F′lac DNA as a percentage of total DNA in Escherichia coli was determined by DNA-DNA hybridization at a number of growth rates. The data are in closest agreement with the hypothesis that episome replication coincides with termination of rounds of chromosome replication and are inconsistent with the hypotheses that it occurs at a constant cell age, or at the same time as initiation of rounds of chromosome replication. The possibility that episome replication occurs at a constant mass:particle ratio is not ruled out by the data presented.     

Dynamics of Escherichia coli chromosome segregation during multifork replication

Slowly growing Escherichia coli cells have a simple cell cycle, with replication and progressive segregation of the chromosome completed before cell division. In rapidly growing cells, initiation of replication occurs before the previous replication rounds are complete. At cell division, the chromosomes contain multiple replication forks and must be segregated while this complex pattern of replication is still ongoing. Here, we show that replication and segregation continue in step, starting at the origin and progressing to the replication terminus. Thus, early-replicated markers on the multiple-branched chromosomes continue to separate soon after replication to form separate protonucleoids, even though they are not segregated into different daughter cells until later generations. The segregation pattern follows the pattern of chromosome replication and does not follow the cell division cycle. No extensive cohesion of sister DNA regions was seen at any growth rate. We conclude that segregation is driven by the progression of the replication forks.     

OriC plasmids do not affect timing of chromosome replication in Escherichia coli K12

Summary The variability of the time interval between successive rounds of chromosome replication was estimated by density-shift experiments, by measuring the conversion of heavy DNA to hybrid density and light DNAs upon transfer of a steady-state culture growing in medium with [¹³C]glucose and ¹⁵NH₄Cl to medium with light isotopes. The coefficient of variation (CV%) for the interreplication time of the Escherichia coli K12 chromosome was found to be 17%, i.e. similar to that for interdivision time. The presence of additional copies of oriC in the cell on a high copy number plasmid did not increase the CV of interreplication time. It is concluded that a single rate-limiting event is unlikely to time the initiation of chromosome replication. The regulation of initiation at oriC and the coordination with cell division is discussed.     

New killing system controlled by two genes located immediately upstream of the mukB gene in Escherichia coli

The nucleotide sequence was determined of the region upstream of the mukB gene of Escherichia coli. Two new genes were found, designated kicA and kicB (killing of cell); the gene order is kicB-kicA-mukB. Promoter activities were detected in the regions immediately upstream of kicB and kicA, but not in front of mukB. Gene disruption experiments revealed that the kicA disruptant was nonviable, but the kicB-disrupted mutant and the mutant lacking both the kicB and kicA genes were able to grow. When kicA disruptant cells bearing a temperature-sensitive replication plasmid carrying the kicA ⁺ gene were grown at 30° C and then transferred to 42° C, the mutant cells gradually lost colony-forming ability, even in the presence of a mukB ⁺ plasmid. Rates of protein synthesis, but not of RNA or DNA synthesis, fell dramatically during incubation at 42° C. These results suggested that the kicB gene encodes a killing factor and the kicA gene codes for a protein that suppresses the killing function of the kicB gene product. It was also demonstrated that KicA and KicB can function as a post-segregational killing system, when the genes are transferred from the E. coli chromosome onto a plasmid.     

Super-resolution imaging of Escherichia coli nucleoids reveals highly structured and asymmetric segregation during fast growth

Bacterial replication and chromosome segregation are highly organized both in space and in time. However, spatial analysis is hampered by the resolution limit of conventional fluorescence microscopy. In this study, we incubate rapidly-growing Escherichia coli with 5-ethynyl-2′-deoxyuridine (EdU), label the resulting EdU-DNA with photoswitchable fluorophores, and image incorporated molecules with an average experimental precision of 13 nm. During the segregation process, nucleoids develop highly-defined and cell-cycle dependent hetero-structures, which contain discrete DNA fibers with diameters far below the diffraction limit. Strikingly, these structures appear temporally shifted between sister chromosomes, an asymmetry which accumulates for ongoing replication rounds. Moreover, nucleoid positioning and expansion along the bacterial length axis fit into an elongation-mediated segregation model in fast growing E. coli cultures. This is supported by close proximity of the nucleoids to the bacterial plasma membrane, the nature of the observed hetero-structures and recently found interactions of membrane-associated proteins with DNA.