Transient enhanced cell division by blocking DNA synthesis in Escherichia coli.

Duplication of the bacterial nucleoid is necessary for cell division hence specific arrest of DNA replication inhibits divisions culminating in filamentation, nucleoid dispersion and appearance of a-nucleated cells. It is demonstrated here that during the first 10 min however, Escherichia coli enhanced residual divisions: the proportion of constricted cells doubled (to 40%), nucleoids contracted and cells remodelled dimensions: length decreased and width increased. The preliminary data provides further support to the existence of temporal and spatial couplings between the nucleoid/replisome and the sacculus/divisome, and is consistent with the idea that bacillary bacteria modulate width during the division process exclusively.

Thymineless Death Lives On: New Insights into a Classic Phenomenon.

The primary mechanisms by which bacteria lose viability when deprived of thymine have been elusive for over half a century. Early research focused on stalled replication forks and the deleterious effects of uracil incorporation into DNA from thymidine-deficient nucleotide pools. The initiation of the replication cycle and origin-proximal DNA degradation during thymine starvation have now been quantified via whole-genome microarrays and other approaches. These advances have fostered innovative models and informative experiments in bacteria since this topic was last reviewed. Given that thymineless death is similar in mammalian cells and that certain antibacterial and chemotherapeutic drugs elicit thymine deficiency, a mechanistic understanding of this phenomenon might have valuable biomedical applications.

Thymineless death, at the origin.

Thymineless death (TLD) in bacteria has been a focus of research for decades. Nevertheless, the advances in the last 5 years, with Escherichia coli as the model organism, have been outstanding. Independent research groups have presented compelling results that establish that the initiation of chromosome replication under thymine starvation is a key element in the scenario of TLD. Here we review the experimental results linking the initiation of replication to the lethality under thymine starvation and the proposed mechanisms by which TLD occurs. The concept of this relationship was 'in the air,' but approaches were not sufficiently developed to demonstrate the crucial role of DNA initiation in TLD. Genome-wide marker frequency analysis and Two Dimensional agarose gel electrophoresis have been critical methods employed to reveal that initiation events and the degradation of the oriC region occur during thymine starvation. The relationships between these events and TLD have established them to be the main underlying causes of the lethality under thymine starvation. Furthermore, we summarize additional important findings from the study of different mutant strains, which support the idea that the initiation of chromosomal replication and TLD are connected.

Rifampicin suppresses thymineless death by blocking the transcription-dependent step of chromosome initiation.

Thymineless death (TLD), a phenomenon in which thymine auxotrophy becomes lethal when cells are starved of thymine, can be prevented by the presence of rifampicin, an RNA polymerase inhibitor. Several lines of evidence link TLD to chromosome initiation events. This suggests that rifampicin-mediated TLD suppression could be due to the inhibition of RNA synthesis required for DNA chromosomal initiation at oriC, although other mechanisms cannot be discarded. In this work, we show that the addition of different rifampicin concentrations to thymine-starved cells modulates TLD and chromosomal initiation capacity (ChIC). Time-lapse experiments find increasing levels of ChIC during thymine starvation correlated with the accumulation of simple-Y, double-Y and bubble arc replication intermediates at the oriC region as visualized by two-dimensional DNA agarose gel electrophoresis. None of these structures were observed following rifampicin addition or under genetic-physiological conditions that suppress TLD, indicating that abortive chromosome replication initiations under thymine starvation are crucial for this lethality. Significantly, the introduction of mioC and gid mutations which alter transcription levels around oriC, reduces ChIC and alleviates TLD. These results show that the impairment of transcription-dependent initiation caused by rifampicin addition, is responsible for TLD suppression. Our findings here may provide new avenues for the development of improved antibacterial treatments and chemotherapies based on thymine starvation-induced cell death.

Tuning the replication fork progression by the initiation frequency.

The thermo-resistant period of the thermo-sensitive ribonucleotide reductase RNR101 encoded by the nrdA101 allele in Escherichia coli is prolonged for 50 min at 42°C, enabling an increase in DNA content of about 45%. Assuming that fork progression in the nrdA101 mutant is impaired, the question whether reduced number of ongoing replication rounds altered the thermo-resistant period in this strain was investigated. Decreases in the oriC/terC ratio and in the number of oriC per cell at 30°C were found in the presence of oriC228, oriC229 and oriC239 alleles in strain nrdA101. Correlated with this effect, increased thermo-resistance period of the RNR101 was allowed, and the detrimental effects on cell division, chromosome segregation and cell viability observed in the nrdA101 mutant at 42°C were suppressed. These results indicate that conditions leading to chromosome initiation deficiency at 30°C enhance the replication fork progression in the nrdA101 mutant at 42°C. We propose that coordination between initiation frequency and replication fork progression could be significant for most of the replication systems with important consequences in their cell cycle regulation.

Overlap of replication rounds disturbs the progression of replicating forks in a ribonucleotide reductase mutant of Escherichia coli.

Ribonucleotide reductase (RNR) is the only enzyme specifically required for the synthesis of deoxyribonucleotides (dNTPs). Surprisingly, Escherichia coli cells carrying the nrdA101 allele, which codes for a thermosensitive RNR101, are able to replicate entire chromosomes at 42 °C under RNA or protein synthesis inhibition. Here we show that the RNR101 protein is unstable at 42 °C and that its degradation under restrictive conditions is prevented by the presence of rifampicin. Nevertheless, the mere stability of the RNR protein at 42 °C cannot explain the completion of chromosomal DNA replication in the nrdA101 mutant. We found that inactivation of the DnaA protein by using several dnaAts alleles allows complete chromosome replication in the absence of rifampicin and suppresses the nucleoid segregation and cell division defects observed in the nrdA101 mutant at 42 °C. As both inactivation of the DnaA protein and inhibition of RNA synthesis block the occurrence of new DNA initiations, the consequent decrease in the number of forks per chromosome could be related to those effects. In support of this notion, we found that avoiding multifork replication rounds by the presence of moderate extra copies of datA sequence increases the relative amount of DNA synthesis of the nrdA101 mutant at 42 °C. We propose that a lower replication fork density results in an improvement of the progression of DNA replication, allowing replication of the entire chromosome at the restrictive temperature. The mechanism related to this effect is also discussed.

RecA-dependent replication in the nrdA101(Ts) mutant of Escherichia coli under restrictive conditions.

Cells carrying the thermosensitive nrdA101 allele are able to replicate entire chromosomes at 42°C when new DNA initiation events are inhibited. We investigated the role of the recombination enzymes on the progression of the DNA replication forks in the nrdA101 mutant at 42°C in the presence of rifampin. Using pulsed-field gel electrophoresis (PFGE), we demonstrated that the replication forks stalled and reversed during the replication progression under this restrictive condition. DNA labeling and flow cytometry experiments supported this finding as the deleterious effects found in the RecB-deficient background were suppressed specifically by the absence of RuvABC; however, this did not occur in a RecG-deficient background. Furthermore, we show that the RecA protein is absolutely required for DNA replication in the nrdA101 mutant at restrictive temperature when the replication forks are reversed. The detrimental effect of the recA deletion is not related to the chromosomal degradation caused by the absence of RecA. The inhibition of DNA replication observed in the nrdA101 recA mutant at 42°C in the presence of rifampin was reverted by the presence of the wild-type RecA protein expressed ectopically but only partially suppressed by the RecA protein with an S25P mutation [RecA(S25P)], deficient in the rescue of the stalled replication forks. We propose that RecA is required to maintain the integrity of the reversed forks in the nrdA101 mutant under certain restrictive conditions, supporting the relationship between DNA replication and recombination enzymes through the stabilization and repair of the stalled replication forks.

DNA replication initiation as a key element in thymineless death.

Thymine deprivation results in the loss of viability in cells from bacteria to eukaryotes. Numerous studies have identified a variety of molecular processes and cellular responses associated with thymineless death (TLD). It has been observed that TLD occurs in actively growing cells, and DNA damage and DNA recombination structures have been associated with cells undergoing TLD. We measured the loss of viability in thymine-starved cells differing in the number of overlapping replication cycles (n), and we found that the magnitude of TLD correlates with the number of replication forks. By using pulsed field gel electrophoresis (PFGE), we determined the proportion of linear DNA (DSBs) and the amount of DNA remaining in the well after treatment with XbaI (nmDNA) under thymine starvation in the absence or presence of both rifampicin (suppressing TLD) and hydroxyurea (maintaining TLD). Our results indicate that DSBs and nmDNA are induced by thymine starvation, but they do not correlate with the lethality observed in the presence of the drugs. We asked whether TLD was related to chromosomal DNA initiation. DNA labeling experiments and flow cytometric analyses showed that new initiation events were induced under thymine starvation. These new DNA replication initiation events were inhibited in the presence of rifampicin but not in the presence of hydroxyurea, indicating that TLD correlates with the induction of new initiation events in Escherichia coli. In support of this finding, cells carrying a deletion of the datA site, in which DNA initiation is allowed in the presence of rifampicin, underwent TLD in the presence of rifampicin. We propose that thymineless-induced DNA initiation generates a fraction of DNA damage and/or nmDNA at origins that is critical for TLD. Our model provides new elements to be considered when testing mammalian chemotherapies that are based on the inhibition of thymidylate synthetase.

Double-strand break generation under deoxyribonucleotide starvation in Escherichia coli.

Stalled replication forks produced by three different ways of depleting deoxynucleoside triphosphate showed different capacities to undergo "replication fork reversal." This reaction occurred at the stalled forks generated by hydroxyurea treatment, was impaired under thermal inactivation of ribonucleoside reductase, and did not take place under thymine starvation.

Defective ribonucleoside diphosphate reductase impairs replication fork progression in Escherichia coli.

The observed lengthening of the C period in the presence of a defective ribonucleoside diphosphate reductase has been assumed to be due solely to the low deoxyribonucleotide supply in the nrdA101 mutant strain. We show here that the nrdA101 mutation induces DNA double-strand breaks at the permissive temperature in a recB-deficient background, suggesting an increase in the number of stalled replication forks that could account for the slowing of replication fork progression observed in the nrdA101 strain in a Rec(+) context. These DNA double-strand breaks require the presence of the Holliday junction resolvase RuvABC, indicating that they have been generated from stalled replication forks that were processed by the specific reaction named "replication fork reversal." Viability results supported the occurrence of this process, as specific lethality was observed in the nrdA101 recB double mutant and was suppressed by the additional inactivation of ruvABC. None of these effects seem to be due to the limitation of the deoxyribonucleotide supply in the nrdA101 strain even at the permissive temperature, as we found the same level of DNA double-strand breaks in the nrdA(+) strain growing under limited (2-microg/ml) or under optimal (5-microg/ml) thymidine concentrations. We propose that the presence of an altered NDP reductase, as a component of the replication machinery, impairs the progression of the replication fork, contributing to the lengthening of the C period in the nrdA101 mutant at the permissive temperature.

Differences in the degree of inhibition of NDP reductase by chemical inactivation and by the thermosensitive mutation nrdA101 in Escherichia coli suggest an effect on chromosome segregation.

NDP reductase activity can be inhibited either by treatment with hydroxyurea or by incubation of an nrdA (ts) mutant strain at the non-permissive temperature. Both methods inhibit replication, but experiments on these two types of inhibition yielded very different results. The chemical treatment immediately inhibited DNA synthesis but did not affect the cell and nucleoid appearance, while the incubation of an nrdA101 mutant strain at the non-permissive temperature inhibited DNA synthesis after more than 50 min, and resulted in aberrant chromosome segregation, long filaments, and a high frequency of anucleate cells. These phenotypes are not induced by SOS. In view of these results, we suggest there is an indirect relationship between NDP reductase and the chromosome segregation machinery through the maintenance of the proposed replication hyperstructure.

The synchrony phenotype persists after elimination of multiple GATC sites from the dnaA promoter of Escherichia coli.

To examine whether methylation of the GATC sites present in the dnaA promoter region is responsible for the strict temporal coordination of initiation events at oriC as measured by the synchrony of initiation, we introduced point mutations eliminating three (TGW1) and five (TGW2) of the six GATC sites present in the dnaA promoter region. All of the strains containing these mutations, including the one with five GATC sites eliminated, initiated chromosomal replication synchronously.

Escherichia coli cells with increased levels of DnaA and deficient in recombinational repair have decreased viability.

The dnaA operon of Escherichia coli contains the genes dnaA, dnaN, and recF encoding DnaA, beta clamp of DNA polymerase III holoenzyme, and RecF. When the DnaA concentration is raised, an increase in the number of DNA replication initiation events but a reduction in replication fork velocity occurs. Because DnaA is autoregulated, these results might be due to the inhibition of dnaN and recF expression. To test this, we examined the effects of increasing the intracellular concentrations of DnaA, beta clamp, and RecF, together and separately, on initiation, the rate of fork movement, and cell viability. The increased expression of one or more of the dnaA operon proteins had detrimental effects on the cell, except in the case of RecF expression. A shorter C period was not observed with increased expression of the beta clamp; in fact, many chromosomes did not complete replication in runout experiments. Increased expression of DnaA alone resulted in stalled replication forks, filamentation, and a decrease in viability. When the three proteins of the dnaA operon were simultaneously overexpressed, highly filamentous cells were observed (>50 micro m) with extremely low viability and, in runout experiments, most chromosomes had not completed replication. The possibility that recombinational repair was responsible for the survival of cells overexpressing DnaA was tested by using mutants in different recombinational repair pathways. The absence of RecA, RecB, RecC, or the proteins in the RuvABC complex caused an additional approximately 100-fold drop in viability in cells with increased levels of DnaA, indicating a requirement for recombinational repair in these cells.

Ribonucleoside diphosphate reductase is a component of the replication hyperstructure in Escherichia coli.

Although the nrdA101 allele codes for a ribonucleoside diphosphate (rNDP) reductase that is essentially destroyed in less than 2 min at 42 degrees C, and chemical inhibition of the enzyme by hydroxyurea stops DNA synthesis at once, we found that incubation at 42 degrees C of an Escherichia coli strain containing this allele allows DNA replication for about 40min. This suggests that mutant rNDP reductase is protected from thermal inactivation by some hyperstructure. If, together with the temperature upshift, RNA or protein synthesis is inhibited, the thermostability time of the mutant rNDP reductase becomes at least as long as the replication time and residual DNA synthesis becomes a run-out replication producing fully replicated chromosomes. This suggests that cessation of replication in the nrdA101 mutant strain is not the result of inactivation of its gene product but of the activity of a protein reflecting the presence of a partially altered enzyme. The absence of Tus protein, which specifically stops the replication complex by inhibiting replicative helicase activity, allows forks to replicate for a longer time at the restrictive temperature in the nrdA101 mutant strain. We therefore propose that rNDP reductase is a component of the replication complex, and that this association with other proteins protects the protein coded by allele nrdA101 from thermal inactivation.