A novel dnaC mutation that suppresses priB rep mutant phenotypes in Escherichia coli K-12

The loading of a replisome in prokaryotic and eukaryotic cells at an origin of DNA replication and during replication restart is a highly ordered and regulated process. During replication restart in Escherichia coli, the PriA, PriB, PriC, DnaT and Rep proteins form multiple pathways that bind to repaired replication forks. These complexes are then recognized by DnaC as sites to load DnaB, the replicative helicase. Several dnaC mutations have been isolated that suppress phenotypes of some replication restart mutants. A new dnaC mutation (dnaC824) is reported here that efficiently suppresses priB rep mutant phenotypes. Furthermore, it is shown that dnaC824 will suppress phenotypes of priB priA300, rep priA300 and priB priC strains. Unlike other dnaC suppressors, it can only weakly suppress the absence of priA. Others have reported a different type of dnaC mutation, dnaC1331, is able to mimic priB mutant phenotypes. This is supported herein by showing that like dnaC1331, a priB mutation is synthetically lethal with a dam mutation and this can be rescued by a mutH mutation. Furthermore, priB dam lethality can also be suppressed by dnaC824. Like a priB mutation, a dnaC1331 mutation causes a priA2::kan-like phenotype when combined with priA300. Lastly, we show that dnaC824 is dominant to wild type and that dnaC1331 is recessive to wild type. Several models are discussed for the action of these mutant dnaC proteins in replication restart.     

Multiple genetic pathways for restarting DNA replication forks in Escherichia coli K-12

In Escherichia coli, the primosome assembly proteins, PriA, PriB, PriC, DnaT, DnaC, DnaB, and DnaG, are thought to help to restart DNA replication forks at recombinational intermediates. Redundant functions between priB and priC and synthetic lethality between priA2::kan and rep3 mutations raise the possibility that there may be multiple pathways for restarting replication forks in vivo. Herein, it is shown that priA2::kan causes synthetic lethality when placed in combination with either Deltarep::kan or priC303:kan. These determinations were made using a nonselective P1 transduction-based viability assay. Two different priA2::kan suppressors (both dnaC alleles) were tested for their ability to rescue the priA-priC and priA-rep double mutant lethality. Only dnaC809,820 (and not dnaC809) could rescue the lethality in each case. Additionally, it was shown that the absence of the 3'-5' helicase activity of both PriA and Rep is not the critical missing function that causes the synthetic lethality in the rep-priA double mutant. One model proposes that replication restart at recombinational intermediates occurs by both PriA-dependent and PriA-independent pathways. The PriA-dependent pathways require at least priA and priB or priC, and the PriA-independent pathway requires at least priC and rep. It is further hypothesized that the dnaC809 suppression of priA2::kan requires priC and rep, whereas dnaC809,820 suppression of priA2::kan does not.     

The rep Mutation III. Altered Structure of the Replicating Escherichia coli Chromosome

The rep gene function of Escherichia coli is essential for the replication of P2 and phiX174 double-stranded deoxyribonucleic acid (DNA). Compared with isogenic rep(+) strains, rep mutants show the following characteristics: larger cell size, more DNA per cell, and a slightly lower DNA/mass ratio. The replicating rep chromosomes show a steeper gradient of marker frequencies and contain more replicating forks per chromosome. The nucleoid body of rep mutants sediments faster and contains more DNA. We deduce that the rep function is required for the "normal" replication of the E. coli chromosome and that in its absence the E. coli chromosome replicates in an altered manner, perhaps involving slower-moving replicating forks.     

Replication fork reactivation in a dnaC2 mutant at non-permissive temperature in Escherichia coli

Replicative helicases unwind double-stranded DNA in front of the polymerase and ensure the processivity of DNA synthesis. In Escherichia coli, the helicase loader DnaC as well as factors involved in the formation of the open complex during the initiation of replication and primosomal proteins during the reactivation of arrested replication forks are required to recruit and deposit the replicative helicase onto single-stranded DNA prior to the formation of the replisome. dnaC2 is a thermosensitive allele of the gene specifying the helicase loader; at non-permissive temperature replication cannot initiate, but most ongoing rounds of replication continues through to completion (18% of dnaC2 cells fail to complete replication at non-permissive temperature). An assumption, which may be drawn from this observation, is that only a few replication forks are arrested under normal growth conditions. This assumption, however, is at odds with the severe and deleterious phenotypes associated with a null mutant of priA, the gene encoding a helicase implicated in the reactivation of arrested replication forks. We developed an assay that involves an abrupt inactivation of rounds of synchronized replication in a large population of cells, in order to evaluate the ability of dnaC2 cells to reactivate arrested replication forks at non-permissive temperature. We compared the rate at which arrested replication forks accumulated in dnaC2 priA(+) and dnaC2 priA2 cells and observed that this rate was lower in dnaC2 priA(+) cells. We conclude that while replication cannot initiate in a dnaC2 mutant at non-permissive temperature, a class of arrested replication forks (PriA-dependent and DnaC-independent) are reactivated within these cells.     

DNA double-strand breaks caused by replication arrest.

We report here that DNA double-strand breaks (DSBs) form in Escherichia coli upon arrest of replication forks due to a defect in, or the inhibition of, replicative DNA helicases. The formation of DSBs was assessed by the appearance of linear DNA detected by pulse-field gel electrophoresis. Processing of DSBs by recombination repair or linear DNA degradation was abolished by mutations in recBCD genes. Two E. coli replicative helicases were tested, Rep, which is essential in recBC mutants, and DnaB. The proportion of linear DNA increased up to 50% upon shift of rep recBTS recCTS cells to restrictive temperature. No increase in linear DNA was observed in the absence of replicating chromosomes, indicating that the formation of DSBs in rep strains requires replication. Inhibition of the DnaB helicase either by a strong replication terminator or by a dnaBTS mutation led to the formation of linear DNA, showing that blocked replication forks are prone to DSB formation. In wild-type E. coli, linear DNA was detected in the absence of RecBC or of both RecA and RecD. This reveals the existence of a significant amount of spontaneous DSBs. We propose that some of them may also result from the impairment of replication fork progression.     

RecA-mediated rescue of Escherichia coli strains with replication forks arrested at the terminus

The recombinational rescue of chromosome replication was investigated in Escherichia coli strains with the unidirectional origin oriR1, from the plasmid R1, integrated within oriC in clockwise (intR1(CW)) or counterclockwise (intR1(CC)) orientations. Only the intR1(CC) strain, with replication forks arrested at the terminus, required RecA for survival. Unlike the strains with RecA-dependent replication known so far, the intR1(CC) strain did not require RecBCD, RecF, RecG, RecJ, RuvAB, or SOS activation for viability. The overall levels of degradation of replicating chromosomes caused by inactivation of RecA were similar in oriC and intR1(CC) strains. In the intR1(CC) strain, RecA was also needed to maintain the integrity of the chromosome when the unidirectional replication forks were blocked at the terminus. This was consistent with suppression of the RecA dependence of the intR1(CC) strain by inactivating Tus, the protein needed to block replication forks at Ter sites. Thus, RecA is essential during asymmetric chromosome replication for the stable maintenance of the forks arrested at the terminus and for their eventual passage across the termination barrier(s) independently of the SOS and some of the major recombination pathways.     

The speed of the Escherichia coli fork in vivo depends on the DnaB:DnaC ratio

The DnaC protein is required for loading the DnaB helicase at oriC . Thus DnaC promotes the formation of the pre-replication complex, but must leave the complex in order for the DnaB protein to function as a helicase. In vitro , a slight excess of DnaC inhibits the movement of replication forks by inhibiting DnaB helicase activity (Allen and Kornberg, 1991). Here we show that inhibition of DNA replication by excess DnaC also occurs in vivo . The rate of replication-fork movement was measured by flow cytometry. Initiation of replication was inhibited with rifampicin and the rate of fork movement monitored during replication run-out by measuring the increase in the fraction of the cell population with fully replicated chromosomes. The replication rate was inversely related to the amount of excess DnaC protein. Initiation of replication was also inhibited. Co-overexpression of DnaB protein alleviated the inhibition of replication caused by moderate excess of DnaC. The results show that DnaC interacts with replication forks during elongation in vivo , probably by binding to DnaB and inhibiting its helicase activity. Therefore, the ratio of DnaC to DnaB and the affinity of DnaC for a helicase hexamer at an established replication fork are of great importance for the rate of replication fork movement also in vivo .     

Isolation and characterization of temperature-sensitive mutants of the Staphylococcus aureus dnaC gene

A protein encoded by the Staphylococcus aureus dnaC gene has 44% and 58% homology with Escherichia coli DnaB and Bacillus subtilis DnaC replicative DNA helicases, respectively. We identified five mutant strains whose temperature-sensitive colony formation phenotypes were complemented by the dnaC gene. DNA replication in these mutants has a fast-stop phenotype, indicating that the S. aureus dnaC gene encodes the replicative DNA helicase required for the elongation step. These mutants were also sensitive to UV irradiation, suggesting that the dnaC gene is involved in DNA repair. The number of viable mutant cells decreased at a non-permissive temperature, suggesting that S. aureus DnaC helicase is a promising target for antibiotics providing bactericidal effects.     

Essential amino acids of Escherichia coli DnaC protein in an N-terminal domain interact with DnaB helicase

Escherichia coli DnaC protein bound to ATP forms a complex with DnaB protein. To identify the domain of DnaC that interacts with DnaB, a genetic selection was used based on the lethal effect of induced dnaC expression and a model that inviability arises by the binding of DnaC to DnaB to inhibit replication fork movement. The analysis of dnaC alleles that preserved viability under elevated expression revealed an N-terminal domain of DnaC involved in binding to DnaB. Mutant proteins bearing single amino acid substitutions (R10P, L11Q, L29Q, S41P, W32G, and L44P) that reside in regions of predicted secondary structure were inert in DNA replication activity because of their inability to bind to DnaB, but they retained ATP binding activity, as indicated by UV cross-linking to [alpha-(32)P]ATP. These alleles also failed to complement a dnaC28 mutant. Other selected mutations that map to regions carrying Walker A and B boxes are expected to be defective in ATP binding, a required step in DnaB-DnaC complex formation. Lastly, we found that the sixth codon from the N terminus encodes aspartate, resolving a reported discrepancy between the predicted amino acid sequence based on DNA sequencing data and the results from N-terminal amino acid sequencing (Nakayama, N., Bond, M. W., Miyajima, A., Kobori, J., and Arai, K. (1987) J. Biol. Chem. 262, 10475-10480).     

Protein--protein interactions in the eubacterial replisome

Replication of genomic DNA is a universal process that proceeds in distinct stages, from initiation to elongation and finally to termination. Each stage involves multiple stable or transient interactions between protein subunits with functions that are more or less conserved in all organisms. In Escherichia coli, initiation of bidirectional replication at the origin (oriC) occurs through the concerted actions of the DnaA replication initiator protein, the hexameric DnaB helicase, the DnaC?helicase loading partner and the DnaG primase, leading to establishment of two replication forks. Elongation of RNA primers at each fork proceeds simultaneously on both strands by actions of the multimeric replicase, DNA polymerase III holoenzyme. The fork that arrives first in the terminus region is halted by its encounter with a correctly-oriented complex of the Tus replication terminator protein bound at one of several Ter sites, where it is trapped until the other fork arrives. We summarize current understanding of interactions among the various proteins that act in the different stages of replication of the chromosome of E. coli, and make some comparisons with the analogous proteins in Bacillus subtilis and the coliphages T4 and T7.     

DNA mismatch repair-induced double-strand breaks

Escherichia coli dam mutants are sensitized to the cytotoxic action of base analogs, cisplatin and N-methyl-N'-nitro-N-nitrosoguanidine (MNNG), while their mismatch repair (MMR)-deficient derivatives are tolerant to these agents. We showed previously, using pulse field gel electrophoresis (PFGE), that MMR-mediated double-strand breaks (DSBs) are produced by cisplatin in dam recB(Ts) cells at the non-permissive temperature. We demonstrate here that the majority of these DSBs require DNA replication for their formation, consistent with a model in which replication forks collapse at nicks or gaps formed during MMR. DSBs were also detected in dam recB(Ts) ada ogt cells exposed to MNNG in a dose- and MMR-dependent manner. In contrast to cisplatin, the formation of these DSBs was not affected by DNA replication and it is proposed that two separate mechanisms result in DSB formation. Replication-independent DSBs arise from overlapping base excision and MMR repair tracts on complementary strands and constitute the majority of detectable DSBs in dam recB(Ts) ada ogt cells exposed to MNNG. Replication-dependent DSBs result from replication fork collapse at O(6)-methylguanine (O(6)-meG) base pairs undergoing MMR futile cycling and are more likely to contribute to cytotoxicity. This model is consistent with the observation that fast-growing dam recB(Ts) ada ogt cells, which have more chromosome replication origins, are more sensitive to the cytotoxic effect of MNNG than the same cells growing slowly.     

Fine balance in the regulation of DnaB helicase by DnaC protein in replication in Escherichia coli.

The DnaC protein of Escherichia coli is essential for replication in vivo and in vitro. In the initiation of replication of a minichromosome at its origin, DnaC delivers the DnaB helicase from a DnaB.DnaC complex to the future replication fork and then departs. However, if an excess of DnaC was present in subsequent steps, it severely inhibited replication by slowing the DnaB helicase at the replication fork. When DnaB was present at a level equimolar with the excess DnaC, the inhibition was relieved, implying that the ratio of DnaC to DnaB is critical for achieving optimal replication activity and avoiding inhibition by DnaC. In vivo, overproduction of DnaC slowed cell growth. This slowing was alleviated by overproducing DnaB at the same time. E. coli strains with a dnaCts gene defective in chromosomal initiation were complemented by the wild-type gene in trans. On the other hand, strains with an elongation-defective dnaCts gene were not complemented by the wild-type dnaC gene. The dominance of the mutant protein suggests that it remains tightly complexed with DnaB at the replication fork, inhibiting elongation even in the presence of the wild-type DnaC.     

Genome-wide replication profiles of S-phase checkpoint mutants reveal fragile sites in yeast

The S-phase checkpoint kinases Mec1 and Rad53 in the budding yeast, Saccharomyces cerevisiae, are activated in response to replication stress that induces replication fork arrest. In the absence of a functional S-phase checkpoint, stalled replication forks collapse and give rise to chromosome breakage. In an attempt to better understand replication dynamics in S-phase checkpoint mutants, we developed a replication origin array for budding yeast that contains 424 of 432 previously identified potential origin regions. As expected, mec1-1 and rad53-1 mutants failed to inhibit late origin activation. Surprisingly however, 17 early-firing regions were not replicated efficiently in these mutants. This was not due to a lack of initiation, but rather to problems during elongation, as replication forks arrested in close proximity to these origins, resulting in the accumulation of small replication intermediates and eventual replication fork collapse. Importantly, these regions were not only prone to chromosome breakage in the presence of exogenous stress but also in its absence, similar to fragile sites in the human genome.     

dnaC-dependent reconstitution of replication forks in Escherichia coli lysates.

Lysates of Escherichia coli exhibit a DNA-synthesizing activity that depends on the presence of replication forks and of replication proteins. Replicative activity was reconstituted in vitro by mixing lysates prepared from temperature-sensitive dnaB mutants with wild-type dnaB protein. Lysates of double mutants deficient in both dnaB and dnaC genes could only be complemented by the addition of both dnaB and dnaC proteins, whereas lysates deficient in dnaC protein did not require the addition of any exogenous factor. This shows that the replication machinery, once it is running along the chromosome, is independent of dnaC protein, dnaC activity, however, is required for the replacement of defective dnaB protein at running replication forks.     

Sequential binding of SeqA protein to nascent DNA segments at replication forks in synchronized cultures of Escherichia coli

To demonstrate that sequestration A (SeqA) protein binds preferentially to hemimethylated GATC sequences at replication forks and forms clusters in Escherichia coli growing cells, we analysed, by the chromatin immunoprecipitation (ChIP) assay using anti-SeqA antibody, a synchronized culture of a temperature-sensitive dnaC mutant strain in which only one round of chromosomal DNA replication was synchronously initiated. After synchronized initiation of chromosome replication, the replication origin oriC was first detected by the ChIP assay, and other six chromosomal regions having multiple GATC sequences were sequentially detected according to bidirectional replication of the chromosome. In contrast, DNA regions lacking the GATC sequence were not detected by the ChIP assay. These results indicate that SeqA binds hemimethylated nascent DNA segments according to the proceeding of replication forks in the chromosome, and SeqA releases from the DNA segments when fully methylated. Immunofluorescence microscopy reveals that a single SeqA focus containing paired replication apparatuses appears at the middle of the cell immediately after initiation of chromosome replication and the focus is subsequently separated into two foci that migrate to 1/4 and 3/4 cellular positions, when replication forks proceed bidirectionally an approximately one-fourth distance from the replication origin towards the terminus. This supports the translocating replication apparatuses model.     

sbcB sbcC null mutations allow RecF-mediated repair of arrested replication forks in rep recBC mutants

We have proposed previously that, in Escherichia coli, blockage of replication forks can lead to the reversal of the fork. Annealing of the newly synthesized strands creates a double-stranded end adjacent to a Holliday junction. The junction is migrated away from the DNA end by RuvAB and can be cleaved by RuvC, while RecBCD is required for the repair of the double-stranded tail. Consequently, the rep mutant, in which replication arrests are frequent and fork reversal occurs, requires RecBCD for growth. We show here that the combination of sbcB sbcCD null mutations restores the viability to rep recBC mutants by activation of the RecF pathway of recombination. This shows that the proteins belonging to the RecF pathway are able to process the DNA ends made by the replication fork reversal into a structure that allows recombination-dependent replication restart. However, we confirm that, unlike sbcB null mutations, sbcB15, which suppresses all other recBC mutant defects, does not restore the viability of rep recBC sbcCD strains. We also show that ruvAB inactivation suppresses the lethality and the formation of double-stranded breaks (DSBs) in a rep recBC recF strain, totally deficient for homologous recombination, as well as in rep recBC mutants. This confirms that RuvAB processing of arrested replication forks is independent of the presence of recombination intermediates.     

FtsK controls metastable recombination provoked by an extra Ter site in the Escherichia coli chromosome terminus

The FtsK protein is required for septum formation in Escherichia coli and as a DNA translocase for chromosome processing while the septum closes. Its domain of action on the chromosome overlaps the replication terminus region, which lies between replication pause sites TerA and TerC. An extra Ter site, PsrA*, has been inserted at a position common to the FtsK and terminus domains. It is well tolerated, although it compels replication forks travelling clockwise from oriC to stall and await arrival of counter-clockwise forks. Elevated recombination has been detected at the stalled fork. Analysis of PsrA*-induced homologous recombination by an excision test revealed unique features. (i) rates of excision near PsrA* may fluctuate widely from clone to clone, a phenomenon we term whimsicality, (ii) excision rates are nevertheless conserved for many generations, a phenomenon we term memorization; their metastability at the clone level is explainable by frequent shifting between three cellular states--high, medium and low probability of excision, (iii) PsrA*-induced excision is RecBC-independent and is strongly counteracted by FtsK, which in addition is involved in its whimsicality and (iv) whimsicality disappears as the distance from the pause site increases. Action of FtsK at a replication fork was unexpected because the factor was thought to act on the chromosome only at septation, i.e. after replication is completed. Idiosyncrasy of PsrA*-induced recombination is discussed with respect to possible intermingling of replication, repair and post-replication steps of bacterial chromosome processing during the cell cycle.