Thymineless death (TLD) is a classic and enigmatic phenomenon, documented in bacterial, yeast, and human cells, whereby cells lose viability rapidly when deprived of thymine. Despite its being the essential mode of action of important chemotherapeutic agents, and despite having been studied extensively for decades, the basic mechanisms of TLD have remained elusive. In Escherichia coli, several proteins involved in homologous recombination (HR) are required for TLD, however, surprisingly, RecA, the central HR protein and activator of the SOS DNA–damage response was reported not to be. We demonstrate that RecA and the SOS response are required for a substantial fraction of TLD. We show that some of the Rec proteins implicated previously promote TLD via facilitating activation of the SOS response and that, of the roughly 40 proteins upregulated by SOS, SulA, an SOS–inducible inhibitor of cell division, accounts for most or all of how SOS causes TLD. The data imply that much of TLD results from an irreversible cell-cycle checkpoint due to blocked cell division. FISH analyses of the DNA in cells undergoing TLD reveal blocked replication and apparent DNA loss with the region near the replication origin underrepresented initially and the region near the terminus lost later. Models implicating formation of single-strand DNA at blocked replication forks, a SulA-blocked cell cycle, and RecQ/RecJ-catalyzed DNA degradation and HR are discussed. The data predict the importance of DNA damage-response and HR networks to TLD and chemotherapy resistance in humans.
A long-standing enigma in the fields of DNA repair and cancer chemotherapy is why it is that cells starved of the base thymine die rapidly. This process, called thymineless death (TLD), is conserved in bacterial, yeast, and human cells and is the mode of action of important cancer chemotherapeutic drugs. Tumors that become resistant to those drugs have ceased to die from TLD. Despite its ubiquity, importance, and having been studied for more than 50 years, the mechanism(s) of TLD remained elusive. Here we show that a large fraction of TLD requires RecA, the central protein in homologous recombinational (HR) DNA repair, and activation of the bacterial DNA–damage (or SOS) response, which RecA controls. We find that of the 40 or so proteins upregulated during an SOS response, SulA, an inhibitor of cell division, accounts for most of how SOS–activation causes TLD. In cells undergoing TLD, we observe blocked replication of the E. coli chromosome followed by loss of DNA near the replication origin then terminus. This implies that much of TLD results from an irreversible cell-cycle checkpoint that blocks cell division when single-stranded DNA (the SOS–inducing signal) accumulates and that the rest results from DNA destruction, models for which are presented.
Citation: Fonville NC, Bates D, Hastings PJ, Hanawalt PC, Rosenberg SM (2010) Role of RecA and the SOS Response in Thymineless Death in Escherichia coli. PLoS Genet 6(3): e1000865. doi:10.1371/journal.pgen.1000865
Editor: Gregory S. Barsh, Stanford University School of Medicine, United States of America
Received: October 19, 2009; Accepted: January 29, 2010; Published: March 5, 2010
Copyright: © 2010 Fonville et al. This is an open-access article distributed under the terms of the Creative Commons Attribution License, which permits unrestricted use, distribution, and reproduction in any medium, provided the original author and source are credited.
Funding: Supported by National Institutes of Health (http://www.nih.gov) grants R01-GM64022 (PJH) and R01-CA85777 (SMR). The funders had no role in study design, data collection and analysis, decision to publish, or preparation of the manuscript.
Competing interests: The authors have declared that no competing interests exist.
Thymineless death (TLD), the rapid loss of viability in cultures deprived of thymine, occurs in E. coli, yeast and human cells (reviewed ). Cancer chemotherapeutic drugs methotrexate, 5-fluorouracil (5-FU), and fluorodeoxyuridine, and the antibiotic trimethoprim, work by inducing TLD by targeting thymidylate synthase and/or interfering with de novo synthesis of thymidine monophosphate. Whereas 5-FU kills cells both TLD-dependently and TLD-independently (reviewed ), newer drugs are being developed that target thymidylate synthase specifically . Despite its relevance to problems of chemotherapy resistance, and although studied extensively, the mechanism(s) responsible for TLD remain unclear.
Work by Sat et al. suggested that TLD in E. coli was a form of cell suicide induced by the MazF toxin gene, an RNase that can induce cell death under various stresses coincident with destruction of mRNAs , by a mechanism not fully understood. Though intriguing, this is probably not the full story of TLD. Whereas inhibition of transcription by various drugs relieved TLD –, MazF is repressed under active transcription by the presence MazE anti-toxin, and becomes available specifically when transcription is inhibited and MazE is degraded , such that inhibiting transcription would have been expected to exacerbate TLD (discussed ).
TLD also requires proteins involved in homologous recombination (HR) and repair, such as RecF and RecO which load RecA recombinase onto single-strand (ss)DNA ,, RecQ DNA helicase ,, and RecJ exonuclease . TLD is exacerbated in cells lacking the UvrD helicase , which acts in nucleotide excision repair (NER), and mismatch repair, and dismantles RecA filaments on single strand DNA, and so opposes HR . The UvrD anti-TLD role appears not to be via its role in NER, because NER-defective uvrA cells are not TLD hypersensitive . TLD is also exacerbated in cells lacking RecBCD, the main double–strand exonuclease and catalyst of double-strand-break repair by homologous recombination in E. coli . Chromosomal abnormalities/damage are associated with TLD in that cells undergoing TLD exhibit DNA breaks  and degradation . Further, abnormal DNA structures detected during TLD are reduced in cells lacking RecF, RecJ, RecQ or RecA . Despite this evidence supporting a mechanism for TLD involving HR proteins, surprisingly, RecA, the central HR protein and activator of the SOS DNA-damage response, was reported not to be required for TLD ,. In these studies non-null recA alleles were used: missense mutations recA1, recA13 and recA56 encode proteins with diminished strand exchange and SOS induction in vitro (measured by LexA cleavage), while retaining the ability to bind ssDNA ; and recA99 is an amber nonsense mutation that results in expression of a 7-amino-acid peptide ,. A single conflicting report using an undefined recA allele  drew the opposite conclusion, that RecA was involved in TLD. Moreover, the SOS response, which is controlled by RecA, was also reported not to affect TLD . This might have seemed to contradict a previous report that SulA, a protein made only during SOS, promoted TLD . However, that study tested sulA effects only in lon (protease-negative) cells, which have abnormally high SulA expression, leaving open the possibility that normally (in lon+ cells) SulA and SOS were not involved.
The evidence that numerous HR proteins promote TLD and the conflicting recA literature led us to reinvestigate the roles of RecA, HR proteins, and the SOS response in TLD. We show that RecA, is required for much of TLD, and that its major role is via the SOS response. We find that the SOS-controlled inhibitor of cell division, SulA, accounts for most of the requirement for the SOS response in TLD, implicating irreversible checkpoint activation, causing a block to cell division, as a major contributor to TLD. We find that HR proteins previously shown to be required for TLD promote TLD by both SOS-dependent and SOS-independent pathways involving chromosome-segregation failure and apparent chromosome-region-specific DNA destruction.
Roles of RecA in TLD
In contrast with previous results obtained with non-null recA alleles ,, we find that cells carrying a deletion of recA are initially more sensitive to thymine deprivation than rec+ cells (Figure 1A, before 180 min.), but are ultimately more resistant to TLD (Figure 1A, after 180 min.). The magnitude of the effect of the recA deletion is somewhat variable between experiments (e.g., Figure 1A versus Figure 1B), but we observed the same trend in a second genetic background KL742 (Figure S1). Most of the work presented uses the AB2497 genetic background because, first, it has been used commonly in the E. coli TLD literature (e.g., ,,), and second, it shows greater sensitivity to thymine deprivation than KL742.
Figure 1. RecA and the SOS response in TLD.
(A) ΔrecA cells (SMR10433, ▪) are significantly more sensitive to thymine deprivation than the isogenic parent (AB2497, ♦) at t≤120 min, but are significantly more resistant at t≥180 min. Inability to induce the SOS response and SulA reduces TLD: lexA3(Ind−) (SMR10669, ) and recA430 (SMR10668, ) “SOS-off” mutants are not significantly different from ΔrecA (SMR10433) at t≥240 min, but are significantly more resistant to TLD than their isogenic parent AB2497 at t≥150 min. sulA strain (SMR10674, ▴) shows TLD resistance similar to lexA3(Ind−) and recA430 “SOS-off” mutants, and significantly greater than the parent at t≥120 min. (B) RecA acts mostly via the LexA/SOS pathway of TLD. ΔrecA (SMR10433, ▪) and ΔrecA lexA3(Ind−) (SMR10912, △) mutants are slightly but not significantly more resistant to TLD than the lexA3(Ind−) single mutant (SMR10669, ), indicating that most of the RecA phenotype is via the LexA/SOS pathway. All three mutants are significantly more resistant than their rec+ lex+ parent AB2497 (♦). (C) RecA acts mostly in the SulA-dependent TLD pathway. ΔrecA sulA (SMR10713, ) is not significantly different from ΔrecA (SMR10670, ▪) but shows greater resistance to TLD than sulA (SMR10674, ▴) alone. Parental strain AB2497 (♦). (D) RuvABC protect cells from TLD. ΔruvABC (SMR10660, ) is more sensitive to TLD than its isogenic parent (AB2497, ♦), however ΔrecA ΔruvABC (SMR11118, •) cells are as resistant to TLD as ΔrecA (SMR10433, ▪). Mean ± SEM of 5 (A,B) or 3 (C,D) experiments. See Materials and Methods for statistical methods.doi:10.1371/journal.pgen.1000865.g001
The shape of the ΔrecA curve (Figure 1A, ▪s) implies that early during thymine deprivation RecA protects against TLD, but at later times RecA contributes to TLD. We do not know why in some instances, ΔrecA cultures show an increase in colony forming units (cfu) during TLD (e.g., Figure 1C between 120 and 180 min.). Perhaps in the absence of RecA some cells complete an additional round of cell division because some cells lyse, releasing thymine used by the remainder.
In the following section, we show that activation of the SOS DNA-damage response is required for much of TLD. To determine whether the apparent dual roles of RecA in TLD correspond to its two known functions in HR versus induction of the SOS response, we examined cells carrying the recA430 allele, which encodes a RecA protein that is competent for HR but defective for induction of the SOS response . We find that recA430 cells display the increased TLD resistance seen with the ΔrecA allele late in thymine starvation, but do not show the increased TLD sensitivity early in TLD seen with the ΔrecA null allele (Figure 1A). This implies that the early protective role of RecA in TLD is not via SOS-induction, and so could be via HR, whereas the later TLD-promoting role is via SOS induction (discussed below).
MazF is an RNase expressed during stress that leads to programmed cell death (reviewed ) and was implicated in TLD ,. The previously reported requirement for MazF in TLD was variable (complete  versus 4- to 5-fold ) and was not tested in AB2497, the strain used for much previous work on TLD. We wished to understand whether the role of RecA might be, for example, activating expression of MazF. To determine whether the observed role for RecA (Figure 1A, Figure S1) is part of the same pathway as the MazF RNase in TLD, we tested the magnitude of the mazF effect in the AB2497 strain used here. We find that ΔmazF caused a slight, but insignificant, increase in TLD resistance (Figure S2, see Materials and Methods for statistical methods), indicating that the MazF RNase is not a major mechanism contributing to TLD in this strain. Thus, the role of RecA in promoting TLD is likely to be independent of MazF.
SOS response and SulA in TLD
RecA functions both in HR and in induction of the SOS response to DNA damage (reviewed ,). The SOS response is induced when single-stranded (ss)DNA, the SOS-inducing signal, accumulates at sites of DNA damage or blocked replication forks. RecA binds the ssDNA, becomes activated as a co-protease and facilitates auto-proteolytic cleavage of the LexA transcriptional repressor, thus upregulating expression of about 40 damage-inducible SOS genes.
We found that blocking the ability of cells to induce SOS with either of two special “SOS-off” mutations conferred resistance to TLD: lexA3(Ind−), which encodes an uncleavable LexA/SOS repressor; and recA430, the recombination-proficient, SOS-induction-deficient recA allele (Figure 1A, orange s and grey s). We conclude that induction of the SOS response is required for TLD.
Both the lexA3(Ind−) and recA430 results reported here contradict a previous report that lexA3(Ind−) did not affect TLD-sensitivity . Experiments summarized in Figure S3 and legend indicate that the strain used previously contained the lexA3(Ind−) mutation but additionally carried another genetic element(s) that suppressed the TLD-resistance phenotype.
Addition of an operator-constitutive recAo allele, which constitutively produces SOS-induced levels of RecA, to the lexA3(Ind−) cells did not overcome the resistance to TLD conferred by lexA3(Ind−) (Figure S4), and is significantly different from the AB2497 parental strain only after 300 minutes of thymine deprivation (p = 0.012). We conclude that SOS-induced levels of a LexA-controlled function other than, or in addition to, RecA is required for TLD.
SulA is an inhibitor of cell division that is expressed only during an SOS response . We find that sulA cells are nearly as resistant to TLD as lexA3(Ind−) or recA430 cells (Figure 1A), indicating that SulA can account for most or nearly all of the role of the SOS response in TLD. These data imply that a large fraction of TLD results from an irreversible block to cell division caused by SOS induction and SulA expression.
The following data indicate that much of the role of RecA in promoting TLD results from its role in induction of SOS and SulA. First, we see that after 150 min ΔrecA cells are only slightly more resistant to TLD than sulA cells (Figure 1C). Because SulA induction requires RecA , this implies that most of the contribution of RecA to TLD is via the same pathway as SulA. Second, ΔrecA sulA cells show slightly, but statistically insignificantly greater TLD resistance than the ΔrecA single mutant (Figure 1C) indicating, as expected, that sulA functions completely in the same pathway as recA. Third, ΔrecA sulA is slightly but significantly more resistant than the sulA single mutant after 210 minutes of thymine deprivation (Figure 1C), indicating that SulA accounts for most, but not all, of the RecA role in TLD. Fourth, ΔrecA and ΔrecA lexA3(Ind−) cells are also slightly but insignificantly more TLD resistant late in TLD than lexA3(Ind−) single mutant cells (Figure 1B). This indicates that most of the ΔrecA phenotype late in TLD occurs via the same pathway (SOS induction) as that blocked in the lexA3(Ind−) “SOS-off” mutant. The slightly greater TLD resistance of ΔrecA single mutants and of both ΔrecA sulA and ΔrecA lexA3(Ind−) double mutants compared with sulA and lexA3(Ind−) single mutants suggest that there is a small SOS/SulA-independent role for RecA, however, most of the requirement for RecA in TLD appears to occur via the same pathway that leads to SOS/SulA induction. This could be because the important role of RecA in TLD is in inducing SOS directly or that, e.g., RecA-promoted HR intermediates cause SOS/SulA induction that leads to death, or both.
Holliday-junction-resolution prevents TLD
As noted above, there is a small RecA-dependent but SOS/SulA-independent component of TLD (previous paragraph, and Figure 1B and 1C). We hypothesized that this segment of TLD might result from “death-by-recombination” (per ), caused when interchromosomal HR intermediates (IRIs) accumulate and prevent chromosome segregation, thereby killing cells. Thymine deprivation could lead to ssDNA gaps in replicating DNA. Perhaps while some thymine remains, repair by HR with a sister chromosome is possible and protective, explaining the early part of the ΔrecA curve; but later in the complete absence of thymine, the cellular capacity to resolve RecA-promoted IRIs might be inhibited and accumulated IRIs could cause chromosome-segregation failure and death (model discussed below).
The RuvABC resolvasome constitutes a major pathway of IRI resolution in E. coli . The death-by-recombination hypothesis for TLD predicts that RuvABC would protect cells from TLD by reducing levels of IRIs that cause death. Indeed, we find that deletion of ruvABC makes cells more sensitive to TLD (Figure 1D). As predicted, this sensitivity is completely dependent on RecA activity (Figure 1D), implying that accumulation of unresolved RecA-promoted IRIs in cells lacking RuvABC promotes TLD. In support of the interpretation that ΔruvABC exacerbated TLD because of excess unprocessed HJs/IRIs, expression of an unrelated HJ resolvase, RusA, partially compensated for the lack of RuvABC (Figure S5A). RusA is encoded in a cryptic prophage and is expressed if cells carry the rus-1 mutation, which restores partial resistance to UV light to ruvC strains . These experiments do not address whether in wild-type (RuvABC+) cells TLD normally results from excess IRIs. To test this one would ideally provide more resolution capacity than in wild-type cells, and ask whether TLD was reduced. However, because of toxicity effects upon overproduction, interpretations of results from overproduction experiments are inconclusive, and we have not presented those here.
SOS–dependent and –independent roles of RecF in TLD
Having established a role for RecA in TLD via SulA/SOS response activation, we sought to determine whether other HR proteins previously shown to be required for TLD promote TLD by the same pathway.
RecF loads RecA onto ssDNA, a precursor to both HR and SOS induction , and is required for replication restart  apparently via activating SOS, in that SOS-constitutive-mutant cells no longer require RecF . We find that both ΔrecF lexA3(Ind−) (Figure 2A) and ΔrecF sulA (Figure 2B) cells show somewhat greater TLD resistance than lexA3(Ind−) and sulA single mutants, respectively. The difference is significant in both cases (Figure 2 legend). The data imply that most of role of RecF in TLD is in the SOS/SulA-dependent pathway leading to TLD, but that RecF also promotes TLD SOS/SulA-independently either via HR or another route.
Figure 2. RecF promotes TLD via SOS–dependent and SOS–independent pathways.
(A) The ΔrecF lexA3(Ind−) (SMR10692) double mutant () is more TLD resistant than its parent AB2497 (♦) and than lexA3(Ind−) (SMR10669, ▴), significant at t≥240 min, but not more than the ΔrecF (SMR10691, ▪) single mutant. (B) Similar results as (A) are seen for the ΔrecF sulA (SMR10694, ) double mutant: greater resistance than AB2497 (♦) and sulA (SMR10674, ▴) significant at t≥150 min, and similar resistance to ΔrecF (SMR10693, ▪). Mean ± SEM of 3 experiments (A,B).doi:10.1371/journal.pgen.1000865.g002
RecQ and RecJ promote TLD SOS/SulA- and RecA- independently
Under some conditions RecQ is required for SOS induction . To test whether the role of RecQ in TLD is via SOS/SulA induction, we examined ΔrecQ lexA3(Ind−) (Figure 3A) and ΔrecQ sulA (Figure 3B) cells. Both double mutants were significantly more resistant than their respective single-mutant controls indicating a wholly or partly additive TLD resistance when both SOS/SulA and RecQ are inactivated. We conclude that RecQ promotes TLD via a pathway wholly or partly independent of and additive with the SOS/SulA TLD pathway.
Figure 3. RecQ promotes TLD SOS- and RecA-independently.
(A) Additive effects of ΔrecQ and lexA3(Ind−) mutations. ΔrecQ lexA3(Ind−) (SMR10683, ) cells show significantly greater TLD resistance than either ΔrecQ (SMR10436, ▴) at t≥120 min or lexA3(Ind−) (SMR10669, ▪) at t≥270 min. Parental strain AB2497 (♦). (B) Additive effects of ΔrecQ and sulA mutations. ΔrecQ sulA (SMR10677, ) cells show significantly greater TLD resistance than ΔrecQ (SMR10436, ▴) at t≥180 min and sulA (SMR10674, ▪) at t≥120 min. (C) Additive effects of ΔrecQ and ΔrecA mutations. ΔrecQ ΔrecA (SMR10913, ) shows significantly greater TLD resistance than ΔrecQ (SMR10681, ▴) at t≥240 min and ΔrecA (SMR10433, ▪) at t≥210 min, indicating that RecQ and RecA promote TLD through different pathways. (D) Additive effects of ΔrecQ and ΔrecF mutations. ΔrecQ ΔrecF (SMR11205, ) is more resistant to TLD than either ΔrecF (SMR10691, ▪) or ΔrecQ (SMR10681, ▴) alone indicating that RecQ and RecF promote TLD through different pathways. Mean ± SEM of 5 (A,C) or 3 (B,D) experiments.doi:10.1371/journal.pgen.1000865.g003
If the sole role of RecQ in TLD were to assist RecA-mediated accumulation of IRIs leading to death by recombination, then loss of RecQ would be expected to provide no further resistance to TLD above that already seen in ΔrecA cells. However, we observed greater TLD resistance of ΔrecQ ΔrecA double mutants than ΔrecA cells (Figure 3C). Similarly, ΔrecQ ΔrecF double mutants showed greater resistance to TLD than ΔrecF or ΔrecQ (Figure 3D). We conclude that although RecQ might catalyze death-by-recombination in TLD in a minor pathway, it must also promote TLD by a RecA- RecF-independent, and thus HR-independent mechanism.
RecJ exonuclease is thought to work closely with RecQ to unwind and degrade nascent DNA at stalled replication forks ,, and recJ and recQ have similar phenotypes in TLD (Figure 4A and ), and also in a “death-by-recombination” pathway in which cells that accumulate unresolved interchromosomal recombination intermediates (IRIs) die from chromosome-segregation failure . We find that the double recQ recJ mutant is as resistant to TLD as recJ alone (Figure 4A) indicating that these two proteins promote TLD via the same pathway. Interestingly recJ has a greater resistance to TLD than recQ (Figure 4A), possibly because RecQ helicase can create the 5′-ssDNA-end substrate degraded by RecJ exonuclease (e.g., ,), but RecJ can also degrade 5′-ssDNA ends that arise via means other than RecQ. Like RecQ, RecJ promotes TLD via a pathway that is wholly or partly additive with, and thus wholly or partly independent of, SOS induction (Figure 4B); we find that ΔrecJ lexA3(Ind−) cells are significantly more TLD resistant than either ΔrecJ or lexA3(Ind−) single mutants. These data show that at least two pathways contribute to TLD, a RecA-, RecF-, and LexA-dependent one requiring SOS/SulA induction and another involving HR proteins RecQ and RecJ without SOS induction or RecA.
Figure 4. RecJ works with RecQ to promote TLD SOS-independently.
(A) RecJ functions in the same TLD pathway as RecQ. ΔrecQ ΔrecJ (SMR11198, ) is as resistant to TLD as ΔrecJ (SMR10695, ▪), but more resistant than ΔrecQ (SMR10681, ▴). Parental strain AB2497 (♦). (B) Additive effects of recJ and lexA3(Ind−) mutations. recJ lexA3 (SMR10696; ) cells show significantly greater TLD resistance than lexA3 (SMR10669, ▪) at t≥150 min and recJ (SMR10695, ▴) at t≥240 min. The wholly or partly additive effects of SOS/SulA with recQ and recJ mutations indicate that at least part of how RecQ and RecJ promote TLD is independent of the SOS/SulA death pathway. Mean ± SEM of 3 experiments (A,B).doi:10.1371/journal.pgen.1000865.g004
Topoisomerase III plays no role in TLD
Homologues of RecQ have been shown to work with Topoisomerase III in a “dissolvasome” complex to resolve converging replication  or recombination intermediates . We tested the possibility that Topoisomerase III was necessary for TLD, similarly to RecQ, but did not find significant resistance to TLD in cells lacking topB, the gene encoding Topoisomerase III (Figure S6).
Chromosome-segregation and -replication defects and DNA loss during TLD
We found that the majority of cells undergoing TLD exhibit severe chromosome-segregation defects (Figure 5A). Whereas most cells grown in the presence of thymine appear small and have discreet, segregated nucleoids (bacterial chromosomes), one hour after thymine deprivation most cells appear elongated with a single, small central DNA mass which appears to contain less DNA than normal nucleoids (Figure 5A and 5B 90 min). “Guillotining” of DNA during cell division (see Figure 5A) occurs early during TLD, whereas anucleate cells, which may result from degradation of broken/guillotined DNA or septum formation at the ends of elongated cells, appear later (Figure 5A).
Figure 5. Chromosome segregation and DNA loss during TLD.
(A) Chromosome-segregation defects in E. coli AB2497 during thymine deprivation. DAPI stained DNA appears as bright masses or nucleoids. ~300 cells scored per timepoint. (B) Representative FISH of AB2497 cells during TLD. Origins, green foci (and arrows); termini, red foci (and arrows); DNA, blue (DAPI). (C) Percentage of FISH-labeled cells with different numbers ori and ter foci showing loss of ori-proximal foci early, and ter-proximal foci late during TLD. 1000, 800, and 530 cells scored at 0, 90, and 120 min, respectively. Images in (B) are merges of 3 separate images taken with filters specific for green foci, red foci, and blue DAPI stain; however scoring of types in (B,C) was performed on individual non-merged filtered images in which only green or only red foci were visible. Mean ± SEM of 3 experiments.doi:10.1371/journal.pgen.1000865.g005
DNA content of the cells undergoing TLD appeared diminished with respect to both normal cells (Figure 5A) and cells dying the death-by-recombination observed previously . We examined chromosome replication and integrity using fluorescent in-situ hybridization (FISH) with probes homologous to the chromosomal replication origin (ori) (green) and terminus (ter) (red, Figure 5B). At time 0, cells were small with an average of 2.2±0.1:1 labeled ori:ter foci. Per Figure 5C, 45% had 2 ori and 1 ter focus, expected in replicating DNA, 23% had 1 of each, and 17% and 11% had only one ori or ter focus, respectively. The 17% and 11% with only one ori or ter focus presumably reflect the imperfect efficiency of the FISH probes to reveal their targets, as reported previously ,, which is a constant for each probe set against which deviations are compared and normalized (,, Figure 5C).
The profile of ori and ter foci changed dramatically with prolonged thymine deprivation (Figure 5C). At 90 min (Figure 5C), only 3% had 2 ori:1 ter, whereas 64% had 1 of each. Although it is formally possible that many chromosomes completed replication but did not re-initiate, this is highly unlikely given the absence of thymine. A more likely explanation is that replication halted mid-chromosome. In this second (more likely) instance, the subsequent shift from the majority of cells containing 2 ori and 1 ter to the majority containing a single ori and ter over the first 90 min of thymine deprivation may indicate that ori-containing DNA was specifically lost or destroyed. Significantly, those with 1 ori:0 ter focus increased to 28%, implying loss of ter-containing DNA. Supporting this interpretation, the fraction with 1 ter:0 ori decreased to 1.6%. This pattern was more pronounced at 210 min (Figure 5C), at which time 2 ori:1 ter cells fell further to 2.3%; 1 ori:1 ter cells dropped to 46%; while cells with 1ori:0ter increased correspondingly to 48%. During normal segregation of daughter chromosomes, first, ori's segregate to the distal cell poles away from the cell-division septum while the ter sequences localize at the septum and are replicated and segregated last  (illustrated Figure 6E). During TLD, first, all of the foci stayed mid-cell, where the cell-division septum would form in nonarrested cells (Figure 5B); second, the number of foci per cell is fewer than normal (Figure 5B and 5C); and third, the accumulation of 1 ori:1 ter cells replacing 2 ori: 1 ter cells, followed by depletion of 1 ori:1 ter and concurrent accumulation of 1 ori:0 ter cells implies that chromosomes either completed replication then lost their ter sequences, or, more likely given the general DNA reduction seen (Figure 5A and 5B), lost one of their two oris, then subsequently lost ter-containing DNA. We failed to observe a significant fraction of cells containing a single ter and no ori (discussed below). The apparent degradation of DNA near ter (which is probably preceded by degradation near one of the two oris) could be caused by chromosome tearing as cells try to segregate unresolved chromosomes, perhaps unsegregated because of IRIs per death-by-recombination models (Figure 6E), or by RecQ/J-promoted DNA degradation, discussed below.
Figure 6. Models for TLD by SOS, death-by-recombination, and RecQ/J-promoted DNA destruction.
(A) Gaps in DNA result from insufficient thymine. (B) Gap extension by RecQ and RecJ. (C) RecF-assisted RecA loading at ssDNA gaps promotes strand exchange and IRI formation. (D) Some portion of IRIs can be resolved by RuvABC to yield segregated chromosomes. (E) “Death-by-recombination,” a death caused by failed chromosome segregation, occurs when more IRIs accumulate than can be processed by Ruv and other IRI-resolution pathways . (F) SOS induction and SulA production create an irreversible cell-cycle checkpoint which prevents cells from recovering upon addition of thymine. Note that all ssDNA substrates drawn, including those in G, H and I could lead to SOS-induction. (G) RecQ/J-mediated DNA fragmentation, a possible mechanism for the RecA-independent contribution of RecQ/J to TLD. This degradation towards the ori from stopped forks along the chromosome, then (not shown) RecBCD-mediated degradation of the double-stranded DNA end back, past ori, to the next stalled fork, would lead to specific loss of ori-containing DNA. (H) RecQ/RecJ-promoted DNA destruction. Nascent-strand removal from stopped forks to ori and past to the next stopped fork, might be used to restore arrested replication bubbles to the duplex state, but creates extensive ssDNA. (I) Breakage of an old strand in regions of extensive ssDNA, shown here to occur if a hairpin forms and is cleaved by a hairpin endonuclease (but possible with other secondary structures), opens the whole chromosome up to degradation by RecQ and RecJ. This model accounts for apparent loss of first ori- then ter-containing DNAs. Lines, strands of DNA except in bottommost schemes (F, and H left) in which solid and dashed circles represent whole bacterial chromosomes; arrow heads, 3′ ends; IRI, interchromosomal recombination intermediate.doi:10.1371/journal.pgen.1000865.g006
The data presented establish a prominent role for RecA, the SOS response and the SOS-controlled SulA inhibitor of cell division in TLD. They further show that at least three pathways of TLD operate concurrently with a remarkable pattern of chromosome-segregation failure and chromosome-region-specific loss of FISH-detectable foci, in which first apparent replication-origin-containing then terminus-proximal DNA disappeared.
Death by SOS
First, a major TLD pathway, constituting ≥1 of the 2–3 logs of loss of colony-forming ability observed by 300 min of thymine starvation, is attributable to RecA- and RecF-dependent activation of the SOS DNA-damage response turning on the SulA inhibitor of cell division (Figure 1, Figure 2). This implies, surprisingly, that a significant fraction of TLD results from an irreversible cell-cycle checkpoint such that when returned to medium with thymine in the cfu assay, cell division does not resume. Simply removing sulA allowed these cells to form colonies (Figure 1, Figure 2, Figure 3), as if many of the underlying DNA problems that caused SOS induction and SulA expression were not themselves lethal. Irreversible SOS-induction causing apparent cell stasis or senescence has been reported previously in a study from one of our laboratories of spontaneous SOS induction in growing E. coli populations which showed that only about 30% of spontaneously SOS-induced cells recover to a proliferating state . The discovery that at least a log of TLD results from inhibition of cell division raises the possibility that some TLD might reflect cell stasis rather than death. A model for the SOS/SulA dependent component of TLD is shown in Figure 6F. SOS is activated when RecA binds ssDNA . In Figure 6 we consider potential sources of ssDNA that might activate SOS during TLD, some of which would not otherwise kill cells (discussed below).
Death by recombination
A minor second TLD pathway appeared to require RecA but not SulA (Figure 1C) and so might reflect a lethal role of HR. In Figure 6A–6E we consider a “death-by-recombination” model for this component of TLD, based on the observations of death by recombination in Holliday-junction-resolution-defective cells ( and references therein). In it we hypothesize that ssDNA gaps caused by inability to replicate in the absence of thymine provoke the RecQ, J, F, A-dependent initiation of HR with a sister chromosome (Figure 6A–6E) creating interchromosomal recombination intermediates (IRIs, Figure 6D and 6E). IRIs are normally resolved by RuvABC allowing chromosome separation (Figure 6D) , but we suggest that when the number of gaps and resulting IRIs exceeds resolution capacity, their failure to be resolved will cause death by failed chromosome segregation (Figure 6E). Death by failed chromosome segregation caused by excessive IRI accumulation (“death-by-recombination”) was seen in cells lacking Ruv resolution and UvrD anti-RecA proteins  and cells lacking UvrD and RecG Holliday-junction-processing proteins , and, like TLD, required RecA, RecF, RecQ and RecJ (SOS independently). As predicted by this model, TLD is associated with failed chromosome segregation (Figure 5) and is exacerbated by removal of RuvABC (Figure 1D), implying that a mechanism like this can occur at least in Ruv-deficient cells. A possible death-by-recombination component of TLD might underlie the minor RecA-dependent SulA-independent fraction of TLD (Figure 1C).
Death by RecQ and RecJ
In Figure 6G–6I we suggest two HR-independent ways by which RecQ and RecJ could cause TLD and the DNA destruction suggested by our cytological and FISH results (Figure 5). In Figure 6G, RecQ helicase and RecJ 5′ exonuclease are shown degrading DNA at a 5′ end at a replication fork lagging strand , leading to DNA fragmentation when the next fork upstream is reached. Because this mechanism degrades newly replicated DNA from a stopped fork towards the ori, this might cause the observed loss of ori-containing foci early during TLD (Figure 5B and 5C, assuming degradation of the double-strand DNA end created, see Figure 6G), and could explain RuvC-independent linearization of E. coli chromosomes during TLD reported by Guzman and colleagues , but does not explain ter-specific DNA loss.
Similarly, when replication forks stop in thymine-starved cells, RecQ 5′ helicase and RecJ 5′ single-strand-dependent exonuclease might degrade DNA extensively from the forks' 5′-ending lagging strands back towards the ori (Figure 6H), removing both nascent strands from arrested replication bubbles so that cells unable to complete replication return their chromosomes to a simple double-stranded circular starting point allowing re-initiation of replication later, when replication precursors are available (not an apparently death-promoting activity).
Although this appears to predict only ori-proximal DNA loss, extensive nascent-strand degradation would expose long tracts of ssDNA, which would induce SOS and might also be susceptible to further breakage upon exposure of secondary-structure-forming sequences in the extensive ssDNA regions (Figure 6I). Digestion of secondary structures would break an “old” strand in these replication bubbles which would then open up the whole chromosome to degradative activities, including the ter (Figure 6I). This might underlie the initial loss of ori-containing FISH foci, and later loss of terminus-proximal FISH foci because after an old strand is broken, single-strand degradation can pass a stopped fork and proceed towards the terminus (Figure 6I, right). Although simple removal of nascent strands (Figure 6H) would be expected not to be lethal, breaking an old strand followed by chromosome degradation (Figure 6I) could be lethal. Both models 6G and 6I can explain why there is first loss of only one of two ori foci.
Another possibility for ter-specific DNA loss is that chromosome dimers formed by HR that are not resolved will accumulate as shown in Figure 6E, with ters at the cell-division septum and ori's away from it . Tearing of unresolved chromosomes might be expected to occur terminus proximally and this could set off degradation specific to the ter region. Perhaps chromosome dimers formed by HR, which are usually resolved at the septum by XerCD , cannot be resolved when cell division is blocked by SulA, and this could result in such tearing (Figure 6E).
Other TLD pathway(s)
In addition to the TLD pathways listed, our data indicate that at least one more must operate because recA recQ cells which are defective for SOS, HR, and the SOS/HR-independent roles for RecQ in TLD, still suffer ≥1 log of TLD by 300 min (Figure 4C).
Cancer chemotherapies and resistance
Thymineless death is the mode of action of important cancer chemotherapeutic drugs methotrexate, 5-fluorouracil and 5-fluorodeoxyuridine, as well as the antibiotic trimethoprim. The results presented here catalogue a series of proteins and pathways that if disrupted could be expected to confer some level of resistance to those drugs in bacteria and humans. Humans have several RecA homologues including RAD51, whose function in double-strand-break repair by HR is disrupted in BRCA-defective cells including in some breast and ovarian cancers (reviewed ). Humans possess five RecQ homologues, defects in three of which are known to be associated with cancer-predisposition syndromes (reviewed ), any of which might also be defective in sporadic cancers. Cancers with the homologues and analogues of these bacterial DNA repair pathways disrupted might be resistant to TLD, and so to treatment with TLD-inducing drugs. Similarly disruption of the eukaryotic DNA-damage responses and checkpoints might also confer resistance as seen for the SOS response here. The DNA repair, replication and metabolism pathways are very well conserved from bacteria to humans (reviewed ) making application of these mechanisms to human cancer treatment plans and investigations practical and imperative.
Materials and Methods
Strains and TLD assays
Origins of strains used in this study are given in Table S1. P1 transductions were as described . TLD experiments were as described  with minor variations. Thymine auxotrophs were grown at 37°C with shaking in M9 minimal medium with 50 µg/ml thymine, 0.1% glucose and 0.5% casamino acids, and for strains containing pGB2 or pGBruvABC, 100 µg/ml spectinomycin. Saturated cultures were diluted 25-fold into the same medium and grown to early/mid-log (OD450 of 0.5). 1.0 ml samples were centrifuged, washed twice with M9 saline solution, and resuspended in 2.0 ml of M9 with glucose and casamino acids (no thymine), then returned to 37°C, with shaking, for up to five hours with aliquots taken at intervals for cfu assays on LBH thymine plates. Cfu were scored on a Microbiology International ProtoCOL colony counter after 24 h at 37°C. Longer incubations verified that all cfu were apparent at 24 h. Because the absolute extent of killing varied widely between experiments, whereas the relative effect of the mutations used did not, data presented show curves that are means of sets of independent experiments in which absolute extents of killing were similar.
Error bars represent ± one SEM of ≥3 independent experiments. Statistical analyses were performed using SigmaStat. For TLD assays significance was determined as p<0.05 using repeated measure ANOVA to analyze the curve data, and Tukey post-hoc analysis.
Chromosome-segregation analyses were as described  with minor changes. Cells were fixed by adding an equal volume of PBS with 4% paraformaldehyde for 10 min at room temperature and 20 min on ice, washed three times with cold PBS and stored in an appropriate volume of PBS. Cells were stained with 4′,6-diamidino-2-phenylindole (DAPI; 1 µg/ml), placed on slides, and photographed with an Olympus B×51 microscope equipped with an Uplan Fluorite 100× oil objective, DAPI filter (U-N31000, Olympus), and an Olympus MagnaFire CCD digital camera.
Fluorescence in situ hybridization
FISH was as described . Probes were 6 kb DNA fragments PCR amplified (Phusion DNA polymerase, New England Biolabs) from MG1655 DNA. Primers for the ori and ter probes were as described . Probes were visualized using a Zeiss Axio Imager microscope equipped with 100× oil immersion objective, DAPI filter, Oregon Green filter, Rhodamine filter, and Hamamatsu EMCCD camera. Foci were scored on each channel prior to RGB merging of the images. Images were processed using Axiovision digital image processing software and ImageJ.
RecA is required for TLD in the KL742 strain background. ΔrecA cells (SMR10432, ▪) are significantly more resistant to TLD than KL742 (♦) at t≥180 min, and ΔrecQ cells (SMR10435, ▴) are significantly more resistant at t≥90 min. The results recapitulate those shown in Figure 1A, Figure 3A using the AB2497 strain background. Mean ± SEM of 3 experiments.
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MazF is not the predominant cause of TLD in the AB2497 strain background. A strain lacking the MazF toxin (SMR10685, ▪) of the MazEF toxin/antitoxin pair is slightly, but not significantly, more resistant to TLD than the parental strain (♦). Mean ± SEM of 3 experiments.
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The lexA3(Ind−) mutation causes TLD resistance in the HL353 strain background. This was observed when the strain HL353 lexA3(Ind−) was reconstructed (SMR10675, ▴), but not with the originally published construction: HL354 (▪). SMR10675 is significantly different from HL353 (♦) at t≥180 min. Mean ± SEM of 3 experiments. To understand why Morganroth and Hanawalt saw no TLD-resistance in a lexA3(Ind−) strain relative to its lexA+ parent , whereas we observed TLD resistance of both a lexA3(Ind−) strain and recA430 strain relative to their isogenic lexA+ recA+ parent (Figure 1A), we first repeated their result with their strains HL353 (Parental) and HL354 (lexAInd−) (this figure). Next, we reintroduced the lexA3(Ind−) allele by phage P1-mediated transduction into the HL353 genetic background used by Morganroth and Hanawalt, thus creating strain SMR10675. We observed that SMR10675, but not the originally published lexA3(Ind−) strain HL354, was TLD resistant (this figure), confirming our finding that an inducible SOS response is required for TLD. We sequenced the lexA gene and verified the presence of the lexA3(Ind−) mutation (G to A at position 355 [Markham, et al]) and the absence of any other mutation in the lexA gene or ≥500 bp up- or downstream of lexA in all three putative lexA3(Ind−) strains: ours in the AB2497 strain background (SMR10669), SMR10675 and HL354. Because the lexA3(Ind−) allele confers TLD-resistance in both genetic backgrounds, including when moved afresh into HL353, because a different SOS-off mutation, recA430, also confers TLD resistance, and because SulA is required for TLD (Figure 1A and 1C) and is expressed only during SOS [Courcelle, et al], we conclude that induction of SOS is required for TLD. It seems most likely that some other, unknown mutation(s) is present in HL354 which suppresses the TLD-resistance phenotype conferred by lexA3(Ind−) in that strain. [Markham BE, Little JW, Mount DW (1981) Nucleotide sequence of the lexA gene of Escherichia coli K-12. Nucleic Acids Res 9: 4149-4161.] [Courcelle J, Khodursky A, Peter B, Brown PO, Hanawalt PC (2001) Comparative gene expression profiles following UV exposure in wild-type and SOS-deficient Escherichia coli. Genetics 158: 41-64.]
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SOS–induced levels of RecA do not compensate for an uninducible SOS/LexA regulon in TLD. The recAo strain SMR10673 (▴) was not significantly different from the isogenic parent AB2497 (♦) except for at 300 minutes of thymine deprivation (p = 0.012) and recAo lexA3(Ind−) cells (SMR10676, ) were no more TLD sensitive than lexA3(Ind−) (SMR10669, ▪) or sulA (SMR10674, •) cells. Mean ± SEM of 3 experiments.
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RusA expression partially reverses the hyper-TLD-sensitivity of ΔruvABC cells. (A) The RusA resolvase, expressed in rus-1 cells, partially restores TLD resistance to ΔruvABC cells. In the ΔruvABC (SMR10689, ▴) background, the rus-1 allele (SMR10690, ) increased resistance to TLD, but in the thy− rus+ parental background (SMR10687, ▪) activating RusA via rus-1 mutation (SMR10686, ♦) did not have a significant effect. We cannot rule out the possibility that the lack of effect in Ruv+ cells is due to an inability of RusA to function when RuvABC are present (in vitro, RusA was inhibited by RuvA [McGlynn, et al]). Also, there is no reason to believe that rus-1 creates more resolution capacity than in wild-type cells, such that restoration to Ruv+ levels might be expected. (B) Possible RusA effects on TLD are not masked by SulA. Similar results to those in (A) are obtained even when RusA is activated in the absence of SulA. RusA activation partially suppressed the TLD hypersensitivity of ΔruvABC sulA cells (SMR10719, •, and SMR10718, ▴, respectively), but activating RusA in the absence of SulA (SMR10717, ▪) conferred no additional TLD-resistance over that conferred by sulA alone (SMR10716, ♦). This rules out the possibility that SulA expression might mask increased TLD-resistance of rus-1 cells by preventing cell division. Means ± SEM of 3 experiments (A,B). [McGlynn P, Lloyd RG, Marians KJ (2001) Formation of Holliday junctions by regression of nascent DNA in intermediates containing stalled replication forks: RecG stimulates regression even when the DNA is negatively supercoiled. Proc Natl Acad Sci U S A 98: 8235-8240.]
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Topoisomerase III is not required for TLD. Cells lacking topB (SMR10672, ▪) are not significantly more resistant to TLD than their isogenic parental strain (AB2497; ♦), indicating that Topoisomerase III is not required for the RecQ-pathway of TLD in E. coli. Mean ± SEM of 3 experiments.
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E. coli strains and plasmids used.
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We thank M. Blankschien, R. Galhardo, J. Gibson, C. Gonzales, J. Halliday, C. Herman, D. Magner, and Z. Vaksman for helpful suggestions and comments and R.G. Lloyd for the gift of a rus-1 strain.
Conceived and designed the experiments: NCF SMR. Performed the experiments: NCF. Analyzed the data: NCF DB PJH PCH SMR. Contributed reagents/materials/analysis tools: DB PCH SMR. Wrote the paper: NCF PJH PCH SMR.
- 1. Ahmad SI, Kirk SH, Eisenstark A (1998) Thymine metabolism and thymineless death in prokaryotes and eukaryotes. Annu Rev Microbiol 52: 591–625.
- 2. Longley DB, Harkin DP, Johnston PG (2003) 5-fluorouracil: mechanisms of action and clinical strategies. Nat Rev Cancer 3: 330–338.
- 3. Jackman AL, Taylor GA, Gibson W, Kimbell R, Brown M, et al. (1991) ICI D1694, a quinazoline antifolate thymidylate synthase inhibitor that is a potent inhibitor of L1210 tumor cell growth in vitro and in vivo: a new agent for clinical study. Cancer Res 51: 5579–5586.
- 4. Sat B, Reches M, Engelberg-Kulka H (2003) The Escherichia coli mazEF suicide module mediates thymineless death. J Bacteriol 185: 1803–1807.
- 5. Godoy VG, Jarosz DF, Walker FL, Simmons LA, Walker GC (2006) Y-family DNA polymerases respond to DNA damage-independent inhibition of replication fork progression. Embo J 25: 868–879.
- 6. Nakayama H, Hanawalt P (1975) Sedimentation analysis of deoxyribonucleic acid from thymine-starved Escherichia coli. J Bacteriol 121: 537–547.
- 7. Cummings DJ, Kusy AR (1969) Thymineless death in Escherichia coli: inactivation and recovery. J Bacteriol 99: 558–566.
- 8. Morganroth PA, Hanawalt PC (2006) Role of DNA replication and repair in thymineless death in Escherichia coli. J Bacteriol 188: 5286–5288.
- 9. Aizenman E, Engelberg-Kulka H, Glaser G (1996) An Escherichia coli chromosomal “addiction module” regulated by guanosine [corrected] 3′,5′-bispyrophosphate: a model for programmed bacterial cell death. Proc Natl Acad Sci U S A 93: 6059–6063.
- 10. Nakayama H, Nakayama K, Nakayama R, Nakayama Y (1982) Recombination-deficient mutations and thymineless death in Escherichia coli K12: reciprocal effects of recBC and recF and indifference of recA mutations. Can J Microbiol 28: 425–430.
- 11. Nakayama K, Shiota S, Nakayama H (1988) Thymineless death in Escherichia coli mutants deficient in the RecF recombination pathway. Can J Microbiol 34: 905–907.
- 12. Nakayama K, Irino N, Nakayama H (1985) The recQ gene of Escherichia coli K12: molecular cloning and isolation of insertion mutants. Mol Gen Genet 200: 266–271.
- 13. Nakayama H, Nakayama K, Nakayama R, Irino N, Nakayama Y, et al. (1984) Isolation and genetic characterization of a thymineless death-resistant mutant of Escherichia coli K12: identification of a new mutation (recQ1) that blocks the RecF recombination pathway. Mol Gen Genet 195: 474–480.
- 14. Siegal E (1973) Ultraviolet-Sensitive Mutator Strain of Escherichia coli K-12. J Bacteriol 113: 145–160.
- 15. Veaute X, Delmas S, Selva M, Jeusset J, Le Cam E, et al. (2005) UvrD helicase, unlike Rep helicase, dismantles RecA nucleoprotein filaments in Escherichia coli. Embo J 24: 180–189.
- 16. Freifelder D (1969) Single-strand breaks in bacterial DNA associated with thymine starvation. J Mol Biol 45: 1–7.
- 17. Breitman TR, Maury PB, Toal JN (1972) Loss of deoxyribonucleic acid-thymine during thymine starvation of Escherichia coli. J Bacteriol 112: 646–648.
- 18. Nakayama K, Kusano K, Irino N, Nakayama H (1994) Thymine starvation-induced structural changes in Escherichia coli DNA. Detection by pulsed field gel electrophoresis and evidence for involvement of homologous recombination. J Mol Biol 243: 611–620.
- 19. Anderson JA, Barbour SD (1973) Effect of thymine starvation on deoxyribonucleic acid repair systems of Escherichia coli K-12. J Bacteriol 113: 114–121.
- 20. Lauder SD, Kowalczykowski SC (1993) Negative co-dominant inhibition of recA protein function. Biochemical properties of the recA1, recA13 and recA56 proteins and the effect of recA56 protein on the activities of the wild-type recA protein function in vitro. J Mol Biol 234: 72–86.
- 21. Mount DW (1971) Isolation and genetic analysis of a strain of Escherichia coli K-12 with an amber recA mutation. J Bacteriol 107: 388–389.
- 22. Dutreix M, Moreau PL, Bailone A, Galibert F, Battista JR, et al. (1989) New recA mutations that dissociate the various RecA protein activities in Escherichia coli provide evidence for an additional role for RecA protein in UV mutagenesis. J Bacteriol 171: 2415–2423.
- 23. Inouye M (1971) Pleiotropic effect of the recA gene of Escherichia coli: uncoupling of cell division from deoxyribonucleic acid replication. J Bacteriol 106: 539–542.
- 24. Huisman O, D'Ari R, George J (1980) Inducible sfi dependent division inhibition in Escherichia coli. Mol Gen Genet 177: 629–636.
- 25. Howe WE, Mount DW (1975) Production of cells without deoxyribonucleic acid during thymidine starvation of lexA− cultures of Escherichia coli K-12. J Bacteriol 124: 1113–1121.
- 26. Ennis DG, Fisher B, Edmiston S, Mount DW (1985) Dual role for Escherichia coli RecA protein in SOS mutagenesis. Proc Natl Acad Sci U S A 82: 3325–3329.
- 27. Engelberg-Kulka H, Hazan R, Amitai S (2005) mazEF: a chromosomal toxin-antitoxin module that triggers programmed cell death in bacteria. J Cell Sci 118: 4327–4332.
- 28. Lusetti SL, Cox MM (2002) The bacterial RecA protein and the recombinational DNA repair of stalled replication forks. Annu Rev Biochem 71: 71–100.
- 29. Butala M, Zgur-Bertok D, Busby SJ (2009) The bacterial LexA transcriptional repressor. Cell Mol Life Sci 66: 82–93.
- 30. Friedberg E, Walker G, Siede W, Wood R, Schultz R, et al. (2005) DNA Repair and Mutagenesis, Second Edition. Washington, D.C.: ASM Press.
- 31. Magner DB, Blankschien MD, Lee JA, Pennington JM, Lupski JR, et al. (2007) RecQ promotes toxic recombination in cells lacking recombination intermediate-removal proteins. Mol Cell 26: 273–286.
- 32. Zerbib D, Mezard C, George H, West SC (1998) Coordinated actions of RuvABC in Holliday junction processing. J Mol Biol 281: 621–630.
- 33. Bolt EL, Lloyd RG (2002) Substrate specificity of RusA resolvase reveals the DNA structures targeted by RuvAB and RecG in vivo. Mol Cell 10: 187–198.
- 34. Courcelle J, Carswell-Crumpton C, Hanawalt PC (1997) recF and recR are required for the resumption of replication at DNA replication forks in Escherichia coli. Proc Natl Acad Sci U S A 94: 3714–3719.
- 35. Rangarajan S, Woodgate R, Goodman MF (2002) Replication restart in UV-irradiated Escherichia coli involving pols II, III, V, PriA, RecA and RecFOR proteins. Mol Microbiol 43: 617–628.
- 36. Hishida T, Han YW, Shibata T, Kubota Y, Ishino Y, et al. (2004) Role of the Escherichia coli RecQ DNA helicase in SOS signaling and genome stabilization at stalled replication forks. Genes Dev 18: 1886–1897.
- 37. Courcelle J, Hanawalt PC (1999) RecQ and RecJ process blocked replication forks prior to the resumption of replication in UV-irradiated Escherichia coli. Mol Gen Genet 262: 543–551.
- 38. Suski C, Marians KJ (2008) Resolution of converging replication forks by RecQ and Topoisomerase III. Mol Cell 30: 779–789.
- 39. Raynard S, Bussen W, Sung P (2006) A double Holliday junction dissolvasome comprising BLM, Topoisomerase IIIalpha, and BLAP75. J Biol Chem 281: 13861–13864.
- 40. Bates D, Kleckner N (2005) Chromosome and replisome dynamics in E. coli: loss of sister cohesion triggers global chromosome movement and mediates chromosome segregation. Cell 121: 899–911.
- 41. Pennington JM, Rosenberg SM (2007) Spontaneous DNA breakage in single living Escherichia coli cells. Nat Genet 39: 797–802.
- 42. Fonville NC, Blankschien MD, Magner DB, Rosenberg SM (2010) RecQ-dependent death-by-recombination in cells lacking RecG and UvrD. DNA Repair (in press). doi:10.1016/j.dnarep.2009.12.019.
- 43. Guarino E, Salguero I, Jimenez-Sanchez A, Guzman EC (2007) Double-strand break generation under deoxyribonucleotide starvation in Escherichia coli. J Bacteriol 189: 5782–5786.
- 44. Ip SC, Bregu M, Barre FX, Sherratt DJ (2003) Decatenation of DNA circles by FtsK-dependent Xer site-specific recombination. Embo J 22: 6399–6407.
- 45. Powell SN, Kachnic LA (2008) Therapeutic exploitation of tumor cell defects in homologous recombination. Anticancer Agents Med Chem 8: 448–460.
- 46. Singh DK, Ahn B, Bohr VA (2009) Roles of RECQ helicases in recombination based DNA repair, genomic stability and aging. Biogerontology 10: 235–252.
- 47. Miller J (1972) Generalized transduction; use of P1 in strain construction;. In: Miller J, editor. Cold Spring Harbor, New York: Cold Spring Harbor Laboratory. pp. 201–205.