UV-induced DNA damage disrupts the coordination between replication initiation, elongation and completion

Replication initiation, elongation and completion are tightly coordinated to ensure that all sequences replicate precisely once each generation. UV-induced DNA damage disrupts replication and delays elongation, which may compromise this coordination leading to genome instability and cell death. Here, we profiled the Escherichia coli genome as it recovers from UV irradiation to determine how these replicational processes respond. We show that oriC initiations continue to occur, leading to copy number enrichments in this region. At late times, the combination of new oriC initiations and delayed elongating forks converging in the terminus appear to stress or impair the completion reaction, leading to a transient over-replication in this region of the chromosome. In mutants impaired for restoring elongation, including recA, recF and uvrA, the genome degrades or remains static, suggesting that cell death occurs early after replication is disrupted, leaving partially duplicated genomes. In mutants impaired for completing replication, including recBC, sbcCD xonA and recG, the recovery of elongation and initiation leads to a bottleneck, where the nonterminus region of the genome is amplified and accumulates, indicating that a delayed cell death occurs in these mutants, likely resulting from mis-segregation of unbalanced or unresolved chromosomes when cells divide.

RADX Promotes Genome Stability and Modulates Chemosensitivity by Regulating RAD51 at Replication Forks

RAD51 promotes homology-directed repair (HDR), replication fork reversal, and stalled fork protection. Defects in these functions cause genomic instability and tumorigenesis but also generate hypersensitivity to cancer therapeutics. Here we describe the identification of RADX as an RPA-like, single-strand DNA binding protein. RADX is recruited to replication forks, where it prevents fork collapse by regulating RAD51. When RADX is inactivated, excessive RAD51 activity slows replication elongation and causes double-strand breaks. In cancer cells lacking BRCA2, RADX deletion restores fork protection without restoring HDR. Furthermore, RADX inactivation confers chemotherapy and PARP inhibitor resistance to cancer cells with reduced BRCA2/RAD51 pathway function. By antagonizing RAD51 at forks, RADX allows cells to maintain a high capacity for HDR while ensuring that replication functions of RAD51 are properly regulated. Thus, RADX is essential to achieve the proper balance of RAD51 activity to maintain genome stability.

Predicting the Dynamics and Heterogeneity of Genomic DNA Content within Bacterial Populations across Variable Growth Regimes

For many applications in microbial synthetic biology, optimizing a desired function requires careful tuning of the degree to which various genes are expressed. One challenge for predicting such effects or interpreting typical characterization experiments is that in bacteria such as E. coli, genome copy number varies widely across different phases and rates of growth, which also impacts how and when genes are expressed from different loci. While such phenomena are relatively well-understood at a mechanistic level, our quantitative understanding of such processes is essentially limited to ideal exponential growth. In contrast, common experimental phenomena such as growth on heterogeneous media, metabolic adaptation, and oxygen restriction all cause substantial deviations from ideal exponential growth, particularly as cultures approach the higher densities at which industrial biomanufacturing and even routine screening experiments are conducted. To meet the need for predicting and explaining how gene dosage impacts cellular functions outside of exponential growth, we here report a novel modeling strategy that leverages agent-based simulation and high performance computing to robustly predict the dynamics and heterogeneity of genomic DNA content within bacterial populations across variable growth regimes. We show that by feeding routine experimental data, such as optical density time series, into our heterogeneous multiphasic growth simulator, we can predict genomic DNA distributions over a range of nonexponential growth conditions. This modeling strategy provides an important advance in the ability of synthetic biologists to evaluate the role of genomic DNA content and heterogeneity in affecting the performance of existing or engineered microbial functions.

RecBCD is required to complete chromosomal replication: Implications for double-strand break frequencies and repair mechanisms

Several aspects of the mechanism of homologous double-strand break repair remain unclear. Although intensive efforts have focused on how recombination reactions initiate, far less is known about the molecular events that follow. Based upon biochemical studies, current models propose that RecBCD processes double-strand ends and loads RecA to initiate recombinational repair. However, recent studies have shown that RecBCD plays a critical role in completing replication events on the chromosome through a mechanism that does not involve RecA or recombination. Here, we examine several studies, both early and recent, that suggest RecBCD also operates late in the recombination process - after initiation, strand invasion, and crossover resolution have occurred. Similar to its role in completing replication, we propose a model in which RecBCD is required to resect and resolve the DNA synthesis associated with homologous recombination at the point where the missing sequences on the broken molecule have been restored. We explain how the impaired ability to complete chromosome replication in recBC and recD mutants is likely to account for the loss of viability and genome instability in these mutants, and conclude that spontaneous double-strand breaks and replication fork collapse occur far less frequently than previously speculated.

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.

Interplay of DNA repair, homologous recombination, and DNA polymerases in resistance to the DNA damaging agent 4-nitroquinoline-1-oxide in Escherichia coli

Escherichia coli has three DNA damage-inducible DNA polymerases: DNA polymerase II (Pol II), DNA polymerase IV (Pol IV), and DNA polymerase V (Pol V). While the in vivo function of Pol V is well understood, the precise roles of Pol IV and Pol II in DNA replication and repair are not as clear. Study of these polymerases has largely focused on their participation in the recovery of failed replication forks, translesion DNA synthesis, and origin-independent DNA replication. However, their roles in other repair and recombination pathways in E. coli have not been extensively examined. This study investigated how E. coli's inducible DNA polymerases and various DNA repair and recombination pathways function together to convey resistance to 4-nitroquinoline-1-oxide (NQO), a DNA damaging agent that produces replication blocking DNA base adducts. The data suggest that full resistance to this compound depends upon an intricate interplay among the activities of the inducible DNA polymerases and recombination. The data also suggest new relationships between the different pathways that process recombination intermediates.

RecA433 cells are defective in recF-mediated processing of disrupted replication forks but retain recBCD-mediated functions

RecA is required for recombinational processes and cell survival following UV-induced DNA damage. recA433 is a historically important mutant allele that contains a single amino acid substitution (R243H). This mutation separates the recombination and survival functions of RecA. recA433 mutants remain proficient in recombination as measured by conjugation or transduction, but are hypersensitive to UV-induced DNA damage. The cellular functions carried out by RecA require either recF pathway proteins or recBC pathway proteins to initiate RecA-loading onto the appropriate DNA substrates. In this study, we characterized the ability of recA433 to carry out functions associated with either the recF pathway or recBC pathway. We show that several phenotypic deficiencies exhibited by recA433 mutants are similar to recF mutants but distinct from recBC mutants. In contrast to recBC mutants, recA433 and recF mutants fail to process or resume replication following disruption by UV-induced DNA damage. However, recA433 and recF mutants remain proficient in conjugational recombination and are resistant to formaldehyde-induced protein-DNA crosslinks, functions that are impaired in recBC mutants. The results are consistent with a model in which the recA433 mutation selectively impairs RecA functions associated with the RecF pathway, while retaining the ability to carry out RecBCD pathway-mediated functions. These results are discussed in the context of the recF and recBC pathways and the potential substrates utilized in each case.

RecBCD and RecJ/RecQ Initiate DNA Degradation on Distinct Substrates in UV-Irradiated Escherichia coli

After UV irradiation, recA mutants fail to recover replication, and a dramatic and nearly complete degradation of the genomic DNA occurs. Although the RecBCD helicase/nuclease complex is known to mediate this catastrophic DNA degradation, it is not known how or where this degradation is initiated. Previous studies have speculated that RecBCD targets and initiates degradation from the nascent DNA at replication forks arrested by DNA damage. To test this question, we examined which enzymes were responsible for the degradation of genomic DNA and the nascent DNA in UV-irradiated recA cells. We show here that, although RecBCD degrades the genomic DNA after UV irradiation, it does not target the nascent DNA at arrested replication forks. Instead, we observed that the nascent DNA at arrested replication forks in recA cultures is degraded by RecJ/RecQ, similar to what occurs in wild-type cultures. These findings indicate that the genomic DNA degradation and nascent DNA degradation in UV-irradiated recA mutants are mediated separately through RecBCD and RecJ/RecQ, respectively. In addition, they demonstrate that RecBCD initiates degradation at a site(s) other than the arrested replication fork directly.

Inactivation of the DnaB helicase leads to the collapse and degradation of the replication fork: a comparison to UV-induced arrest

Replication forks face a variety of structurally diverse impediments that can prevent them from completing their task. The mechanism by which cells overcome these hurdles is likely to vary depending on the nature of the obstacle and the strand in which the impediment is encountered. Both UV-induced DNA damage and thermosensitive replication proteins have been used in model systems to inhibit DNA replication and characterize the mechanism by which it recovers. In this study, we examined the molecular events that occur at replication forks following inactivation of a thermosensitive DnaB helicase and found that they are distinct from those that occur following arrest at UV-induced DNA damage. Following UV-induced DNA damage, the integrity of replication forks is maintained and protected from extensive degradation by RecA, RecF, RecO, and RecR until replication can resume. By contrast, inactivation of DnaB results in extensive degradation of the nascent and leading-strand template DNA and a loss of replication fork integrity as monitored by two-dimensional agarose gel analysis. The degradation that occurs following DnaB inactivation partially depends on several genes, including recF, recO, recR, recJ, recG, and xonA. Furthermore, the thermosensitive DnaB allele prevents UV-induced DNA degradation from occurring following arrest even at the permissive temperature, suggesting a role for DnaB prior to loading of the RecFOR proteins. We discuss these observations in relation to potential models for both UV-induced and DnaB(Ts)-mediated replication inhibition.

Nascent DNA processing by RecJ favors lesion repair over translesion synthesis at arrested replication forks in Escherichia coli

DNA lesions that arrest replication can lead to rearrangements, mutations, or lethality when not processed accurately. After UV-induced DNA damage in Escherichia coli, RecA and several recF pathway proteins are thought to process arrested replication forks and ensure that replication resumes accurately. Here, we show that the RecJ nuclease and RecQ helicase, which partially degrade the nascent DNA at blocked replication forks, are required for the rapid recovery of DNA synthesis and prevent the potentially mutagenic bypass of UV lesions. In the absence of RecJ, or to a lesser extent RecQ, the recovery of replication is significantly delayed, and both the recovery and cell survival become dependent on translesion synthesis by polymerase V. The RecJ-mediated processing is proposed to restore the region containing the lesion to a form that allows repair enzymes to remove the blocking lesion and DNA synthesis to resume. In the absence of nascent DNA processing, polymerase V can synthesize past the lesion to prevent lethality, although this occurs with slower kinetics and a higher frequency of mutagenesis.

Nucleotide excision repair or polymerase V-mediated lesion bypass can act to restore UV-arrested replication forks in Escherichia coli

Nucleotide excision repair and translesion DNA synthesis are two processes that operate at arrested replication forks to reduce the frequency of recombination and promote cell survival following UV-induced DNA damage. While nucleotide excision repair is generally considered to be error free, translesion synthesis can result in mutations, making it important to identify the order and conditions that determine when each process is recruited to the arrested fork. We show here that at early times following UV irradiation, the recovery of DNA synthesis occurs through nucleotide excision repair of the lesion. In the absence of repair or when the repair capacity of the cell has been exceeded, translesion synthesis by polymerase V (Pol V) allows DNA synthesis to resume and is required to protect the arrested replication fork from degradation. Pol II and Pol IV do not contribute detectably to survival, mutagenesis, or restoration of DNA synthesis, suggesting that, in vivo, these polymerases are not functionally redundant with Pol V at UV-induced lesions. We discuss a model in which cells first use DNA repair to process replication-arresting UV lesions before resorting to mutagenic pathways such as translesion DNA synthesis to bypass these impediments to replication progression.

Links between DNA replication and recombination in prokaryotes

Recombination plays a crucial role in underpinning genome duplication, ensuring that replication blocks are removed or bypassed, and that the replication machinery is subsequently reloaded back onto the DNA. Recent studies have identified a surprising variety of ways in which damaged replication forks are repaired and have shown that the mechanism used depends on the nature of the original blocking lesion. Indeed, an emerging theme is that a single recombination enzyme or complex can perform highly varied tasks, depending on the context of the recombination reaction.

When replication travels on damaged templates: bumps and blocks in the road

Escherichia coli can accurately replicate their genome even when it contains hundreds of damaged bases. In this situation, processes such as DNA repair, translesion DNA synthesis, and recombination all contribute to the cell's ability to successfully complete this task. However, under conditions when these reactions go awry, these same processes can result in cell lethality, mutagenesis, or genetic instability. In order to understand the molecular events that can lead this normally faithful duplication of the genome to become less than perfect, it is essential to define the substrates and conditions when each of these processes are recruited to the replication fork.

RecO Acts with RecF and RecR to Protect and Maintain Replication Forks Blocked by UV-induced DNA Damage in Escherichia coli

In Escherichia coli, recF and recR are required to stabilize and maintain replication forks arrested by UV-induced DNA damage. In the absence of RecF, replication fails to recover, and the nascent lagging strand of the arrested replication fork is extensively degraded by the RecQ helicase and RecJ nuclease. recO mutants are epistatic with recF and recR with respect to recombination and survival assays after DNA damage. In this study, we show that RecO functions with RecF and RecR to protect the nascent lagging strand of arrested replication forks after UV-irradiation. In the absence of RecO, the nascent DNA at arrested replication forks is extensively degraded and replication fails to recover. The extent of nascent DNA degradation is equivalent in single, double, or triple mutants of recF, recO, or recR, and the degradation is dependent upon RecJ and RecQ functions. Because RecF has been shown to protect the nascent lagging strand from degradation, these observations indicate that RecR and RecO function with RecF to protect the same nascent strand of the arrested replication fork and are likely to act at a common point during the recovery process. We discuss these results in relation to the biochemical and cellular properties of RecF, RecO, and RecR and their potential role in loading RecA filaments to maintain the replication fork structure after the arrest of replication by UV-induced DNA damage.

RecA-Dependent Recovery of Arrested DNA Replication Forks

DNA damage encountered during the cellular process of chromosomal replication can disrupt the replication machinery and result in mutagenesis or lethality. The RecA protein of Escherichia coli is essential for survival in this situation: It maintains the integrity of the arrested replication fork and signals the upregulation of over 40 gene products, of which most are required to restore the genomic template and to facilitate the resumption of processive replication. Although RecA was originally discovered as a gene product that was required to change the genetic information during sexual cell cycles, over three decades of research have revealed that it is also the key enzyme required to maintain the genetic information when DNA damage is encountered during replication in asexual cell cycles. In this review, we examine the significant experimental approaches that have led to our current understanding of the RecA-mediated processes that restore replication following encounters with DNA damage.

DNA damage-induced replication fork regression and processing in Escherichia coli

DNA lesions that block replication are a primary cause of rearrangements, mutations, and lethality in all cells. After ultraviolet (UV)-induced DNA damage in Escherichia coli, replication recovery requires RecA and several other recF pathway proteins. To characterize the mechanism by which lesion-blocked replication forks recover, we used two-dimensional agarose gel electrophoresis to show that replication-blocking DNA lesions induce a transient reversal of the replication fork in vivo. The reversed replication fork intermediate is stabilized by RecA and RecF and is degraded by the RecQ-RecJ helicase-nuclease when these proteins are absent. We propose that fork regression allows repair enzymes to gain access to the replication-blocking lesion, allowing processive replication to resume once the blocking lesion is removed.

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.

Participation of recombination proteins in rescue of arrested replication forks in UV-irradiated Escherichia coli need not involve recombination

Alternative reproductive cycles make use of different strategies to generate different reproductive products. In Escherichia coli, recA and several other rec genes are required for the generation of recombinant genomes during Hfr conjugation. During normal asexual reproduction, many of these same genes are needed to generate clonal products from UV-irradiated cells. However, unlike conjugation, this latter process also requires the function of the nucleotide excision repair genes. Following UV irradiation, the recovery of DNA replication requires uvrA and uvrC, as well as recA, recF, and recR. The rec genes appear to be required to protect and maintain replication forks that are arrested at DNA lesions, based on the extensive degradation of the nascent DNA that occurs in their absence. The products of the recJ and recQ genes process the blocked replication forks before the resumption of replication and may affect the fidelity of the recovery process. We discuss a model in which several rec gene products process replication forks arrested by DNA damage to facilitate the repair of the blocking DNA lesions by nucleotide excision repair, thereby allowing processive replication to resume with no need for strand exchanges or recombination. The poor survival of cellular populations that depend on recombinational pathways (compared with that in their excision repair proficient counterparts) suggests that at least some of the rec genes may be designed to function together with nucleotide excision repair in a common and predominant pathway by which cells faithfully recover replication and survive following UV-induced DNA damage.

Single-strand interruptions in replicating chromosomes cause double-strand breaks

Replication-dependent chromosomal breakage suggests that replication forks occasionally run into nicks in template DNA and collapse, generating double-strand ends. To model replication fork collapse in vivo, I constructed phage lambda chromosomes carrying the nicking site of M13 bacteriophage and infected with these substrates Escherichia coli cells, producing M13 nicking enzyme. I detected double-strand breaks at the nicking sites in lambda DNA purified from these cells. The double-strand breakage depends on (i) the presence of the nicking site; (ii) the production of the nicking enzyme; and (iii) replication of the nick-containing chromosome. Replication fork collapse at nicks in template DNA explains diverse phenomena, including eukaryotic cell killing by DNA topoisomerase inhibitors and inviability of recombination-deficient vertebrate cell lines.

Therefore, what are recombination proteins there for?

The order of discovery can have a profound effect upon the way in which we think about the function of a gene. In E. coli, recA is nearly essential for cell survival in the presence of DNA damage. However, recA was originally identified, as a gene required to obtain recombinant DNA molecules in conjugating bacteria. As a result, it has been frequently assumed that recA promotes the survival of bacteria containing DNA damage by recombination in which DNA strand exchanges occur. We now know that several of the processes that interact with or are controlled by recA, such as excision repair and translesion synthesis, operate to ensure that DNA replication occurs processively without strand exchanges. Yet the view persists in the literature that recA functions primarily to promote recombination during DNA repair. With the benefit of hindsight and more than three decades of additional research, we reexamine some of the classical experiments that established the concept of DNA repair by recombination, and we consider the possibilities that recombination is not an efficient mechanism for rescuing damaged cells, and that recA may be important for maintaining processive replication in a manner that does not generally promote recombination.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

Recovery of DNA replication in UV-irradiated Escherichia coli requires both excision repair and recF protein function

After UV doses that disrupt DNA replication, the recovery of replication at replication forks in Escherichia coli requires a functional copy of the recF gene. In recF mutants, replication fails to recover and extensive degradation of the nascent DNA occurs, suggesting that recF function is needed to stabilize the disrupted replication forks and facilitate the process of recovery. We show here that the ability of recF to promote the recovery of replication requires that the disrupting lesions be removed. In the absence of excision repair, recF+ cells protect the nascent DNA at replication forks, but replication does not resume. The classical view is that recombination proteins operate in pathways that are independent from DNA repair, and therefore the functions of Rec proteins have been studied in repair-deficient cells. However, mutations in either uvr or recF result in failure to recover replication at UV doses from which wild-type cells recover efficiently, suggesting that recF and excision repair contribute to a common pathway in the recovery of replication.

Correlation between survival, ability to rejoin DNA and stability of DNA after preirradiation inhibition of protein synthesis in a rec mutant of Escherichia coli K12

A 90 min inhibition of protein synthesis induced by starvation for amino acids (AA-) or by treatment with chloramphenicol (CAP) prior to UV irradiation (2.5 Jm-2) increased the resistance of the strain Escherichia coli K12 SR19 to UV radiation more than ten-fold. Under these conditions, cultures in which protein synthesis was inhibited before the UV irradiation rejoin short regions of DNA synthesized after the irradiation to a normal-size molecule, whereas an exponentially growing culture does not rejoin DNA synthesized after UV irradiation to a molecule of a normal size. In the exponentially growing culture both the parental and the newly synthesized DNA are unstable after the irradiation. In cultures with inhibited protein synthesis only the parental DNA is somewhat unstable. In Escherichia coli K12 SR19 where protein synthesis was inhibited before the irradiation, a correlation between the survival of cells, the ability to rejoin short regions of DNA synthesized after UV irradiation and a higher stability of both parental and newly synthesized DNAs could be demonstrated.

Division delay and DNA degradation after mutagen treatment of the yeast, Saccharomyces cerevisiae

The treatment of the yeast mutant TMP1-1, which is capable of incorporating low levels of 3H-thymidine-5' - monophosphate with UV light and ethyl methane sulphonate resulted in division delay when cultures were reinnoculated into fresh medium. The initiation of cell division was accompanied by the degradation of up to 20% of the nuclear DNA fraction. The period of DNA degradation correlates closely with the time at which yeast cultures undergo mitotic recombination and appears to represent the degradation of DNA during a post-replication repair process.

DNA degradation in minicells of Escherichia coli K-12. II. Effect of recA1 and recB21 mutations on DNA degradation in minicells and detection of exonuclease V activity

The properties of minicell producing mutants of Escherichia coli deficient in gentic recombination were examined. Experiments were designed to test recombinant formation in conjugal crosses, survival following UV-irradiation in cells, and the state of DNA metabolism in minicells. The REC- phenotypes are unaffected by min+/- genotypes in whole cells. In contrast to minicells produced by rec+ parental cells, minicells from a recB21 strain have limited capacity to degrade linear, Hfr transfereed DNA. The lack of a functional recA gene product, presumably involved in inhibiting the recBC nuclease action(s), permits unrestricted Hfr DNA breakdown in minicells produced by a recA1 strain. This results in an increase in TCA soluble products and in the formation of small DNA molecules that sediment near the top of an alkaline sucrose gradient. Unlike the linear DNA, circular duplex DNA from plasmids R 64-11 or lambdadv, segregated into the minicells, is resistant to breakdown. By using in vitro criteria, and [32P]-labelled linear DNA from bacteriophage T7 for substrate, we found that the ATP-dependent exonuclease of the recBC complex (exo V) is present in rec+ and recA- minicells, and is lacking in the recB21 mutant. In fact, the absence of a functional exo V in recBC- minicells results in isolation of larger than average Hfr DNA from minicells. We suggest that recombination (REC) enzymes segregate into the polar minicells at the time of minicell biogenesis. This system should be useful for studies on DNA metabolism and functions of the recBC and recA gene products.

Temperature-sensitive recovery of a mutant of Escherichia coli K-12 irradiated with ultraviolet light

URT-43 is a mutant of Escherichia coli K-12 which gives a much larger number of survivors when ultraviolet (UV)-irradiated bacteria are incubated on agar medium at 30 C than when they are incubated on the medium at 41 C, although in both cases the number of survivors is fewer than that given by its wild-type ancestor. The UV sensitivity of this mutant was found to be markedly influenced by the presence of a high concentration of NaCl or sucrose in the plating medium. Thus, when irradiated bacteria were plated on agar medium containing 2% NaCl or 0.5 m sucrose at 30 C, they exhibited a resistance similar to that of their wild-type ancestor. At 30 C, there was also an extensive recovery in liquid M9 medium supplemented with all of the nutrients required for growth and NaCl or sucrose. At 41 C, however, the recovery was greatly inhibited. Direct chemical analysis of thymine dimers has revealed that no significant amount of the dimer was released from deoxyribonucleic acid during the period of extensive recovery. It was concluded, therefore, that the temperature-sensitive recovery of URT-43 does not accompany excision of the bulk of pyrimidine dimers. To learn the gene function involved in the recovery, double mutants carrying an additional mutation either in a uvr or a rec gene have been investigated for their UV sensitivities and recovery in liquid medium. It was found that recA(-) and recB(-) derivatives retain the ability of undergoing an efficient recovery at a low temperature, whereas uvrB(-) and uvrC(-) derivatives have completely lost this ability. For these reasons, it was concluded that the mechanism responsible for the recovery of URT-43 involves the function controlled by the uvr genes. The results of photoreactivation suggested that most of the entities dealt with during recovery were pyrimidine dimers.

Relationship between radiation response and the deoxyribonucleic acid replication cycle in bacteria: dependence on the excision-repair system

Prestarvation of Escherichia coli for required amino acids results in a marked enhancement in both ultraviolet light (UV) or X-ray resistance for selective strains. Preventing protein synthesis by starvation for required amino acids results in completion of the cycle of chromosomal replication then underway. We have investigated the relationship between starvation-induced resistance enhancement (SIRE) and the excision-repair (Hcr) system in several E. coli strains including E. coli B/r hcr(+) and its isogenic mutant E. coli B/r hcr(-). The following observations were made. (i) The Hcr system is the major component of SIRE in UV-irradiated strain B/r. By using the Hcr(+) strain, SIRE increases the 10% survival dose from approximately 400 ergs to approximately 1,200 ergs/mm(2). With the Hcr cells, the increase is from approximately 45 ergs to 60 ergs/mm(2). (ii) Although prestarvation leads to a moderate enhancement of resistance to X irradiation, this effect is not dependent on the Hcr system. (iii) The double mutant, E. coli B(s-1) (hcr(-)exr(-)) is completely unable to express SIRE whether studied with UV or X irradiation. It is concluded that the Hcr system is the major system responsible for SIRE in UV-treated cells, whereas Exr (resistance to X rays) may be involved to a minor extent. The Exr character appears to be required for SIRE expression in X-ray exposed cells.