Conditional Lethality of recA and recB Derivatives of a Strain of Escherichia coli K-12 with a Temperature-Sensitive Deoxyribonucleic Acid Polymerase I

We have isolated a strain of Escherichia coli K-12 carrying a mutation, polA12, that results in the synthesis of a temperature-sensitive deoxyribonucleic acid (DNA) polymerase I. The double mutants polA12 recA56 and polA12 recB21, constructed at 30 C, are inviable at 42 C. About 90% of the cells of both double mutants die after 2 hr of incubation at 42 C. Both double mutants filament at 42 C and show a dependence on high cell density for growth at 30 C. In polA12 recB21 cells at 42 C, DNA and protein synthesis gradually stop in parallel. In polA12 recA56 cells, DNA synthesis continues for at least 1 hr at 42 C, and there is extensive DNA degradation. The results suggest that the primary lesion in these double mutants is not in DNA replication per se.     

Role of DNA polymerase I in postreplication repair: a reexamination with Escherichia coli delta polA.

Using strains of Escherichia coli K-12 that are deleted for the polA gene, we have reexamined the role of DNA polymerase I (encoded by polA) in postreplication repair after UV irradiation. The polA deletion (in contrast to the polA1 mutation) made uvrA cells very sensitive to UV radiation; the UV radiation sensitivity of a uvrA delta polA strain was about the same as that of a uvrA recF strain, a strain known to be grossly deficient in postreplication repair. The delta polA mutation interacted synergistically with a recF mutation in UV radiation sensitization, suggesting that the polA gene functions in pathways of postreplication repair that are largely independent of the recF gene. When compared to a uvrA strain, a uvrA delta polA strain was deficient in the repair of DNA daughter strand gaps, but not as deficient as a uvrA recF strain. Introduction of the delta polA mutation into uvrA recF cells made them deficient in the repair of DNA double-strand breaks after UV irradiation. The UV radiation sensitivity of a uvrA polA546(Ts) strain (defective in the 5'----3' exonuclease of DNA polymerase I) determined at the restrictive temperature was very close to that of a uvrA delta polA strain. These results suggest a major role for the 5'----3' exonuclease activity of DNA polymerase I in postreplication repair, in the repair of both DNA daughter strand gaps and double-strand breaks.     

Deoxyribonucleic acid repair in vitro by extracts of Escherichia coli.

Deoxyribonucleic acid (DNA) from bacteriophage T7 has been used to monitor the capacity of gently lysed extracts of Escherichia coli to perform repair resynthesis after ultraviolet (UV) irradiation. Purified DNA damaged by up to 100 J of UV radiation per m2 was treated with an endonuclease from Micrococcus luteus that introduces single-strand breaks in irradiated DNA. This DNA was then used as a substrate to study repair resynthesis by extracts of E. coli. It was found that incubation with the extract and exogenous nucleoside triphosphates under suitable assay conditions resulted in removal of all pyrimidine dimers and restoration of the substrate DNA to its original molecular weight. Repair resynthesis, detected as nonconservative, UV-stimulated DNA synthesis, was directly proportional tothe number of pyrimidine dimers introduced by radiation. The repair mode described here appears to require DNA polymerase I since it does no occur at the restrictive temperature in polA12 mutants, which contain a thermolabile polymerase. The addition of purified DNA polymerase I to extracts made from a polA mutant restores the ability to complete repair at the restrictive temperature.     

Temperature-Sensitive Mutants for the Replication of Plasmids in Escherichia coli: Requirement for Deoxyribonucleic Acid Polymerase I in the Replication of the Plasmid ColE1

An Escherichia coli mutant (polA1), defective in deoxyribonucleic acid (DNA) polymerase I, (EC 2.7.7.7) is unable to maintain colicinogenic factor E1 (ColE1), whereas several sex factor plasmids are maintained normally in this strain. polA1 mutant strains containing these sex factor plasmids do not exhibit a readily detectable plasmid-induced polymerase activity. A series of E. coli mutants that are temperature sensitive for ColE1 maintenance, but able to maintain other plasmids, were isolated and shown to fall into two phenotypic groups. Mutants in one group are defective specifically in ColE1 maintenance at 43 C, but exhibit normal DNA polymerase I activity. Mutations in the second group map in the polA gene of E. coli, and bacteria carrying these mutations are sensitive to methylmethanesulfonate (MMS). Revertants that were selected either for MMS resistance or the ability to maintain ColE1 were normal for both properties. The DNA polymerase I enzyme of two of these mutants shows a pronounced temperature sensitivity when compared to the wild-type enzyme. An examination of the role of DNA polymerase I in ColE1 maintenance indicates that it is essential for normal replication of the plasmid. In addition, the presence of a functional DNA polymerase I in both the donor and recipient cell is required for the ColV-promoted conjugal transfer of ColE1 and establishment of the plasmid in the recipient cell.     

Unlinking of Cell Division from Deoxyribonucleic Acid Replication in a Temperature-sensitive Deoxyribonucleic Acid Synthesis Mutant of Escherichia coli

A new type of temperature-sensitive deoxyribonucleic acid (DNA) synthesis mutant, which can divide without a completion of DNA replication, was isolated from a thymidine-requiring Escherichia coli strain by means of photo-bromouracil selection after nitrosoguanidine mutagenesis. In this mutant, in spite of the fact that DNA synthesis stopped immediately after the temperature shift from 30 to 41 C, cells could continue to divide, though at a reduced rate. This cell division without DNA synthesis at 41 C is further supported by the following results. (i) Cell division took place at high temperature without addition of thymidine but not at all at 30 C. The parent strain of the mutant did not divide at 41 C without thymidine. (ii) Smaller cells isolated from the culture grown at 41 C did not contain DNA. This was shown by chemical analysis of the smaller cells and on electron micrographs. Ability of cells to divide was examined according to sizes of cells. By using the culture at 30 C, cells of various sizes were separated by means of sucrose-density gradient centrifugation. It was found that all cell fractions, including the smallest one, could divide at high temperature. These results suggest that in this mutant the completion of DNA replication is not required for triggering cell division at high temperature. Heat sensitivity of a factor which links cell division with DNA replication appears to be responsible. Some possible mechanisms of the coordination between cell division and DNA replication are discussed.     

Toxicity of organic acids for repair-deficient strains of Escherichia coli

The wild-type strain and four DNA repair-deficient strains (uvrA6, uvrB5, recA56, and polA1) of Escherichia coli K-12 were treated with acetic acid, lactic acid, and p-aminobenzoic acid at pH 3.5 during their stationary phase of growth. All three acids were highly toxic to the polymerase-deficient strain. The greater sensitivity of the strain carrying the polA1 gene than its isogenic pol+ derivatives suggested that damage caused by acidity requires polA+ gene products for repair.     

Toxicity of organic acids for repair-deficient strains of Escherichia coli.

The wild-type strain and four DNA repair-deficient strains (uvrA6, uvrB5, recA56, and polA1) of Escherichia coli K-12 were treated with acetic acid, lactic acid, and p-aminobenzoic acid at pH 3.5 during their stationary phase of growth. All three acids were highly toxic to the polymerase-deficient strain. The greater sensitivity of the strain carrying the polA1 gene than its isogenic pol+ derivatives suggested that damage caused by acidity requires polA+ gene products for repair.     

uvrC Gene Function in Excision Repair in Toluene-Treated Escherichia coli

We have examined the role of the uvrC gene in UV excision repair by studying incision, excision, repair synthesis, and DNA strand reformation in Escherichia coli mutants made permeable to nucleoside triphosphates by toluene treatment. After irradiation, incisions occur normally in uvrC cells in the presence of nicotinamide mononucleotide (NMN), a ligase-blocking agent, but cannot be detected otherwise. We conclude that repair incisions are followed by a ligation event in uvrC mutants, masking incision. However, a uvrC polA12 mutant accumulates incisions only slightly less efficiently than a polA12 strain without NMN. Excision of pyrimidine dimers is defective in uvrC mutants (polA(+) or polA12) irrespective of the presence or absence of NMN. DNA polymerase I-dependent, NMN-stimulated repair synthesis, which is demonstrable in wild-type cells, is absent in uvrC polA(+) cells, but the uvrC polA12 mutant exhibits a UV-specific, ATP-dependent repair synthesis like parental polA12 strains. A DNA polymerase I-mediated reformation of high-molecular-weight DNA takes place efficiently in uvrC polA(+) mutants after incision accumulation, and the uvrC polA12 mutant shows more reformation than the polA12 strain after incision. These results indicate that normal incision occurs in uvrC mutants, but there appears to be a defect in the excision of pyrimidine dimers, allowing resealing via ligation at the site of the incision. The lack of NMN-stimulated repair synthesis in uvrC polA(+) cells indicates that incision is not the only requirement for repair synthesis.     

Conditional Lethality of Deletions Which Include uvrB in Strains of Escherichia coli Lacking Deoxyribonucleic Acid Polymerase I

Deletions of the uvrB gene were not obtained in polA1 strains of Escherichia coli either by selecting for spontaneous deletions or by transduction from strains carrying such deletions. A strain forming a temperature-sensitive deoxyribonucleic acid polymerase I and carrying a deletion of the uvrB gene is inviable at the nonpermissive temperature.     

Loss and restoration of viability of E. coli due to combinations of mutations affecting DNA polymerase I and repair activities

Summary We have found that the cells possessing the polA6 mutation affecting DNA polymerase I are unable to accept another mutation (uvr502) leading to UV-sensitivity. The introduction of the polA12 mutation determining the synthesis of a temperature sensitive DNA polymerase I into the uvr502 mutant results in the temperature sensitivity of colony forming ability of the double mutant. These data show that the uvr502 derivatives lacking DNA polymerase I are inviable. Reversions to temperature resistance in the population of the double mutant uvr502 polA12 may occur because of reverse mutations at one of the mutated sites or because of mutations suppressing DNA polymerase I deficiency but not UV- or MMS-sensitivity of revertants. DNA and protein synthesis in uvr502 polA12 cells continues after a shift to 45°C with rates almost indistinguishable from those in single mutants or wild type cells. No differences in DNA degradation were observed during incubation of single and double mutants at 45°C. The single strand molecular weight distribution of parent DNA from the double mutant as well as that from wild type cells is not affected by the shift to 45°C and 3 hours incubation at this temperature. We suggest that DNA polymerase I and/or the product altered by the uvr502 mutation are required for some step(s) of discontinuous DNA replication nonessential for the formation of acid insoluble DNA. The DNA polymerase I and the uvr gene product seem to be able to substitute for each other in accomplishing this process.     

A new in vivo termination function for DNA polymerase I of Escherichia coli K12

Escherichia coli deleted for the tus gene are viable. Thus there must be at least one other mechanism for terminating chromosome synthesis. The tus deletion strain yielded a small fraction of cells that overproduce DNA, as determined by flow cytometry after run-out chromosome replication in the presence of rifampicin and cephalexin. A plasmid, paraBAD tus+, prevented the excess DNA replication only when arabinose was added to the medium to induce the synthesis of the Tus protein. Transduction studies were done to test whether or not additional chromosomal deletions could enhance the excess chromosome replication in the tus deletion strain. A strain containing a second deletion in metE udp overproduced DNA at a high level during run-out replication. Further studies demonstrated that a spontaneous unknown mutation had occurred during the transduction. This mutation was mapped and sequenced. It is polA(G544D). Transduction of polA(G544D) alone into the tus deletion strain produced the high DNA overproduction phenotype. The polA(G544D) and six other polA alleles were then tested in wild-type and in tus deletion backgrounds. The two alleles with low levels of 5'-->3' exonuclease (exo) overproduced DNA while those with either high or normal exo overproduce much less DNA in run-out assays in the wild-type background. In contrast, all seven mutant polA alleles caused the high DNA overproduction phenotype in a tus deletion background. To explain these results we propose a new in vivo function for wild-type DNA polymerase I in chromosome termination at site(s) not yet identified.     

Replication of plasmid chimera pBR-mtB-A containing rat liver mtDNA fragment in Escherichia coli polA cells

Escherichia coli K-12 strains p108 (polA6), p3478 (polA1), and KS55 (polA12, ts) deficient in DNA polymerase I were transformed by recombinant pBR-mtB-A plasmid containing BamHI-A fragment of rat liver mtDNA and pBR322 plasmid. The physical map of the pBR-mtB-A, containing the recognition sites for SalI, EcoRI and HinIII endonucleases, was constructed and the orientation of mtDNA fragment joined to pBR322 plasmid was studied. The phenotypic selection using ampicillin containing medium at permissive and nonpermissive temperature (KS55 strain), or at 37 °C (polA6 and polA1 strains) revealed that only the cells transformed with the hybrid plasmid are able to grow under these conditions. The presence of mtDNA insertions in chimeric DNA molecules of pBR-mtB-A in polA strains was proved by electrophoretic and hybridization analysis. Thus the results obtained demonstrate the replication of the vehicle containing both plasmid replicon and mitochondrial origin in the conditions nonpermissive for the stable reproduction of the plasmid DNA alone.     

Characterization of a Temperature-sensitive Mutant of Bacillus subtilis Defective in Deoxyribonucleic Acid Replication

In this paper we present a preliminary characterization of a temperature-sensitive mutant of Bacillus subtilis which appears to be defective in deoxyribonucleic acid (DNA) replication at high temperature. When log-phase cells of the mutant were transferred from 30 to 45 C, protein synthesis and ribonucleic acid synthesis continued more or less normally for several hours, whereas DNA synthesis continued at a normal rate for only 20 to 30 min and then was drastically reduced. The amount of DNA synthesized prior to this reduction corresponded approximately to the amount of DNA synthesized under conditions of protein synthesis inhibition by the parent or mutant strain. After 1 hr of growth at high temperature, cells of the mutant showed a pronounced drop in viable count. After 30 or 60 min of growth at high temperature, DNA synthesis could be restored by lowering the temperature. A longer period of growth at 45 C led to a loss of reversibility of DNA synthesis. Spores of the mutant synthesized no DNA when germinated at high temperature, although an outgrowing cell appeared. When spores were germinated at low temperature until DNA synthesis began, and then were transferred to high temperature, macromolecular synthesis continued as the log-phase transfer experiments described above.     

Induction of an abortive and futile DNA repair process in E. coli by the antitumor DNA bifunctional intercalator, ditercalinium: role in polA in death induction.

Ditercalinium, an antitumor bifunctional intercalator which forms a high affinity reversible complex with DNA, was found to be specifically cytotoxic for polA and lig7 E. coli strains. In the polA strain, the cytotoxic effect of ditercalinium was suppressed by the uvrA mutation. DNA single strand breaks accumulated in presence of ditercalinium at high temperature in lig7 strains but not in polA strains. Ditercalinium caused no DNA synthesis inhibition although it was able to induce SOS functions. It is proposed that the ditercalinium DNA complex because of its non covalent nature acts as a dummy lesion for the UV repair system in E. coli leading to a futile and abortive repair process. Polymerase I appears to be required to prevent the malfunctioning of a DNA repair process triggered by molecules forming non covalent complex with DNA.     

Time Scale for Rejoining of Bacteriophage λ Deoxyribonucleic Acid Molecules in Superinfected pol+ and polA1 Strains of Escherichia coli After Exposure to 4 MeV Electrons

The time scale for rejoining of radiation-induced deoxyribonucleic acid (DNA) single-strand breaks was measured in the presence and absence of oxygen. The involvement of DNA polymerase I in this repair process was studied. Formation and rejoining of DNA strand breaks were measured in lambda DNA infecting lysogenic pol(+) and polA1 strains of Escherichia coli irradiated by 4 MeV electrons under identical conditions. Irradiation and transfer to alkaline detergent could be completed in less than 180 ms. The initial yields of DNA strand breaks were identical in pol(+) and polA1 host cells and four- to fivefold higher in the presence of oxygen than in nitrogen anoxia. Evidence for the existence of a very fast repair process, independent of DNA polymerase I, was not found, since no rejoining of radiation-induced DNA strand breaks was observed during incubation from 45 ms to 3 s. In pol(+) host cells most of the strand breaks produced in the presence of oxygen were rejoined within the first 30 to 40 s of incubation, whereas no rejoining could be detected within the same period of time in anoxic cells. Since no rejoining of broken lambda DNA molecules was observed in polA1 host cells, it is concluded that the synthetase activity of DNA polymerase I is involved in the rejoining of DNA breaks induced by radiation in the presence of oxygen.     

Effect of Poxvirus Infection on Host Cell Deoxyribonucleic Acid Synthesis

Deoxyribonucleic acid (DNA) synthesis was studied in poxvirus-infected cells by measuring (14)C-thymidine incorporation into viral and host cell DNA. A complete separation of the two species of DNA was achieved by combining the previously used "Dounce method" with a separation method based on different reannealing properties of viral and vertebrate DNA. Shortly after infection of HeLa cells with poxviruses, a burst of viral DNA synthesis occurred in the cytoplasm, but a rapid inhibition of host-cell DNA synthesis in the nucleus was observed. This inhibition of cellular DNA synthesis was also found if an accumulation of viral DNA was prevented. At high multiplicites, ultraviolet-irradiated virus inhibited host-cell DNA synthesis to the same extent as fully infectious poxvirus. Under the same conditions, heating at 60 C for 15 min caused a decrease in the ability of cowpox virus to inhibit host-cell DNA synthesis, but did not produce the same effect on vaccinia virus strain WR.     

Anaerobic incubation enhances the colony formation of a polA recB strain of Escherichia coli K-12.

Escherichia coli strain E247 (polA1 recB21) has reduced colony formation (even at the permissive temperature of 30 degrees C) because of a poor suppressor mutation (sup-126). The colony formation was enhanced in the absence of oxygen about 3-fold at 30 degrees C and 10(6)-fold at 43 degrees C, suggesting that a polA recB strain was inviable due to oxygen toxicity. Colony formation was also increased by incubation in an agar medium containing the reducing agent thioglycolate and incubation in the presence of chloroform-killed Saccharomyces cerevisiae pet+ cells, but not pet cells. Since the E247 strain viability was inversely dependent on the oxygen pressure and since the strain was more sensitive to superoxide radical than either the polA or the recB mutant, it seems likely that the polA and recB genes play a role in repairing DNA damage during respiration.     

Host Cell Deoxyribonucleic Acid Polymerase I and the Support of T4 Bacteriophage Growth

Ultraviolet irradiation of Escherichia coli polA(-) cells reduces their capacity to support the growth of T4 phage. There is no additional loss of capacity observed in pol tsA(-)recA(-) double mutants at the nonpermissive temperature. The reversion frequency of a T4 rII mutant after ultraviolet irradiation is not changed by the absence of host deoxyribonucleic acid polymerase I.     

Replication of Deoxyribonucleic Acid in Escherichia coli C Mutants Temperature Sensitive in the Initiation of Chromosome Replication

An Escherichia coli HF4704S mutant temperature sensitive in deoxyribonucleic acid (DNA) synthesis and different from any previously characterized mutant was isolated. The mutated gene in this strain was designated dnaH. The mutant could grow normally at 27 C but not at 43 C, and DNA synthesis continued for an hour at a decreasing rate and then ceased. After temperature shift-up, the increased amount of DNA was 40 to 50%. When the culture was incubated at 43 C for 70 min and then transferred to 27 C, DNA synthesis resumed after about 50 min, initiating synchronously at a fixed region on the bacterial chromosome. The initiation step in DNA replication sensitive to 30 mug of chloramphenicol per ml occurs synchronously before the resumption of DNA replication after the temperature shift-down, being completed about 30 min before the start of DNA replication. When the cells incubated at 27 C in the presence of 30 mug of chloramphenicol per ml after the temperature shift-down to 27 C were transferred to 43 C with simultaneous removal of the antibiotic, no resumption of DNA replication was observed. When the culture was returned to 43 C after being released from high-temperature inhibition at 30 min before the start of DNA replication, no recovery replication was observed; whereas at 20 min, the recovery of replication was observed. These results indicated that HF4704S was temperature sensitive in the initiation of DNA replication. Analysis of HF4704S, by an interrupted conjugation experiment, indicated that gene dnaH was located at about 64 min on the E. coli C linkage map. In E. coli S1814 (a K-12 derivative), which was a dnaH(ts) transductant from HF4704S (C strain) with phage P1, the mutated gene (dnaH) was demonstrated to be closely linked to the thyA marker by conjugation and P1 transduction experiments and to be distinct from genes dnaA through dnaG.     

Frameshift mutagenesis by nitracrine analogues in wild-type, uvrB, polA and recA strains of Salmonella typhimurium, with and without plasmid pKM101

The mutagenic potential of 9-[(3-dimethylaminopropyl)amino]-acridine and its 1-, 2-, 3- and 4-nitro derivatives was studied in several strains of Salmonella typhimurium carrying the frameshift marker hisC3076. The strains all carried deep rough (rfa) mutations, and were either wild-type with respect to DNA repair capacity or carried recA, uvrB, polA1 or polA3 (amber) mutations. Derivatives with and without plasmid pKM101 were also studied. The des-nitro compound resembled 9 aminoacridine and other simple intercalating compounds. Both toxicity and mutagenesis were apparently unaffected by the uvrB and recA mutations or by the presence of plasmid pKM101. However, mutagenicity was reduced by the polA1 mutation, and virtually eliminated by the polA3 mutation. The drug was substantially more toxic in the latter, slightly more toxic in the former, of these polA- strains. Plasmid pKM101 enhanced mutagenesis and protected from toxicity in both polA1- and polA3- strains, although it did not restore either of these parameters to the level in the wild-type strain. The 2-nitro compound was generally similar to the des-nitro compound, except that it was considerably more toxic and apparently non-mutagenic in the recA-bearing strain. By contrast, mutagenicity of the 3- and 4-nitro compounds was enhanced by the uvrB mutation and by the presence of the plasmid. These compounds were highly toxic but non-mutagenic in the recA- strain, and showed some increased toxicity in polA1- and polA3- strains. The 1-nitro compound has been previously found to cross-link DNA. Unlike well-characterised cross-linkers such as mitomycin C it was highly mutagenic in the uvrB- strain, and this mutagenesis was enhanced by plasmid pKM101, but eliminated by the recA mutation. At high doses, where the drug was completely toxic towards uvrB- or recA-carrying strains, it became mutagenic in the DNA-repair-proficient strains. This 'high-dose' mutagenesis was enhanced by plasmid pKM101, but reduced by the polA1 mutation and almost eliminated by the polA3 mutation. Although there are several possible interpretations of these data, they are compatible with the suggestion that the lesion induced by high doses (but not by low doses) of nitracrine is a cross-link, but that this is not the major mutagenic lesion.