Involvement of recA and exr Genes in the In Vivo Inhibition of the recBC Nuclease

When Escherichia coli cells are gamma irradiated they degrade their deoxyribonucleic acid (DNA). The DNA of previously gamma-irradiated T4 phage is also degraded in infected cells. The amount of degradation is not only dependent on the dose but also on the genotype of the cell. The amount of degradation is less in cells carrying a recB or a recC mutation, suggesting that most of the DNA degradation is due to the recB(+) and recC(+) gene product (exonuclease V). In some strains a previous dose of ultraviolet (UV) light followed by incubation renders the cells resistant to DNA degradation after gamma irradiation. We have shown this inhibition to take place for infecting T4 phage also. By using six strains of E. coli selected for mutations in the genes recA, exr (or lex), and uvrB, we have been able to show that the preliminary UV treatment produces no change in recA and exr cells for both endogenous DNA degradation and the degradation of infecting irradiated T4 phage DNA, i.e., inhibition was not detected in these strains. On the other hand, wild-type cells and strains carrying mutations of uvrB show inhibition in both types of experiments. Because the recA gene product and the exr(+) (lex(+)) gene product are necessary for the induction of prophage, it is possible that the phenomenon of inducible inhibition requires recA(+) and exr(+) presence. One interpretation of these results is that an inducible inhibitor may be controlled by the exr gene.     

recA-dependent DNA repair processes

UV-radiation-induced lesions in DNA result in the formation of: (1) excision gaps (i.e. a lesion is excised, leaving a gap), (2) daughter-strand gaps (i.e. a lesion can be skipped during replication, leaving a gap), and (3) double-strand breaks (i.e. the DNA strand opposite a gap can be cut). In Escherichia coli, the recA gene product is involved in repairs of all three types of lesions--repair of daughter-strand gaps (2) and double-strand breaks (3) constitutes post-replication repair. The evidence suggests, furthermore, that recA-dependent repair of excision gaps (1) produced in DNA replicated prior to UV irradiation (pre-replication repair) appears to occur by similar mechanisms.     

Action of nitrofurans on E. coli: mutation and induction and repair of daughter-strand gaps in DNA.

The antibacterial and mutagenic potency of 9 nitrofurans in "treat and plate" experiments varied over almost 5 orders of magnitude. The relative toxicities were as follows: FANFT greater than AF2 greater than ANFT greather than furazolidone greater than furagin greater than nitrofurantoin greater than nitrofurazone greater than methylnitrofuroate greater than nitrofuroic acid. In general, mutagenic activity paralleled toxicity. The compounds at concentrations corresponding to their LD50's, induced mutations at frequencies which ranged from 2.5/10(6) survivors for FANFT to 130/10(6) survivors for furagin (NF416). The observed differences in antibacterial and mutagenic activity are unlikely to be due to lack of activation of the weaker agents since the two most potent agents were reduced somewhat more slowly than many of the less active agents. The relative sensitivities to the antibacterial effects of AF2 of strains WP2, WP2 uvrA, CM561 (lexA) and CM571 (recA) were 1 : 1.6 : 3 : 7 and to nitrofurazone 1 : 1 : 25 : 50. The wvrA strain was 6--7-fold more mutable with both these agents than was WP2. No increase over the spontaneous mutation frequency was observed when recA or lexA strains were exposed to either AF2 or nitrofurazone in these experiments. When wild-type of wvrA bacteria containing nitrofuran-induced lesions replicated their DNA in drug-free medium in the presence of [3H]thymidine for 5 min, the label was found in low molecular weight DNA indicating that daughter-strand gaps were formed. During subsequent incubation in nonradioactive medium the molecular weight of the DNA increased to the control value. A recA strain (which was very sensitive to the lethal effects of AF2 and nitrofurazone) lacked the ability to repair daughter-strand gaps caused by nitrofuran-induced lesions.     

DNA postreplication repair gap filling in temperature-sensitive dnaG, dnaC, dnaA mutants of Escherichiacoli

Gaps in daughter-strand deoxyribonucleic acid (DNA) synthesized after exposure of wild-type $\text{Escherichia}\text{coli}$ to ultraviolet light are filled during reincubation. In this study the $\text{dnaG}\text{,}\text{dnaC}$, and $\text{dnaA}$ gene products have been examined for their role in postreplication repair. These gene products are unique in their specific control of certain types of DNA synthesis: initiation of rounds of replication and chain propagation. Initiation of rounds of replication is not essential to gap filling; however, chain propagation by short DNA piece initiation appears to be essential for gap filling.     

Postreplicational formation and repair of DNA double-strand breaks in UV-irradiated Escherichia coli uvrB cells

The number of DNA double-strand breaks formed in UV-irradiated uvrB recF recB cells correlates with the number of unrepaired DNA daughter-strand gaps, and is dependent on DNA synthesis after UV-irradiation. These results are consistent with the model that the DNA double-strand breaks that are produced in UV-irradiated excision-deficient cells occur as the result of breaks in the parental DNA opposite unrepaired DNA daughter-strand gaps. By employing a temperature-sensitive recA200 mutation, we have devised an improved assay for studying the formation and repair of these DNA double-strand breaks. Possible mechanisms for the postreplication repair of DNA double-strand breaks are discussed.     

Temperature-sensitive recA mutant of Escherichia coli K-12: deoxyribonucleic acid metabolism after ultraviolet irradiation.

A mutant of Escherichia coli K-12 temperature sensitive for genetic recombination was investigated and found to carry a mutation that could be cotransduced with cysC and hence could be in the recA gene. To determine whether recA+ can complement this mutation, matings were carried out at 35 and 40 C between Hfr donors that transfer recA+ or recA1 early and recipients carrying wild-type or mutant alleles. It was found that recA+ but not recA1 complements this mutation in zygotic temporary partial diploids. The mutant allele was accordingly designated recA44. A transductant carrying recA44 behaved normally at low temperatures but more like recA- strains at high temperatures with respect to recombinant colony formation in Hfr matings, cell survival, and deoxyribonucleic acid (DNA) synthesis after ultraviolet irradiation, cellular DNA breakdown, and prophage induction when lysogenic for lambda. Alkaline sucrose sedimentation studies of DNA from recA44 cells showed that short DNA molecules synthesized immediately after ultraviolet irradiation increased in molecular weight during subsequent incubation at 32 C but not at 45 C. Hence, recA+ is required for this molecular weight increase. Cells exposed to ultraviolet light synthesized DNA that remained of low molecular weight during a 40-min incubation at 32 C. This material increased in molecular weight in recArut not in recA44 cells during subsequent incubation at 45 C. Thus, the availability of recA+ during the first 40 min at 32 C after irradiation did not obviate the need for recA+ in the subsequent phases of this post-replication repair process.     

Dark-Recovery Processes in Escherichia coli Irradiated with Ultraviolet Light III. Effect of rec Mutations on Recovery of Excision-Deficient Mutants of Escherichia coli K-12

Mutants of Escherichia coli K-12 unable to excise pyrimidine dimers from their deoxyribonucleic acid (DNA) because of a uvr mutation show a higher survival when plated on a minimal salts medium after exposure to ultraviolet radiation than when plated on a complex medium such as nutrient agar containing yeast extract. This response has been called minimal medium recovery (MMR). Recovery of uvr mutants can take place in liquid as well as on solid medium, but not in buffer or under conditions of amino acid starvation that do not permit cell growth and normal DNA replication. MMR can thus be distinguished from the recovery of recombination-deficient (rec(-)uvr(+)) derivatives of K-12 which can occur under conditions where growth is not possible. Because MMR is characteristic of excision-defective mutants, it evidently reflects a type of repair independent of excision. We have obtained genetic evidence that MMR is determined by the rec genes, which also control recombination in K-12. Cells carrying a uvr mutation together with recA13, recA56, recB21, or recC22 failed to show MMR and were more sensitive to ultraviolet radiation than either their rec(+)uvr(-) or rec(-)uvr(+) parents. The rec(+)uvr(-) derivatives obtained from recA uvr(-) strains by transduction or by reversion regained the capacity for MMR. Our results indicate that inactivation of any one of the three genes, recA, recB, or recC, prevents cells from showing MMR.     

Recombinational DNA repair: the ignored repair systems

The recent finding of a role for the recA gene in DNA replication restart does not negate previous data showing the existence of recA-dependent recombinational DNA repair, which occurs when there are two DNA duplexes present, as in the case for recA-dependent excision repair, for postreplication repair (i.e., the repair of DNA daughter-strand gaps), and for the repair of DNA double-strand breaks. Recombinational DNA repair is critical for the survival of damaged cells.     

Mutation induced by drying of Escherichia coli on a hydrophobic filter membrane.

Drying of Escherichia coli to a required cellular water level was conducted on a hydrophobic membrane at the corresponding relative humidity. Mutation from an arginine auxotroph to the prototroph was induced by drying to a water activity (aw) of 0.53 and below, but not to an aw of 0.75 and above. The critical aw below which mutation occurred in the course of drying was similar to that for induction of deoxyribonucleic acid (DNA) strand breakage in the bacteria. Some ultraviolet or gamma-irradiation-sensitive strains, e.g., strains of carrying recA, recB, and uvrA recA were more sensitive to drying than the wild-type strains or strains carrying uvrA and polA. The DNA strand breakage of every strain was observed to be to a similar extent after drying to an aw of less than 0.53. The drying-resistant strains repaired the damaged DNA partially during postdrying incubation in a growth medium but not in phosphate buffer solution, while the drying-sensitive strains could not at all. Significant mutation on drying occurred in the wild-type strains, strains carrying uvrA and polA, but not in strains carrying recA. It is, therefore, concluded that the mutation is caused by errors in rec-dependent repair of the drying-induced breakage in DNA.     

Separate Branches of the uvr Gene-Dependent Excision Repair Process in Ultraviolet-Irradiated Escherichia coli K-12 Cells; Their Dependence upon Growth Medium and the polA, recA, recB, and exrA Genes

The extent of repair of single-strand breaks (incision breaks) induced in the deoxyribonucleic acid (DNA) of Escherichia coli K-12 cells by the uvr gene-dependent excision repair process after ultraviolet (UV) radiation was determined in the wild-type, polA1, recA56, recB21, and exrA strains. The wild-type strain repaired all incision breaks after incident doses of UV radiation (254 nm) of approximately 60 J m(-2) or less when incubated in growth medium, or approximately 15 J m(-2) or less when incubated in buffer. The polA1 strain repaired the incision breaks completely after incident doses of approximately 12 J m(-2) or less when incubated in growth medium, or after approximately 4 J m(-2) when incubated in buffer. The recA13, recB21, and exrA strains showed essentially complete repair after incident doses of 10 to 15 J m(-2) whether the cells were incubated in buffer or growth medium. These results suggest that the uvr gene-dependent excision repair process may be divided into two branches, one which is dependent on the presence of growth medium and also the rec(+)exr(+) genotype, and a second which can occur in buffer (growth medium-independent) and is largely dependent on DNA polymerase I. The presence of chloramphenicol in the growth medium resulted in an inhibition of the growth medium-dependent repair occurring in wild-type and polA1 cells and had little or no effect on the extent of repair observed in recA56, recB21, or exrA cells. The similarities between the growth medium-dependent and -independent branches of excision repair and two known processes for the repair of X-ray-induced single-strand breaks are discussed.     

recA (Srf) suppression of recF deficiency in the postreplication repair of UV-irradiated Escherichia coli K-12.

The mechanism by which recA (Srf) mutations (recA2020 and recA801) suppress the deficiency in postreplication repair shown by recF mutants of Escherichia coli was studied in UV-irradiated uvrB and uvrA recB recC sbcB cells. The recA (Srf) mutations partially suppressed the UV radiation sensitivity of uvrB recF, uvrB recF recB, and uvrA recB recC sbcB recF cells, and they partially restored the ability of uvrB recF and uvrA recB recC sbcB recF cells to repair DNA daughter-strand gaps. In addition, the recA (Srf) mutations suppressed the recF deficiency in the repair of DNA double-strand breaks in UV-irradiated uvrA recB recC sbcB recF cells. The recA2020 and recA801 mutations do not appear to affect the synthesis of UV radiation-induced proteins, nor do they appear to produce an altered RecA protein, as detected by two-dimensional gel electrophoresis. These results are consistent with the suggestion (M. R. Volkert and M. A. Hartke, J. Bacteriol. 157:498-506, 1984) that the recA (Srf) mutations do not act by affecting the induction of SOS responses; rather, they allow the RecA protein to participate in the recF-dependent postreplication repair processes without the need of the RecF protein.     

Physiological Modifications in the Production and Repair of Methyl Methane Sulfonate-Induced Breaks in the Deoxyribonucleic Acid of Escherichia coli K-12

The medium in which Rec(+) strains of Escherichia coli K-12 are grown affected their sensitivity to treatment with methyl methane sulfonate (MMS). Rec(+) cells grown to the stationary phase in glucose-enriched nutrient broth (GNB) were more resistant to MMS than cells grown in nutrient broth (NB). The repair of MMS-induced breaks (or alkali-labile bonds) in the deoxyribonucleic acid (DNA) from E. coli K-12 strains AB1157, AB1886 uvrA6, and SR111 recA13 recB21 grown in GNB and NB media was examined by means of alkaline sucrose gradient centrifugation. It appeared that essentially all of the repair of breaks that occurred, as evidenced by an increase in "molecular weight," took place within 10 min after treatment with MMS under our conditions. Cell survival was highest in cells for which the size of the DNA after the post-treatment incubation was the largest. The largest DNA after post-treatment incubation was found in Rec(+) cells grown in GNB medium. The results suggest that these cells may have an enhanced capacity for repairing breaks in DNA.     

Reactivation of Photoinactivated Single-Stranded DNA Bacteriophage φX174 by UV-Irradiated Escherichia coli Cells

Reactivation of single-stranded DNA phage, photodynamically inactivated in the presence of proflavine sulfate, by three isogenic Escherichia coli strains having different DNA repair capabilities has been studied. It was found that reactivation of photoinactivated phiX174 was possible only if the host cells were recombination proficient (recA(+)) and had been lightly irradiated with UV light prior to infection; the presence of the uvrA(+) gene was not essential. Only a small part of the proflavine-mediated photodynamic damage in phiX174 could be repaired in this fashion. Burst sizes of reactivated phages were, however, comparable to those of normal unirradiated phages.     

Repair and subsequent fragmentation of deoxyribonucleic acid in ultraviolet-irradiated Bacillus subtilis recA.

Cells of Bacillus subtilis recA1 are sensitive to irradiation with ultraviolet light. Evidence is presented here that these cells are not defective in ultraviolet light-induced incision of deoxyribonucleic acid (DNA) or repair DNA synthesis. Ligation of DNA at repair sites appears to occur, but the DNA is subsequently fragmented, apparently at sites of previous repair synthesis. It is hypothesized that the defect in DNA repair leads to host-specific restriction at repaired sites because of a defect in either the structure of the repaired region or specificity of the restriction/modification system.     

Defective homologous pairing and proficient processive unwinding by the recA430 mutant protein and intermediates of homologous pairing by recA protein

The recA protein promotes the formation and processing of joint molecules of homologous double- and single-stranded DNAs in vitro. Under a set of specified conditions, we found that the substitution of a single amino acid in the recA protein (recA430 mutation) depresses its activity for the homologous pairing to about 1/100 of that by the wild type protein when compared by the rate for the first 2-3 min of the reaction, but that the mutation only slightly, if at all, affects its ability to bind progressively to double-stranded DNA to unwind the double helix ("processive unwinding"). This is in striking contrast to an anti-recA protein monoclonal IgG, ARM193, which severely inhibits the processive unwinding but not the homologous pairing, providing further support for our conclusion that the homologous pairing and processive unwinding are functionally independent of each other. Antibody ARM193 caused the breakdown of spontaneously formed filaments of the recA protein, but the recA430 mutation did not affect the self-polymerization of the protein. The recA430 protein was apparently proficient in the functional binding to a single-stranded DNA and in the hydrolysis of ATP. However, we found that under the above conditions the mutant protein was defective as to homology-independent conjunction of DNA molecules to form a "ternary complex" (of macromolecules). These results suggest that (i) only one DNA-binding site is sufficient for the recA protein to promote the processive unwinding (the ability of the protein to form spontaneous filaments is closely related to this process) and that (ii) two DNA-binding sites on each of the recA polypeptides or those composed of a dimer (or oligomer) of the polypeptide are required for the recA protein to promote both the conjunction of parental DNA molecules and the homologous pairing (the ability to form the spontaneous filaments is not essential to this process). (iii) The simultaneous inactivation of the activity to promote the homologous pairing and that to form the ternary complex by the single substitution of the amino acid provides a physical support for the conclusion that the ternary complex is an indispensable intermediate in the homologous pairing.     

On the polymerization state of recA in the absence of DNA

We present an electron microscopy study on the polymerization state of recA in the absence of DNA. In solution recA exists as monomers, small complexes not clearly longer than wide (approximately 9-18 nm), and filaments (diameter approximately 11 nm and variable lengths). We have attempted to quantify the relative amounts of these species by length measurements of the particles on electron micrographs. The percentages of each of these types was found to depend on recA concentration, temperature and presence in the incubation mixture of Mg2+, ATP gamma S, salt or D2O. These additives do not have an absolute effect on polymerization but rather shift the polymerization equilibrium of recA (which depends on recA concentration) up or down the concentration scale.     

Evidence that ultraviolet light-induced DNA replication death of recA bacteria is prevented by protein synthesis in repair-proficient bacteria

The ultraviolet light (UV) survival curve of Escherichia coli WP10 recA trp is almost biphasic, with a greatly reduced shoulder but demonstrating a transition to a decreased slope with increasing fluences, indicating the presence in the culture of a low frequency of resistant cells. Treatment of the culture with chloramphenicol before UV exposure brought almost all of the cells to a high degree of UV resistance, by bringing them to the end of their DNA replication cycle. The survival curves of the repair-proficient E. coli WP2 trp showed a similar pattern with chloramphenicol treatment or tryptophan starvation before UV exposure, but only if protein synthesis were blocked by chloramphenicol for 60 min after UV exposure. The results suggest that when recA/lexA-regulon induction is prevented, either by the recA mutation or by inhibition of protein synthesis after UV exposure, death occurs unless the cells are in the resistant state characteristic of bacteria at the end of their DNA replication cycle. With repair-proficient bacteria treated before UV exposure with chloramphenicol, when protein synthesis is not blocked after UV exposure, a marked expansion of the shoulder occurs because of the function of another resistance-conferring mechanism. This mechanism also depends on the recA+ gene since expansion of the shoulder does not occur in recA bacteria when protein synthesis is inhibited before UV exposure.     

The involvement of DNA polymerase I in the postreplication repair of ultraviolet radiation-induced damage in Escherichia coli K-12.

Summary A deficiency in DNA polymerase I increased the ultraviolet (UV) radiation sensitivity of a uvrA strain of Escherichia coli K-12 when plated on minimal growth medium. The slope of the survival curve for the uvrA polA strain was 2.0-times greater than that for the uvrA strain. The fluence-dependent yield of unrepaired deoxyribonucleic acid (DNA) parental-strand breaks following UV irradiation and incubation in minimal growth medium was similar in both strains. However, the fluence-dependent yield of unrepaired DNA daughter-strand gaps observed following UV irradiation was 1.8-fold greater in the uvrA polA strain than in the uvrA strain. These results suggest that DNA polymerase I is involved in the filling of at least some daughter-strand gaps during postreplication repair. Also, the uvrA polA strain was sensitized by a post-UV treatment with chloramphenicol (CAP) to a similar extent as was the uvrA strain, indicating that DNA polymerase I is not involved in the CAP-inhibitable pathway of postreplication repair.     

Role of the umuC gene in postreplication repair in UV-irradiated Escherichia coli K-12 uvrB

The role of the umuC gene product in postreplication repair was studied in UV-irradiated Escherichia coli K-12 uvrB cells. A mutation at umuC increased the UV radiation sensitivities of uvrB, uvrB recF, uvrB recB, and uvrB recF recB cells; it also increased the deficiencies in the repair of DNA daughter-strand gaps in these strains, but it did not affect the repair of DNA double-strand breaks that arose from unrepaired DNA daughter-strand gaps. We suggest that the umuC gene product is involved in a minor system for the repair of DNA daughter-strand gaps, possibly the repair of overlapping DNA daughter-strand gaps.     

Pyrimidine dimer excision and DNA degradation during liquid holding recovery in ultraviolet-irradiated Escherichia coli K12 uvr+ rec.

The survival of ultraviolet-irradiated Escherichia coli K12 uvr+re was increased by post-irradiation incubation in phosphate buffer. During this incubation both dimer excision and DNA breakdown were inhibited. It is suggested that the bacteria coped with the remaining dimers in a manner which did not involve excision.