Inactivation of Escherichia coli by Near-Ultraviolet Light and 8-Methoxypsoralen: Different Responses of Strains B/r and K-12

A series of Escherichia coli K-12 AB1157 strains with normal and defective deoxyribonucleic acid repair capacity were more resistant to treatment with 8-methoxypsoralen (8-MOP) and near-ultraviolet light (NUV) than a comparable series of strains from the B/r WP2 family although sensitivities to 254-nm ultraviolet light were closely similar. The difference was most marked with strains deficient in both excision and postreplication repair (uvrA recA). The hypothesis that the internal level of 8-MOP was lower in K-12 than B/r uvrA recA derivatives was ruled out on the basis of fluorometric determinations of 8-MOP content and the similar inactivation curves for phage T3 treated intracellularly within the two strains. The demonstration of liquid holding recovery with AB2480 but not WP100 (both recA uvrA strains) and the somewhat greater resistance of the former strain to inactivation by captan revealed the presence in the K-12 strain of a deoxyribonucleic acid repair system independent of the recA(+) and uvrA(+) genes. The presence of this repair system did not, however, affect the survival of T3 phage treated with 8-MOP plus NUV and probably has a relatively small effect on survival of AB2480 under normal conditions. Experiments in which 8-MOP monoadducts were converted to cross-links by a second NUV exposure in the absence of 8-MOP indicated that the level of potentially cross-linkable monoadducts immediately after 8-MOP + NUV is about eightfold lower in K-12-than in B/r-derived strains. It is therefore suggested that the photoproduct yield in the former is well below that in the latter. In agreement with this is the observation that, during the first 10 min after treatment, deoxyribonucleic acid synthesis was just over five times more sensitive to inhibition by 8-MOP plus NUV in WP100 than in AB2480. We assume that 8-MOP in K-12 bacteria is hindered in some way from adsorbing to cellular (though not to phage T3) deoxyribonucleic acid. Consistent with this, 8-MOP has been shown to act as an inhibitor of a component of repair of 254-nm ultraviolet light damage in WP2 but not in AB1157.     

Genetic and kinetic evidence for different types of postreplication repair in Escherichia coli B.

The changes in molecular weight of deoxyribonucleic acid (DNA) synthesized after ultraviolte irradiation of Escherichia coli WP28 uvrA, and strains additionally mutant at polA, exrA, recA, and exrA and polA loci, were examined by alkaline sucrose gradient centrifugation. In a repari=deficient uvrA recA strain, the frequency of breaks in newly synthesized DNA was equal to that for pyrimidine dimers in parental DNA. Measurements of the amounts and rates of postreplication repair of these breaks indicate that (i) repair is two to three times faster when DNA polymerase I is present, although (ii) almost all breaks are repaired regardless of DNA polymerase I activity. (iii) Increased ultraviolet doses lead to an increase in the proportion of breaks remaining unrepaired in uvrA recA, UVRA exrA, and uvrA exrA polA strains. The numbers of unrepaired breaks resemble the numbers expected if repair of one lesion is prevented by proximity of a second lesion.     

Postreplication Repair of Ultraviolet Damage in Haemophilus influenzae

The deoxyribonucleic acid (DNA) synthesized following ultraviolet (UV) irradiation of wild-type (Rd) and recombination-defective strains of Haemophilus influenzae has been analyzed by alkaline sucrose gradient sedimentation. Strain Rd and a UV-resistant, recombination-defective strain Rd(DB117) (rec-) are able to carry out postreplication repair, i.e., close the single-strand gaps in the newly synthesized DNA; in the UV-sensitive, recombination-defective strain DB117, the gaps remain open. The lack of postreplication repair in this strain may be the result of degradation of the newly synthesized DNA.     

Effects of sodium arsenite on single-strand DNA break formation and post-replication repair in E. coli following UV irradiation

A non-lethal dose of sodium arsenite is found to inhibit the formation of single-strand DNA breaks in Escherichia coli WP2 wild-type and WP6 polA strains after UV irradiation. Inhibition of single-strand breakage follows a dose-dependent relationship with respect to increasing sodium arsenite concentration. ATP level in WP2 cells is decreased in the presence of sodium arsenite and therefore the inhibition of DNA break formation may be mediated through lowered ATP levels in the irradiated cells. In the presence of a non-lethal dose of sodium aresenite, post-replication repair in WP2 uvrA strains after UV irradiation is also inhibited.     

Radioadaptive enhancement of the repair of UV-induced postreplication gaps in Escherichia coli cells deficient in DNA repair

In UV-irradiated E. coli WP2 uvrA, deficient in excision repair of DNA with pyrimidine dimers, gamma-irradiation in low doses (radioadaptation) before UV-irradiation leads to the intensification of postreplication repair of DNA. This process in WP2 uvrA polA and uvrA lexA mutants is less than in WP2 uvrA cells, but in WP2 uvrA recA both postreplication repair and its radioadaptive intensification are absent. In E. coli AB1157 excising pyrimidine dimers the radioadaptive intensification of postreplication repair of DNA is expressed almost to the same extent as in WP2 uvrA. In GW2100 umuC mutant, deficient in DNA polymerase V, postreplication repair of DNA is expressed, but its radioadaptive intensification is absent, while in AB2463 recA13 both postreplication repair of DNA and radioadaptive intensification of postreplication repair of DNA are absent. The above data suggest that DNA polymerase I and LexA protein are needed for radioadaptive intensification of postreplication repair of DNA in uvrA strain, and DNA polymerase V is needed for radioadaptive intensification in E. coli AB1157, and that RecA protein is required for postreplication repair and radioadaptive intensification of postreplication repair of DNA.     

Excision repair of ultraviolet-irradiated deoxyribonucleic acid in plasmolyzed cells of Escherichia coli.

A system of cells made permeable by treatment with high concentrations of surcrose (plasmolysis) has been exploited to study the excision repair of ultraviolet-irradiated deoxyribonucleic acid in Escherichia coli. It is demonstrated that adenosine 5'-triphosphate is required for incision breaks to be made in the bacterial chromosome as well as in covalently closed bacteriophage lambda deoxyribonucleic acid. After plasmolysis, uvrC mutant strains appear as defective in the incision step as the uvrA-mutated strains. This is in contrast to the situation in intact cells where uvrC mutants accumulate single-strand breaks during postirradiation incubation. These observations have led to the proposal of a model for excision repair, in which the ultraviolet-specific endonuclease, coded for by the uvrA and uvrB genes, exists in a complex with the uvrC gene product. The complex is responsible for the incision and possibly also the excision steps of repair. The dark-repair inhibitors acriflavine and caffeine are both shown to interfere with the action of the adenosine 5'-triphosphate-dependent enzyme.     

Postreplication repair of deoxyribonucleic acid and daughter strand exchange in uvr- mutants of Bacillus subtilis

The fate of pyrimidine dimers in deoxyribonucleic acid (DNA) newly synthesized by Bacillus subtilis after ultraviolet irradiation was monitored by use of a damage-specific endonuclease that introduces single-strand breaks adjacent to nearly all of the dimer sites. Two Uvr- strains, one defective in the initiation of dimer excision and the other defective in a function required for efficient dimer excision, were found to be similar to their wild-type parent in the kinetics and extent of converting low-molecular-weight DNA newly synthesized after ultraviolet irradiation to high molecular weight. In the Uvr- strains large molecules of newly synthesized DNA remained susceptible to nicking by the damage-specific endonuclease even after extended incubation in growth medium, whereas the enzyme-sensitive sites were rapidly removed from both preexisting and newly synthesized DNA in Uvr+ cells. Our results support the hypothesis that postreplication repair in bacteria includes recombination between dimer-containing parental DNA strands and newly synthesized strands.     

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.     

Impaired incision of ultraviolet-irradiated deoxyribonucleic acid in uvrC mutants of Escherichia coli.

The production of single-strand breaks in the deoxyribonucleic acid of irradiated uvrC mutants of Escherichia coli K-12 was studied both in vivo and in vitro. In vivo, uvrC mutants displayed a slow accumulation of breaks after irradiation, and in this respect appeared different from uvrA mutants, in which very few breaks could be detected. The breakage observed in uvrC mutants differed from that observed in wild-type strains in both the slow rate of break accumulation and the very limited dose response. The behavior of the uvrC lig-7(Ts) double mutant was shown not to be consistent with the suggestion of ligase reversal as the explanation for the lower rate and limited dose response of break formation observed in ultraviolet-irradiated uvrC mutants in vivo. Rather, there appeared to be a real defect in incision. In toluene-treated cells, we studied the effect of the ligase inhibitor nicotinamide mononucleotide on strand incision. Whereas uvrC mutants displayed more strand breakage in the presence of this inhibitor, the same amount of breakage was seen in uvrA mutants, and as such the breakage could be judged as not due to the main excision repair pathway. Experiments using a cell-free system comprising the partially purified uvr+ gene products demonstrated clearly that there is a requirement for the uvrC+ gene product for strand incision. We suggest that in vivo in the absence of the uvrC+ gene product, a partial analog of this protein may allow some abnormal incision.     

Capacity for postreplication repair correlated with transducibility in Rec- mutants of Bacillus subtilis

Bacillus subtilis strains deficient in transduction, transformation, or both were examined for the ability to remove pyrimidine dimers and to convert deoxyribonucleic acid newly synthesized after ultraviolet irradiation to high molecular weight. In one strain deficient in both recombination processes, short pieces of deoxyribonucleic acid synthesized after irradiation were not converted to high molecular weight. Two transformable strains deficient in transduction were also deficient in postreplication repair (i.e., joining of newly synthesized DNA fragments), whereas a nontransformable strain that was normal in transduction was proficient in postreplication repair. None of the transformable strains showed deficiencies in repair resynthesis or ligase activity. Our results suggest that some recombinational events may be common to transduction and postreplication repair but not to transformation, emphasizing the difference between these two pathways for genetic exchange.     

recA gene product is responsible for inhibition of deoxyribonucleic acid synthesis after ultraviolet irradiation.

Deoxyribonucleic acid synthesis after ultraviolet irradiation was studied in wild-type, uvrA, recB, recA recB, and recA Escherichia coli strains. Inhibition of deoxyribonucleic acid synthesis, which occurs almost immediately after exposing the cells to ultraviolet radiation, depends on the functional gene recA.     

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.     

Effect of tsl (thermosensitive suppressor of lex) mutation on postreplication repair in Escherichia coli K-12.

Cells of Escherichia coli K-12 carrying lexA or recA mutations are more sensitive to UV radiation than corresponding wild-type cells and are defective in postreplication repair. Supressor mutations (tsl) have been described previously which increase the UV resistance of lexA uvr+, lexA uvrA, and recAI uvr+ strains, but not the resistance of recA1 uvrA strains. We have studied the effect of the tsl-1 mutation on postreplication repair and find that the enhanced survival conferred by this mutation is correlated with an increased capacity for postreplication repair.     

Amplified Rnase H Activity in Escherichia coli B/R Increases Sensitivity to Ultraviolet Radiation

Strains of E. coli B/r transformed with the plasmid pSK760 were found to be sensitized to inactivation by ultraviolet radiation (UV) and to have elevated levels of RNase H activity. Strains transformed with the carrier vector pBR322 or the plasmid pSK762C derived from pSK760 but with an inactivated rnh gene were not sensitized. UV-inactivation data for strains having known defects in DNA repair and transformed with pSK760 suggested an interference by RNase H of postreplication repair: uvrA cells were strongly sensitized, wild-type and uvrA recF cells were moderately sensitized and recA cells were not sensitized; and minimal medium recovery was no longer apparent in sensitized uvrA cells. Biochemical studies showed that post-UV DNA synthesis was sensitized and that the smaller amounts of DNA synthesized after irradiation, while of normal reduced size as indicated by sedimentation position in alkaline sucrose gradients, did not shift to a larger size (more rapidly sedimenting) upon additional incubation. We suggest an excess level of RNase H interferes with reinitiation of DNA synthesis on damaged templates to disturb the normal pattern of daughter strand gaps and thereby to inhibit postreplication repair.     

Mutant single-strand binding protein of Escherichia coli: genetic and physiological characterization.

A mutation in the Escherichia coli gene for single-strand binding protein results in temperature-sensitive deoxyribonucleic acid replication (R. R. Meyer, J. Glassberg, and A. Kornberg, Proc. Natl. Acad. Sci. U.S.A. 76:1702-1705, 1979). The mutant (ssb-1) is also more sensitive to ultraviolet irradiation and about one-fifth as active in recombination. Single-strand binding protein is thus implicated in repair and recombination as well as in replication. The mutation in ssb is located between uvrA and melA at 90.8 min on the genetic map. The ssb gene appears to be allelic with lexC, a gene with a proposed role in regulating inducible deoxyribonucleic acid repair.     

UV survival of human mycoplasmas: evidence of dark reactivation in Mycoplasma buccale.

The inactivation by ultraviolet (UV) light irradiation of mycoplasma cells of five human strains was monitored by investigating the colony-forming ability. The survival curves of five strains tested indicated that the cells of Mycoplasma buccale only are single and homogenously susceptible to UV light. The effect of the repair inhibitor, caffeine, on the colony-forming ability of UV-irradiated cells was investigated with M. buccale because of its homogenous susceptibility to UV light. The colony formation of irradiated cells was markedly depressed by post-irradiation treatment with caffeine at concentrations that had little or no effect on the colony formation of unirradiated cells. The colony-forming units (CFU) of UV-irradiated cells which were kept in broth without caffeine in the dark increased without a lag as the time in the dark increased. The colony-forming ability of the irradiated cells completely recovered after 3 hr in the dark. However, when irradiated cells were kept in the presence of caffeine, no increase in their CFU was observed. The mode of action of caffeine on UV-irradiated cells closely resembles that described for other organisms which possess dark reactivation systems for UV-induced damage in deoxyribonucleic acid (DNA). Thus, the results obtained provide evidence for the existence of a dark repair function in M. buccale.     

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.     

Mutation induction by monochromatic 254-nm and 365-nm radiation in strains of Escherichia coli that differ in repair capability

Mutation to tryptophan independence after exposure to radiation at the monocrhomatic wavelengths of 254 and 365 nm was studied and compared in 7 strains of Escherichia coli B/r that differ in repair capability. Efficient mutation induction was obtained with both 254-nm and 365-nm radiation with strains WP2 (wild-type), WP2s (uvrA), WP6s (polA uvrA). Mutants were not induced at either wavelength in the lexA strain WP5 or the recA strains WP10 and WP100. These results support the induction of mutants with 365-nm radiation through the error-prone (SOS) pathway of postreplication repair. Log-log plots of tryptophan revertant data at 254 nm showed the expected slopes of approximately 2.0 over the entire influence range tested. In contrast, similar plots of revertant data at 365 nm were complex in all cases tested: at low fluence values (survival greater than 0.5) in all cases where reversion occurred the slopes were approximately 1.0, while at higher fluences (survival less than 0.5) the slopes of the log-log plots were approximately 3.0 with strains WP2s and WP6s, approximately 4.0 with strain WP6 and approximately 6.0 with strain WP2. Differential sensitivity of components of excision and postreplication repair systems to 365-nm radiation may account for the 2-part mutation curves obtained with uvr⁺ rec⁺ lex⁺ strains. It is proposed that efficient error-free repair of mutational lesions occurs at 365-nm fluences below 2–4×10⁵ J m²⁻; at greater 365-nm fluences, error-free excision repair may be selectively inhibited, forcing a greater fraction of mutational lesions to be processed by the error-prone component of the postreplication repair system. The similarity of the mutational responses of WP2s and WP6 at 365 nm supports the selective inhibition of error-free excision repair.     

Repair of hydrogen peroxide-induced single-strand breaks in Escherichia coli deoxyribonucleic acid.

Near-ultraviolet (300 to 400 nm) irradiation of L-tryptophan yielded H2O2 (a toxic photoproduct) that was selectively lethal for rec and polA1 Escherichia coli mutants. H2O2 treatment of cells resulted in the induction of single-strand deoxyribonucleic acid breaks. These breaks were repaired to only a small extent in polA1, recA recB, and recA mutants, but were efficiently repaired in wild-type strains. We conclude that H2O2 deoxyribonucleic acid lesions require both the polA+ and recA+ pathways for repair.     

Mutation induction by thymidine deprivation in Escherichia coli B/r. I. Influence of caffeine.

The addition of caffeine to the plating medium after thymine deprivation of E. coli WP2 uvr+ thyA or WP2 uvrA thyA had no influence on survival. Caffeine, however, reduced the frequency of mutants. The hypothesis is presented that the reduced mutagenesis is due to the sensitivity to caffeine of an inducible error-prone repair mechanism operating during thymine deprivation and after the re-addition of thymine.