Evidence that the recA441 (tif-1) mutant of Escherichia coli K-12 contains a thermosensitive intragenic suppressor of RecA constitutive protease activity.

The recA441 mutant of Escherichia coli, which has been thought to have thermoinducible constitutive RecA protease activity, is known to have two mutations within recA. We show here that the mutation that alters codon 38 actually confers temperature-independent constitutive protease activity; the second mutation in recA441, which is at codon 298, appears to be acting as a temperature-sensitive suppressor of the protease activity.     

Suppression of the UV-sensitive phenotype of Escherichia coli recF mutants by recA(Srf) and recA(Tif) mutations requires recJ+.

Mutations in recA, such as recA801(Srf) (suppressor of RecF) or recA441(Tif) (temperature-induced filamentation) partially suppress the deficiency in postreplication repair of UV damage conferred by recF mutations. We observed that spontaneous recA(Srf) mutants accumulated in cultures of recB recC sbcB sulA::Mu dX(Ap lac) lexA51 recF cells because they grew faster than the parental strain. We show that in a uvrA recB+ recC+ genetic background there are two prerequisites for the suppression by recA(Srf) of the UV-sensitive phenotype of recF mutants. (i) The recA(Srf) protein must be provided in increased amounts either by SOS derepression or by a recA operator-constitutive mutation in a lexA(Ind) (no induction of SOS functions) genetic background. (ii) The gene recJ, which has been shown previously to be involved in the recF pathway of recombination and repair, must be functional. The level of expression of recJ in a lexA(Ind) strain suffices for full suppression. Suppression by recA441 at 30 degrees C also depends on recJ+. The hampered induction by UV of the SOS gene uvrA seen in a recF mutant was improved by a recA(Srf) mutation. This improvement did not require recJ+. We suggest that recA(Srf) and recA(Tif) mutant proteins can operate in postreplication repair independent of recF by using the recJ+ function.     

Mutagenic action of nitrous acid on prophage lambda

The lethal and mutagenic effects of nitrous acid (0,1 M NaNO2 in 0,1 M acetate buffer, pH 4.6) on prophage lambda cI857 ind- were studied in the wild-type cells of Escherichia coli and in 9 repair-deficient mutants: uvrA6, uvrA6 umuC36, uvrD3, uvrE502, polA1, recA13, lexA102, recF143 and xthA9. After treatment with HNO2, the prophage was heat-induced either immediately or after 90 min incubation in broth at 32 degrees C. The prophage survival after delayed induction was considerably higher than after immediate induction. The lethal action of HNO2 was highly expressed in uvrA- and uvrE- lysogens after delayed induction. The frequency of temperature-independent c mutants forming clear plaques at 32 degrees C reached 4% in the wild-type host after immediate induction, this value being 10-15% in uvrA, uvrA umuC, uvrD, uvrE, polA and xthA mutants, 0,8% in recF- lysogen and only 0,2-0,3% in recA and lexA mutants. Under these conditions, about 90% of c mutants are generated by recA+, lexA+-dependent repair mechanism (most probably, due to W-mutagenesis). After delayed induction, mutation frequency in the wild-type host declines considerably (down to 0,1%). Analogous phenomenon of mutation frequency decline was registered in uvrA, xthA, recF, polA, uvrE and uvrD lysogens. Under conditions of delayed induction, the frequency of HNO2-induced c mutations only slightly depends on the recA+ and lexA+ gene products and mutations are, apparently, fixed by replication.     

Genetic control of heat resistance and thermotolerance by recA and uvrA in E. coli K12

Several recA and uvrA derivatives of E. coli K12 AB1157 develop a transient increase in heat resistance, i.e. induced thermotolerance after a brief exposure to 43.5 degrees C (less than 1 h). Thermotolerance was identified from the appearance of an inflection in the survival curve or from the loss of heat resistance in the presence of chloramphenicol (CAM) or rifampicin. Heat resistance and induced thermotolerance were enhanced by recA and uvrA gene functions and their contribution was roughly as follows: AB1157 (recA+ uvrA+) greater than AB2463 (recA- uvrA+) greater than AB1886 (recA+ uvrA-) greater than AB2480 (recA- uvrA-). In heat resistance, uvrA and recA contributed approximately equally and their effects were additive. Induced thermotolerance developed sooner and was maintained at a higher level in the presence of uvrA as compared with recA. Since uvrA-dependent excision repair is scheduled prior to recA-dependent (postreplication) repair, induction of thermotolerance may be linked to DNA repair. Although recA and uvrA play a distinct role, they are not essential, and thermotolerance can develop in the absence of either one or both of these gene functions. Furthermore, since thermotolerance can be induced in recA mutants (AB2463 and AB2480), its biochemical pathway must be different from that of the recA-dependent SOS system.     

Expression of a novel R-plasmid pEB017 compared to pKM101 in Escherichia coli wild-type, recA and uvrA strains

The expression of bacterial resistance to UV irradiation and nitrofurantoin by a novel R-plasmid pEB017 in DNA-repair-proficient (wild-type) and -deficient (recA; uvrA) host strains was compared to the effects of plasmid pKM101 in the isogenic strains. pEB017 partially protected the uvrA strain, and completely protected the wild-type and recA strains from the killing effect of UV irradiation; pKM101 had no effect on the recA strain and only enhanced the survival of the wild-type and the uvrA strains after UV irradiation. pEB017 conferred nitrofurantoin resistance 10-fold on the wild-type and the recA strains and 4-fold on the uvrA strain; pKM101 did not confer nitrofurantoin resistance on the wild-type and recA strains but gave 4-fold resistance in the uvrA strain.     

Sodium arsenite inhibits spontaneous and induced mutations in Escherichia coli

Sodium arsenite at a non-toxic concentration was found to inhibit strongly mutagenesis induced by ultraviolet light (UV), 4-nitroquinoline-1-oxide (4NQO), furylfuramide (AF-2) and methyl methane-sulfonate (MMS) as well as spontaneous mutation in the reversion assay of E. coli WP2uvrA/pKM101. The effect was not, however, seen in the case of the mutagenesis induced by N-methyl-N'-nitro-N-nitrosoguanidine (MNNG). In order to elucidate the mechanism of the mutation-inhibitory effect of sodium arsenite, its action on umuC gene expression and DNA-repair systems was investigated. It was found that sodium arsenite depressed beta-galactosidase induction, corresponding to the umuC gene expression. For UV-irradiated E. coli strains possessing different DNA-repair capacities, sodium arsenite decreased the UV survival rates of WP2, WP2uvrA[uvrA] and WP67[uvrA polA], increased those of SOS-uninducible strains having either the recA+ or uvrA+ such as CM571 [recA], CM561 [lexA(Ind-)] and CM611[uvrA lexA (Ind-)], and did not affect that of the uvrA recA double mutant, WP100. From these results, we assume that sodium arsenite may have at least two roles in its antimutagenesis: as an inhibitor of umuC gene expression, and as an enhancer of the error-free repairs depending on the uvrA and recA genes.     

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.     

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.     

Effect of tsl mutations in decreasing radiation sensitivity of a recA- strain of Escherichia coli K-12.

It has been shown previously that the radiation sensitivity of lexA- strains of Escherichia coli K-12 can be suppressed by thermosensitive mutations (designated tsl) that are closely linked to the lexA locus and are thought to be intragenic suppressors of lexA mutations (Mount et al., 1973). When a recA mutation is crossed into a suppressed tsl- strain, the extreme radiation sensitivity usually conferred by a recA mutation is decreased, but there is no detectable change in genetic recombination deficiency. Increased resistance to UV in the tsl-reA-strains depends upon ability to synthesize active uvrA+ product.     

A loss of uvrA function decreases the induction of the SOS functions recA and umuC by mitomycin C in Escherichia coli

We have studied the levels of recA and umuC protein synthesis in Escherichia coli as a probe for regulatory and mechanistic events involved in mitomycin C mutagenesis. Both RecA and UmuC protein induction were greatly stimulated by mitomycin C in the wild-type strain, reached a peak at about 60 min for the recA gene, and at 90 min for the umuC gene, respectively, and maintained a plateau. The induction was blocked by recA and lexA(Ind-) mutations that conferred no mutagenesis on the cell. Mutation affecting uvrA protein markedly decreased induction of the recA gene as well as the umuC gene by mitomycin C. The results established that UvrA protein is involved in the induction of recA and umuC, and account, at least in part, for the mitomycin C nonmutability of uvrA mutants.     

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.     

Properties of recA441 protein-catalyzed DNA strand exchange can be attributed to an enhanced ability to compete with SSB protein

We have investigated the recombinase activity of recA441 protein by comparing its in vitro DNA strand exchange activity to that of wild-type recA protein. Consistent with its proficiency in recombination in vivo, recA441 protein is able to catalyze the in vitro exchange of a circular single-stranded DNA molecule for a homologous strand in a linear double-stranded DNA molecule. Under conditions optimal for wild-type recA protein, the rates of joint molecule formation are the same for the two recA proteins, but the wild-type protein converts these intermediate species to gapped circular heteroduplex DNA product molecules more rapidly than recA441 protein. In the recA441 protein reaction, joint molecules are instead converted to extensive homology-dependent DNA networks via presumed reinitiation reactions. Under some conditions, the DNA strand exchange activity of recA441 protein is enhanced relative to the wild-type. These conditions include when single-stranded DNA.SSB protein (where SSB is Escherichia coli single-stranded DNA-binding protein) complexes are formed prior to the addition of recA protein, at low magnesium ion concentration in the presence of spermidine, and at low ATP concentrations. Under the conditions examined, recA441 protein competes more effectively with SSB protein for DNA-binding sites; thus, the differences between the strand exchange activities of the wild-type and recA441 proteins can be attributed to this enhanced ability in SSB protein competition.     

Restoration of RecA protein activity by genetic complementation

Summary Bacteria carrying either recA430 or recA453-441 mutations are sensitive to UV-irradiation since they amplify the synthesis of RecA protein either poorly or not at all. We show here that, in a recA453-441 (recA430) heterodiploid, UV-resistance and amplification of RecA430 protein were restored, indicating that the cellular level of RecA-associated protease activity was high enough to inactivate LexA repressor. Prophage 434 repressor was also extensively inactivated, whereas RecA430 protein alone cannot cleave this substrate. On the other hand, during growth of the recA453-441(recA430) heterodiploid at 42° C in the presence of adenine, a treatment activating only RecA441 protein, RecA441 protease activity was as high as in a recA441 haploid. In contrast, following this inducing treatment, there was no complementation between RecA441 and RecA⁺ proteins in a recA453-441(recA ⁺) heterodiploid. These results indicate that multimerization of RecA protein molecules results in a functional interaction that, in some combination between RecA protein subunits, may enhance RecA-associated protease activity.Obra Social de la Caja de Ahorros de Valencia     

A multicopy phr-plasmid increases the ultraviolet resistance of a recA strain of Escherichia coli

It has been previously reported that the ultraviolet sensitivity of recA strains of Escherichia coli in the dark is suppressed by a plasmid pKY1 which carries the phr gene, suggesting that this is due to a novel effect of photoreactivating enzyme (PRE) of E. coli in the dark (Yamamoto et al., 1983a). In this work, we observed that an increase of UV-resistance by pKY1 in the dark is not apparent in strains with a mutation in either uvrA, uvrB, uvrC, lexA, recBC or recF. The sensitivity of recA lexA and recA recBC multiple mutants to UV is suppressed by the plasmid but that of recA uvrA, recA uvrB and recA uvrC is not. Host-cell reactivation of UV-irradiated lambda phage is slightly more efficient in the recA/pKY1 strain compared with the parental recA strain. On the other hand, the recA and recA/pKY1 strains do not differ significantly in the following properties: Hfr recombination, induction of lambda by UV, and mutagenesis. We suggest that dark repair of PRE is correlated with its capacity of excision repair.     

Induction of SOS responses in Escherichia coli by Panfuran-S, 3-di(hydroxymethyl)amino-6-(5-nitro-2-furylethenyl)-1,2,4-triazine

The inducibility of SOS responses by Panfuran-S, which has been used as an antimicrobial medicine in Japan, was studied in Escherichia coli cells having different DNA-repair capacities for UV lesions. Panfuran-S induced mutations at high frequencies in uvrA and the wild-type strains, and significant killing effects of Panfuran-S were detected in DNA-repair-deficient strains, uvrA and recA. The effective prophage induction was detected in two kinds of lambda-lysogenized cells treated with Panfuran-S. The expression of the umuC+ gene was apparently induced in uvrA and the wild-type strains, but not induced in lexA and recA strains. In particular, high inducibility of the gene expression was detected in uvrA strain as compared with the wild-type strain. From these results, we conclude that Panfuran-S is a DNA-damaging agent and may induce the error-prone SOS responses.     

Mutagenic DNA repair in Escherichia coli. XVI. Mutagenesis by ultraviolet light plus delayed photoreversal in recA strains

Mutagenesis was demonstrable after delayed photoreversal of UV-irradiated strains carrying a recA deletion indicating that RecA protein is not essential for the misincorporation process that is revealed by delayed photoreversal. Moreover, the data suggest that RecA protein actually depresses misincorporation to varying extents depending on the recA allele. No delayed photoreversal was demonstrable in reA1 or recA56 bacteria unless the lexA102(ind-) allele was also present. It is suggested that the level of these RecA proteins may be lower in the lexA102(ind-) strains thus minimising their depressive effect. Delayed photoreversal mutagenesis in strains carrying the recA441 allele was not affected by either adenine or guanosine plus cytidine, substances which affect the proteolytic activity of RecA441 protein.     

Conditional lethality of the recA441 and recA730 mutants of Escherichia coli deficient in DNA polymerase I

E. coli strains bearing the recA441 mutation and various mutations in the polA gene resulting in enzymatically well-defined deficiencies of DNA polymerase I have been constructed. It was found that the recA441 strains bearing either the polA1 or polA12 mutation causing deficiency of the polymerase activity of pol I are unable to grow at 42 degrees C on minimal medium supplemented with adenine, i.e., when the SOS response is continuously induced in strains bearing the recA441 mutation. Under these conditions the inhibition of DNA synthesis is followed in recA441 polA12 by DNA degradation and loss of cell viability. A similar lethal effect is observed with the recA730 polA12 mutant. The recA441 strain bearing the polA107 mutation resulting in the deficiency of the 5'-3' exonuclease activity of pol I shows normal growth under conditions of continuous SOS response. We postulate that constitutive expression of the SOS response leads to an altered requirement for the polymerase activity of pol I.     

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.