Induction of recA+-protein synthesis in Escherichia coli

A molecular target for suppression of the evolution of antibiotic resistance: inhibition of the Escherichia coli RecA protein by N(6)-(1-naphthyl)-ADP

We report that N(6)-(1-naphthyl)-ADP inhibits the Escherichia coli RecA protein in vitro. A novel rapid screen identified it as a potent inhibitor of RecA nucleoprotein filament formation, and further characterization established it as an ATP-competitive inhibitor of RecA-catalyzed ATP hydrolysis. This and other inhibitors of RecA activities represent a new approach for understanding the molecular targets and pathways involved in the evolution of antibiotic resistance in bacteria.

Adaptive doses of MNNG efficiently induce a recA-trp gene fusion

The recA gene product plays a critical role in the Escherichia coli SOS system. To facilitate studies of the regulation of the recA operon, we constructed a gene fusion between the recA operon and the Salmonella trp operon. This gene fusion closely mimics the behavior of the authentic recA operon in vivo. Using the gene fusion, we looked at the effect of N-methyl-N'-nitro-N-nitrosoguanidine (MNNG) on recA expression. In contrast to the expectations from previous work, we found that low (0.5 microgram/ml) adaptive doses of MNNG induce the recA-trp gene fusion as efficiently as other SOS inducers without inducing either lambda or phi 80 prophages. These results are a clear example of the ability of some agents to induce a subset of the SOS-dependent operons. They force a reevaluation of many of the arguments that have led to the conclusion that the SOS and adaptive responses are completely independent.

Differential survival and chloramphenicol-insensitive error-prone repair of hydroxylamine-inactivated phi X174 bacteriophage mutants

Features of inactivation, repair and concomitant mutagenesis of hydroxylamine-treated phi X174 bacteriophages are reported here. (1) For reasons unknown, the nonsense phage mutants tested here were far more sensitive to hydroxylamine than the wild-type phage. In contrast, the sensitivities of these same phi X174 mutants to UV-irradiation are indistinguishable. (2) Hydroxylamine-treated amber phages mutated to ochre but not to wild-type particles, i.e., G leads to A transition events were recovered. (3) The repair of phi X174 phages from hydroxylamine-induced damage was error-prone, but unlike UV damage, did not require protein synthesis de novo. Possible mechanisms of these novel features are discussed.

Study of the expression of UVRA and SSB proteins in vivo in lambda hybrid phages containing the uvrA and ssbA genes of Escherichia coli

A 9.3-kb Eco RI fragment obtained by partial digestion of the plasmid pDR2000 and containing the uvrA and ssbA genes was subcloned in the insertion vector lambda gt4. Two hybrid bacteriophages carrying this fragment inserted in opposite orientations were isolated and used to lysogenize a uvrA and an ssbA mutant of Escherichia coli. Both phages conferred to these host bacteria the ultraviolet resistance of the wild-type parent indicating full complementation of the uvrA and of the ssbA defect. Two polypeptides corresponding to the molecular weights of the UVRA protein (115 000 dalton) and of the SSB protein (18 500 dalton) were synthesized and amplified after infection of a UV-irradiated lambda ind- lysogen with these 2 hybrid phages. The UVRA protein was not amplified after infection of a lex A3 host while SSB was still produced in large amount. These results establish that uvrA is repressed by lexA in vivo whereas ssbA is not.

Interspecies recA protein substitution in Escherichia coli and Proteus mirabilis

With the help of recombinant plasmids carrying the recA gene of Escherichia coli or of Proteus mirabilis the ability of the recA gene products to substitute functionally for each other was studied. The recA protein of each can function in recombination, repair, induction of mutations and prophages and in regulation of its own synthesis within the foreign host nearly equally well as in the natural host. It is, therefore, suggested that recA-dependent processes act similarly in E. coli and P. mirabilis.

Cloned truncated recA genes in E. coli. I. Effect on radiosensitivity and recA+ dependent processes

Plasmids pMH1 and pDR1461, possessing the control region and 22% or 73% of the E. coli recA gene, conferred UV sensitivity to wild-type uvrA, and umuC bacteria. Sensitization was less in recA441 (tif-1) mutants and absent in lexA cells. Radiosensitization correlated with inhibition of recombinational repair, even through induced recA protein synthesis and recombination in Hfr matings were normal. Plasmids pMH1 and pDR1461 also prevented induction of some, but not all, SOS functions. Mutagenic reversion to tryptophan prototrophy and induced reactivation of UV-irradiated phage lambda were eliminated, and the efficiency of lambda lysogenic induction reduced. However, naladixic acid induced filamentous growth, mitomycin-C induced uvrA gene expression and post UV-irradiation DNA degradation control were little changed. Explanations of these effects are discussed which involve the presence of either truncated recA protein or multiple copies of the recA gene control sequence.

Variable expression of the ssb--1 allele in different strains of Escherichia coli K12 and B: differential suppression of its effects on DNA replication, DNA repair and ultraviolet mutagenesis

We have transduced the mutant allele ssb-1, which encodes a temperature-sensitive single-strand DNA binding protein (SSB), into several Escherichia coli strains, and have examined colony-forming ability, DNA replication, sensitivity to ultraviolet light (UV) and UV-induced mutability at the nonpermissive temperature. We have found: 1) that the degree of ssb-1-mediated temperature-sensitivity of colony-forming ability and of DNA replication is strain-dependent, resulting in plating efficiencies at 42 degrees C (relative to 30 degrees C) ranging from 100% to 0.002%; 2) that complete suppression of the temperature-sensitivity caused by ssb-1 occurs only on nutrient agar, and not in any other medium tested; 3) that strains in which ssb-1-mediated temperature-sensitivity is completely suppressed show moderate UV sensitivity and normal UV mutability at 30 degrees C, but much more extreme UV sensitivity and drastically reduced UV mutability at 42 degrees C; and 4) that defects in excision repair or in other Uvr+-dependent processes are not responsible for most of the UV sensitivity promoted by ssb-1. We discuss our results in relation to the known properties of SSB and its possible role in the induction of DNA damage-inducible (SOS) functions.

Cloning of a recA-like gene of Proteus mirabilis

A gene of Proteus mirabilis that can substitute for functions of the recA gene of Escherichia coli has been cloned into the plasmid pBR322, using shotgun experiments. The recA-like gene (recAp.m.) has been localized by restriction mapping within a 1.5-Md PstI fragment that is a part of two cloned HindIII fragments of the chromosome of P. mirabilis. The restriction map of the recAp.m. gene differs from that of the recA gene of E. coli. Functionally, the recombinant plasmids containing the recAp.m. gene restore a nearly wild-type level of UV-resistance to several point and deletion mutants in the recA gene of E. coli.

Plasmid pKM101-dependent repair and mutagenesis in Escherichia coli cells with mutations lexB30 tif and zab-53 in the recA gene

Bacterial survival after UV irradiation was increased in E. coli K12 lexB30 and tif zab-53 mutants harboring plasmid pKM101. Mutagenesis in response to UV was observed in these bacteria which, in absence of pKM101, are not UV-mutable. The mutator effect observed in unirradiated wild-type cells containing pKM101 was higher than incubation at 30 degrees C with adenine than at 37 degrees C. This effect was still enhanced by tif mutation, even in the tif zab-53 strain, but it was abolished by lexB30 mutation. In the tif zab-53 (pKM101) strain, repair and mutagenesis of UV-irradiated phage lambda was observed, but not in the lexB30 mutant carrying pKM101. The pKM101 mutant, pGW1, was unable to protect tif zab-53 bacteria against killing by UV, whereas the protection of lexB30 was intermediate; moreover, it did not promote the mutator effect at 30 degrees C or enhance phage repair and mutagenesis in tif zab-53 cells. All UV-induced bacterial mutations in lexB30 (pKM101) strain were suppressors; in contrast, true revertants were found after UV irradiation of the tif zab-53 (pKM101) cells. We suggest that the constitutive activity of RecA protein is enough for the production of UV-promoted suppressor mutations, whereas true reversions require a more active form of this protein which could exert its effects directly or by acting at a regulatory level on other cellular functions.

tif-dependent induction of colicin E1, prophage lambda, and filamentation in Escherichia coli K-12

To help understand how the tif-1 mutation of the recA gene of Escherichia coli confers adenine activability on the recA protein, we used the fact that cytidine plus guanosine inhibits induction of prophage lambda and cell filamentation in a tif-1 mutant, and that adenine reverses this inhibition. We varied the amount of adenine in agar plates containing a fixed amount of cytidine and scored for survivors of three different tif-dependent lethal induction processes. Much more adenine was required for cell killing when cytidine was present than when it was absent. Therefore adenine does not override cytidine inhibition, but instead appears to compete with it for a site of action which may be on the recA protein. The competition is not at the cell transport level. Our results lead to a model in which the tif form of the recA protein is an allosteric enzyme that binds both negative and positive modulators. By varying the adenine-cytidine ratio of the medium it is possible to control the degree of induction in a tif-1 cell. For the three different tif-dependent inductions studied here, least adenine was required for lambda induction and most for lethal filamentation, presumably reflecting requirements for different amounts of activated recA protein in each process. Varying the adenine-cytidine ratio revealed two stable intermediate stages in lambda induction, as well as a stage of colicin E1 induction in which the cells produced colicin without cell death. The rate of filament formation could be similarly controlled. Experiments with tif (ColE1, lambda) gave evidence of a competition between colicin repressor and lambda repressor for activated recA protein.

Ultraviolet light induction of recA protein in a recB uvrB mutant of Escherichia coli

Full and persistent ultraviolet light induction of recA protein with minimal bacterial deoxyribonucleic acid degradation implicates blocked replication sites rather than degradation products as the inducing signals.

Dissociation of tsl-tif-induced filamentation and recA protein synthesis in Escherichia coli K-12

In Escherichia coli, expression of the tif-1 mutation (in the recA gene) induces the "SOS response" at 40 degrees C, including massive synthesis of the recA(tif) protein, cell filamentation, appearance of new repair and mutagenic activities, and prophage induction. Expression of the tsl-1 mutation (in the lexA gene) induces massive synthesis of the recA protein and cell filamentation at 42 degrees C, although other SOS functions are not induced. In this paper we show that the septation inhibition induced in tif and tsl strains at 42 degrees C is not due to the presence of a high concentration of recA protein since (i) no recA mutants (</=10(-8)) were isolated among thermoresistant nonfilamenting revertants of a tif-1 tsl-1 strain, (ii) in a tsl-1 zab-53 strain, only the low basal level of recA protein was synthesized at 42 degrees C, yet cell division was inhibited, and (iii) in a tsl-1 recA99 (amber) strain, no recA protein could be detected at 42 degrees C, yet cell division was inhibited. Among suppressors of tsl-tif-induced lethality are mutations at a locus which we call infB, located in the 66- to 83-min region. The infB1 mutation confers a highly pleiotropic phenotype, which is suggestive of a regulatory defect; it suppressed tsl-tif-induced filamentation but not recA protein synthesis, it did not suppress ultraviolet-induced filamentation (in a lon derivative), and it reduced but did not abolish tif-mediated induction of lambda prophage and bacterial mutagenesis. The dissociation of tsl-tif-induced septation inhibition and recA protein synthesis in the tif-1 tsl-1 infB1 strain suggests that the control of SOS filamentation may not be strictly identical to the control of recA protein synthesis.

Suppression of induction of SOS functions in an Escherichia coli tif-1 mutant by plasmid R100.1

The tif-1 mutation in the recA gene of Escherichia coli caused, at 40 degrees C, lethal cell filamentation, induction of the recA protein, mutagenesis, and, in lambda lysogens, prophage induction. The presence of plasmid R100.1 in tif-1 strains suppressed tif-mediated cell filamentation and killing, recA protein induction, and prophage induction in lysogens. It also reduced mutagenesis in a tif-1 sfiA11(R100.1) strain. Plasmids F'lac, P1, and pMB9, in contrast, had little or no effect on tif-mediated induction of lambda. The presence of R100.1 did not inhibit the induction of the recA protein or of lambda by ultraviolet irradiation or mitomycin C treatment of tif-1(R100.1) or tif-1(lambda)(R100.1) strains.

Nucleases and their control in wild-type and nuh mutants of Neurospora

A review of all of the work on Neurospora nucleases strongly suggests that five nucleases, originally isolated on the basis of markedly different properties, may actually be derived from a single inactive precursor polypeptide via different routes of proteolysis. One of these nucleases may be involved in DNA repair and/or recombination. Two repair-deficient mutants of Neurospora, uvs-3 and nuh-4, may have a lesion in protease(s) which control the level of this nuclease or in some function which regulates the protease(s). Both of these mutants map in the same gene region and they may be defective in recombination, since they are sensitive to various mutagens and to mitomycin C and they show high frequency of spontaneous, but not radiation-induced, recessive lethal mutations and/or deletions.

Induction of UV-resistant DNA replication in Escherichia coli: induced stable DNA replication as an SOS function

The striking similarity between the treatments that induce SOS functions and those that result in stable DNA replication (continuous DNA replication in the absence of protein synthesis) prompted us to examine the possibility of stable DNA replication being a recA+ lexA+-dependent SOS function. In addition to the treatments previously reported, ultraviolet (UV) irradiation or treatment with mitomycin C was also found to induce stable DNA replication. The thermal treatment of tif-1 strains did not result in detectable levels of stable DNA replication, but nalidixic acid readily induced the activity in these strains. The induction of stable DNA replication with malidixic acid was severely suppressed in tif-1 lexA mutant strains. The inhibitory activity of lexA3 was negated by the presence of the spr-51 mutation, an intragenic suppressor of lexA3. Induced stable DNA replication was found to be considerably more resistant to UV irradiation than normal replication both in a uvrA6 strain and a uvr+ strain. The UV-resistant replication occurred mostly in the semiconservative manner. The possible roles of stable DNA replication in repair of damaged DNA are discussed.

MMS mutagenesis in strains of Escherichia coli carrying the R46 mutagenic enhancing plasmid: phenotypic analysis of Arg+ revertants

Arg+ revertants of E. coli AB1157 and derivative strains were selected after MMS mutagenesis and subjected to a phenotypic analysis which permitted the partitioning of revertants into 4 classes. The distribution of these revertant classes was influenced by mutations affecting DNA-repair systems, mutagen treatment and revertant-selection methods. Introduction of the R46 plasmid into strains also affected this mutational specificity, and it was concluded that the plasmid's mutagenic enhancing effect does not merely augment the cellular error-prone capacity to repair MMS damage to DNA.