DNA degradation, UV sensitivity and SOS-mediated mutagenesis in strains of Escherichia coli deficient in single-strand DNA binding protein: effects of mutations and treatments that alter levels of Exonuclease V or recA protein

Differential suppressor effects of the ssb-1 and ssb-113 alleles on uvrD mutator of Escherichia coli in DNA repair and mutagenesis

We have constructed double mutants carrying either ssb-1 or ssb-113 alleles, which encode temperature-sensitive single strand DNA binding proteins (SSB), and the uvrD::Tn5 allele causing deficiency in DNA helicase II, and have examined sensitivity to ultraviolet light (UV), recombination and spontaneous as well as UV-induced mutagenesis. We have found in a recA+ background that (i) none of the ssb uvrD double mutants was more sensitive to UV than either single mutant; (ii) the ssb-1 allele partially suppressed the strong UV sensitivity of uvrD::Tn5 mutants; (iii) in the recA730 background with constitutive SOS expression, the ssb-1 and ssb-113 alleles suppressed the strong UV-sensitivity caused by the uvrD::Tn5 mutation; (iv) in ssb-113 mutants, the level of recombination was reduced only 10-fold but 100-fold in ssb-1 mutants, showing that there was no correlation between the DNA repair deficiency and the recombination deficiency; (v) the hyper-recombination phenotype of the uvrD::Tn5 mutant was suppressed by the addition of either the ssb-1 or the ssb-113 allele; (vi) no addition of the spontaneous mutator effects promoted by the uvrD::Tn5 and the ssb-113 alleles was observed. These results suggest a possible functional interaction between SSB and Helicase II in DNA repair and mutagenesis.

Relationship between cellular RecA protein concentration and untargeted mutagenesis in Escherichia coli

We measured the production of untargeted mutations in the cI and cII genes of untreated lambda phage undergoing a lytic cycle in UV-irradiated bacterial hosts. As previously shown, treatment with 4 micrograms/ml of rifampicin during post-irradiation incubation inhibited amplification of the RecA protein in these cells. In addition, we observed a decreased mutation rate compared to the untreated, irradiated bacteria. Treatment with 4 micrograms/ml or 8 micrograms/ml rifampicin did not prevent the UV induction of the umuDC operon, as judged by assay of beta-galactosidase activity in a umuC-lacZ fusion strain. In contrast, the UV-induction of beta-galactosidase in the sulA-lacZ fusion strain was decreased by 4 micrograms/ml rifampicin. The inhibition of untargeted mutagenesis by this drug treatment was also observed in a strain constitutive for SOS functions (lexA (Def)) as well as in a RecA-overproducing plasmid strain, suggesting the requirement of other factor(s) in wild-type recA+ cells. An htpR165-carrying strain, that blocks induction of heat-shock proteins, exhibited normal UV-promoted mutagenesis. A correlation was observed between the cellular concentration of RecA protein, increased spontaneously by a temperature shift in a lexA(Ts) strain, and the extent of UV-promoted untargeted mutagenesis. These results suggest a mechanistic role of RecA protein in this process.

Intermediates in homologous pairing promoted by recA protein. Isolation and characterization of active presynaptic complexes

recA protein promotes homologous pairing and strand exchange by an ordered reaction in which the protein first polymerizes on single-stranded DNA. This presynaptic intermediate, which can be formed either in the presence or absence of Escherichia coli single-stranded binding protein (SSB), has been isolated by gel filtration and characterized. At saturation, purified complexes contained one molecule of recA protein per 3.6 nucleotide residues of single-stranded DNA. Complexes that had been formed in the presence of SSB contained up to one molecule of SSB per 15 nucleotide residues, but the content of SSB in different preparations of isolated complexes appeared to be inversely related to the content of recA protein. Even when they have lost as much as a third of their recA protein, presynaptic complexes can retain activity, because the formation of stable joint molecules depends principally on the binding of recA protein to the single-stranded DNA in the localized region that corresponds to the end of the duplex substrate.

Plaque color method for rapid isolation of novel recA mutants of Escherichia coli K-12: new classes of protease-constitutive recA mutants

As a prerequisite to mutational analysis of functional sites on the RecA protein of Escherichia coli, a method was developed for rapid isolation of recA mutants with altered RecA protease function. The method involves plating mutagenized lambda recA+ cI ind on strains deleted for recA and containing, as indicators of RecA protease activity, Mu d(Ap lac) fusions in RecA-inducible genes. The lambda recA phages were recognized by their altered plaque colors, and the RecA protease activity of the lambda recA mutant lysogens was measured by expression of beta-galactosidase from dinD::lac. One class of recA mutants had constitutive protease activity and was designated Prtc; in these cells the RecA protein was always in the protease form without the usual need for DNA damage to activate it. Some Prtc mutants were recombinase negative and were designated Prtc Rec-. Another class of 65 recA mutants isolated as being protease defective were all also recombinase defective. Unlike the original temperature-dependent Prtc Rec+ mutant (recA441), the new Prtc Rec+ mutants showed constitutive protease activity at any growth temperature, with some having considerably greater activity than the recA441 strain. Study of these strong Prtc Rec+ mutants revealed a new SOS phenomenon, increased permeability to drugs. Use of this new SOS phenomenon as an index of protease strength clearly distinguished 5 Prtc mutants as the strongest among 150. These five strongest Prtc mutants showed the greatest increase in spontaneous mutation frequency and were not inhibited by cytidine plus guanosine, which inhibited the constitutive protease activity of the recA441 strain and of all the other new Prtc mutants. Strong Prtc Rec+ mutants were more UV resistant than recA+ strains and showed indications of having RecA proteins whose specific activity of recombinase function was higher than that of wild-type RecA. A Prt+ Rec- mutant with an anomalous response to effectors is described.

Analysis of the regulatory region of the ssb gene of Escherichia coli

The regulation of the ssb gene of E. coli has been studied. We reported earlier that the SOS box of the neighbouring uvrA gene also controls the transcription of the ssb gene. Detailed analysis of the upstream region of ssb by S1 mapping reveals the existence of three in vivo functional promoters of which the most upstream one (PI) is inducible by DNA damage. Measurement of galactokinase synthesis using galK fusion plasmids indicates that the uninduced level of transcription from the PI promoter is low. Ssb multicopy plasmids lacking the PI promoter still complement the UV sensitivity of an Ssb mutant. The role of the three promoters in the regulation of the level of Ssb protein in the cell, is discussed.

Spontaneous mutagenesis: the roles of DNA repair, replication, and recombination

There appears to be no dearth of mechanisms to explain spontaneous mutagenesis. In the case of base substitutions, data for bacteriophage T4 and especially for E. coli and S. cerevisiae suggest important roles in spontaneous mutagenesis for the error-prone repair of DNA damage (to produce mutations) and for error-free repair of DNA damage (to avoid mutagenesis). Data from the very limited number of studies on the subject suggest that about 50% of the spontaneous base substitutions in E. coli, and perhaps 90% in S. cerevisiae are due to error-prone DNA repair. On the other hand, spontaneous frameshifts and deletions seem to result from mechanisms involving recombination and replication. Spontaneous insertions have been shown to be important in the strongly polar inactivation of certain loci, but it is less important at other loci. Perhaps with continued study, the term "spontaneous mutagenesis" will be replaced by more specific terms such as 5-methylcytosine deamination mutagenesis, fatty acid oxidation mutagenesis, phenylalanine mutagenesis, and imprecise-recombination mutagenesis. While most studies have concentrated on mutator mutations, the most conclusive data for the actual source of spontaneous mutations have come from the study of antimutator mutations. Further study in this area, perhaps along with an understanding of chemical antimutagens, should be invaluable in clarifying the bases of spontaneous mutagenesis.

Dual role for Escherichia coli RecA protein in SOS mutagenesis

Induction of the Escherichia coli SOS system increases the ability of the cells to perform DNA repair and mutagenesis. Previous work has shown that this increased mutagenesis is the result of derepression of specific genes through a complex regulatory mechanism controlled by LexA and RecA proteins. One role of RecA protein in this process is to facilitate proteolytic cleavage of LexA protein (the repressor) in response to an inducing signal that reversibly activates RecA protein to perform this function. We show that activated RecA protein plays a second role in SOS mutagenesis, as revealed by analyzing repair of UV-damaged phage lambda in host mutants with alterations in the SOS regulatory system. First, phage mutagenesis was not expressed constitutively in a mutant that is derepressed through lack of functional LexA protein; activated RecA protein was still required. Second, phage mutagenesis was constitutively expressed in the presence of recA mutations that alter RecA protein so that it is activated in normally growing cells. There was also RecA-dependent constitutive expression of SOS mutagenesis in host mutants that lack functional LexA protein and carry plasmids. We discuss several possible biochemical mechanisms for this second role of activated RecA protein in SOS mutagenesis.

Protection of nonmodified phage lambda against EcoK restriction mediated by recA protein

A study was conducted to establish whether the EcoK-specific restriction, which is alleviated in E. coli cells after UV induction of the SOS response (Day 1977), is also alleviated under the influence of an increased level of recA protein without induction of other SOS functions. The host cells used were E. coli K-12, strain AB2497, and its derivatives; the nonmodified phage lambda was a mutant b2b5(vir). An increase of the recA protein level was induced using the plasmid pX02, which is a recombinant of pBR322 carrying the recA gene of E. coli. AB2497(pX02) cells were found to exhibit a lower level of restriction than those without plasmid. The results indicate that the recA protein protects phage DNA during the process of restriction. A further factor affecting restriction is the growth phase of the culture of the restricting host: cells in the late stationary phase exhibit lower restriction than those in the exponential phase of growth. By a combination of these two factors (presence of plasmid pX02 and stationary growth phase) one can reduce the restriction of nonmodified phage about 300 times.

RecA protein--promoted lambda repressor cleavage: complementation between RecA441 and RecA430 proteins in vitro

Induction of prophage lambda occurs in recA441 mutant lysogens after a shift to 42 degrees C in the presence of adenine. If the synthesis of RecA441 protein is maintained at a low basal level by the presence of a second mutation in the recA441 gene, recA453, induction of prophage lambda is prevented. The ability to induce prophage lambda is restored by the introduction, on a transducing phage, of a second recA gene carrying the recA430 mutation; by itself, the RecA430 protein is devoid of activity against the lambda repressor (Rebollo et al. 1984). In order to explain how the RecA430 protein might complement the RecA441 protein to provide lambda repressor cleavage in a recA453-441 (recA430) diploid lysogen, we characterized the cleavage reaction catalysed by a mixture of these proteins in vitro. Our results suggest that, in the presence of dATP, the RecA441 and RecA430 proteins form mixed multimers on single-stranded DNA, in which the RecA441 protein molecules enhance the DNA binding affinity of RecA430 protein molecules, but RecA430 protein molecules support no cleavage of the lambda repressor. Although the effects of the RecA430 and single-strand binding (SSB) proteins are similar in vitro, we show that the SSB protein cannot substitute for the RecA430 protein in restoring lambda repressor cleavage in a recA453-441 lysogen. Comparison of the stimulatory effect of long single-stranded DNA with that of (dA)14 oligonucleotides on the RecA441 protein-directed cleavage of the lambda repressor in the presence of various nucleoside triphosphates (NTPs) indicates that the cooperative binding of the RecA441 protein to single-stranded DNA stabilizes the RecA protein-DNA complexes so that they remain intact long enough to support cleavage of the lambda repressor. We conclude that the low basal level of the RecA441 protein in a recA453-441 cell is sufficient to cleave the lambda repressor, under conditions where a normal basal level of RecA430 protein is also present allowing the formation of mixed multimers on single-stranded DNA regions normally present in the cell.

Quantification of SSB protein in E. coli and its variation during RECA protein induction

Using a two-site immunometric assay (IRMA) we quantified the concentration of single-stranded DNA binding protein (SSB) in several E. coli strains. We found approximately 7,000 monomers of SSB present per bacterium, and this number remained constant throughout the exponential phase of growth. Two ssb- mutants (ssb-1 and ssb-113) are defective in the induction of the S.O.S. pathway. One of the first functions expressed upon induction of the S.O.S. pathway is the amplification of recA protein (RECA), which we monitored by an IRMA assay similar to the one used for SSB quantification. By combining the two assays we determined the level of SSB and RECA in ssb- mutants or in SSB and RECA overproducer strains. We found: a) a normal induction of RECA following UV irradiation of E. coli bacteria overproducing SSB, b) a normal level of SSB in wild type and ssb-1 and ssb-113 mutants either in the absence or in the presence of S.O.S. inducing agents. We confirmed a severe impairment in the induction of RECA in these two mutants after nalidixic acid treatment. Our results suggest that the concentrations of RECA and SSB protein in E. coli are regulated by independent biochemical pathways.

Mechanism of the concerted action of recA protein and helix-destabilizing proteins in homologous recombination

Secondary structure in single-stranded DNA impedes the presynaptic association of recA protein and consequently blocks the formation of joint molecules as evidenced by effects of temperature, nucleotide sequence, and ionic conditions. Escherichia coli single-strand-binding protein eliminates sequence-specific "cold spots" by removing folds even from sites of strong secondary structure. Thus, destabilization of secondary structure in single-stranded DNA is critical for the action of recA protein, whereas specific interactions directly between helix-destabilizing proteins and recA protein are unimportant.

F sex factor encodes a single-stranded DNA binding protein (SSB) with extensive sequence homology to Escherichia coli SSB

We have determined the sequence of the gene encoding a single-stranded DNA (ss DNA) binding protein (SSB) from the Escherichia coli F sex factor and the amino acid sequence of the protein it encodes. The protein has extensive homology with E. coli SSB, particularly within its NH2-terminal region, where 87 of the first 115 amino acid residues are identical to those of the E. coli protein. We have previously shown that this portion of E. coli SSB contains the DNA binding region. The sequences diverge extensively in their COOH-terminal regions, although small areas of homology exist in several places. Six of the last seven amino acid residues of the two proteins are identical, which may have implications in terms of the direct interactions of these proteins with other proteins required for DNA replication, recombination, and repair. The coding region of the F plasmid ssf gene is 537 base pairs. The protein encoded by the gene contains 178 amino acids (one more than E. coli SSB) and has a calculated molecular weight of 19,505. Other than the presumptive Shine-Dalgarno sequence, the promoter and terminator regions of both genes are not similar. The most significant feature in this regard may be the lack of a region of dyad symmetry within the presumptive promoter of the F plasmid ssf gene as is found in the region of the presumptive E. coli ssb promoter. In this report the predicted secondary structures of both the F plasmid and E. coli SSB proteins are compared and the evolutionary significance of their sequence and structural similarities to the functional domains of the proteins are discussed.

DNA repair properties of Escherichia coli tif-1, recAo281 and lexA1 strains deficient in single-strand DNA binding protein

Mutations affecting single-strand DNA binding protein (SSB) impair induction of mutagenic (SOS) repair. To further investigate the role of SSB in SOS induction and DNA repair, isogenic strains were constructed combining the ssb+, ssb-1 or ssb-113 alleles with one or more mutations known to alter regulation of damage inducible functions. As is true in ssb+ strains tif-1 (recA441) was found to allow thermal induction of prophage lambda + and Weigle reactivation in ssb-1 and ssb-113 strains. Furthermore, tif-1 decreased the UV sensitivity of the ssb-113 strain slightly and permitted UV induction of prophage lambda + at 30 degrees C. Strains carrying the recAo281 allele were also constructed. This mutation causes high constitutive levels of RecA protein synthesis and relieves much of the UV sensitivity conferred by lexA- alleles without restoring SOS (error-prone) repair. In contrast, the recAo281 allele failed to alleviate the UV sensitivity associated with either ssb- mutation. In a lexA1 recAo281 background the ssb-1 mutation increased the extent of postirradiation DNA degradation and concommitantly increased UV sensitivity 20-fold to the level exhibited by a recA1 strain. The ssb-113 mutation also increased UV sensitivity markedly in this background but did so without greatly increasing postirradiation DNA degradation. These results suggest a direct role for SSB in recombinational repair apart from and in addition to its role in facilitating induction of the recA-lexA regulon.