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

R-loop induced stress response by second (p)ppGpp synthetase in Mycobacterium smegmatis: functional and domain interdependence

Persistent R-loops lead to replicative stress due to RNA polymerase stalling and DNA damage. RNase H enzymes facilitate the organisms to survive in the hostile condition by removing these R-loops. MS_RHII-RSD was previously identified to be the second (p)ppGpp synthetase in Mycobacterium smegmatis. The unique presence of an additional RNase HII domain raises an important question regarding the significance of this bifunctional protein. In this report, we demonstrate its ability to hydrolyze R-loops in Escherichia coli exposed to UV stress. MS_RHII-RSD gene expression was upregulated under UV stress, and this gene deleted strain showed increased R-loop accumulation as compared to the wild type. The domains in isolation are known to be inactive, and the full length protein is required for its function. Domain interdependence studies using active site mutants reveal the necessity of a hexamer form with high alpha helical content. In previous studies, bacterial RNase type HI has been mainly implicated in R-loop hydrolysis, but in this study, the RNase HII domain containing protein showed the activity. The prospective of this differential RNase HII activity is discussed. This is the first report to implicate a (p)ppGpp synthetase protein in R-loop-induced stress response.

A genetic analysis of the functional interactions within Mycobacterium tuberculosis single-stranded DNA binding protein

Single-stranded DNA binding proteins (SSBs) are vital in all organisms. SSBs of Escherichia coli (EcoSSB) and Mycobacterium tuberculosis (MtuSSB) are homotetrameric. The N-terminal domains (NTD) of these SSBs (responsible for their tetramerization and DNA binding) are structurally well defined. However, their C-terminal domains (CTD) possess undefined structures. EcoSSB NTD consists of β1-β1′-β2-β3-α-β4-β45₁-β45₂-β5 secondary structure elements. MtuSSB NTD includes an additional β-strand (β6) forming a novel hook-like structure. Recently, we observed that MtuSSB complemented an E. coli Δssb strain. However, a chimeric SSB (mβ4-β5), wherein only the terminal part of NTD (β4-β5 region possessing L₄₅ loop) of EcoSSB was substituted with that from MtuSSB, failed to function in E. coli in spite of its normal DNA binding and oligomerization properties. Here, we designed new chimeras by transplanting selected regions of MtuSSB into EcoSSB to understand the functional significance of the various secondary structure elements within SSB. All chimeric SSBs formed homotetramers and showed normal DNA binding. The mβ4-β6 construct obtained by substitution of the region downstream of β5 in mβ4-β5 SSB with the corresponding region (β6) of MtuSSB complemented the E. coli strain indicating a functional interaction between the L₄₅ loop and the β6 strand of MtuSSB.

Chimeras of Escherichia coli and Mycobacterium tuberculosis single-stranded DNA binding proteins: characterization and function in Escherichia coli

Single stranded DNA binding proteins (SSBs) are vital for the survival of organisms. Studies on SSBs from the prototype, Escherichia coli (EcoSSB) and, an important human pathogen, Mycobacterium tuberculosis (MtuSSB) had shown that despite significant variations in their quaternary structures, the DNA binding and oligomerization properties of the two are similar. Here, we used the X-ray crystal structure data of the two SSBs to design a series of chimeric proteins (mβ1, mβ1′β2, mβ1–β5, mβ1–β6 and mβ4–β5) by transplanting β1, β1′β2, β1–β5, β1–β6 and β4–β5 regions, respectively of the N-terminal (DNA binding) domain of MtuSSB for the corresponding sequences in EcoSSB. In addition, mβ1′β2_ESWR SSB was generated by mutating the MtuSSB specific ‘PRIY’ sequence in the β2 strand of mβ1′β2 SSB to EcoSSB specific ‘ESWR’ sequence. Biochemical characterization revealed that except for mβ1 SSB, all chimeras and a control construct lacking the C-terminal domain (ΔC SSB) bound DNA in modes corresponding to limited and unlimited modes of binding. However, the DNA on MtuSSB may follow a different path than the EcoSSB. Structural probing by protease digestion revealed that unlike other SSBs used, mβ1 SSB was also hypersensitive to chymotrypsin treatment. Further, to check for their biological activities, we developed a sensitive assay, and observed that mβ1–β6, MtuSSB, mβ1′β2 and mβ1–β5 SSBs complemented E. coli Δssb in a dose dependent manner. Complementation by the mβ1–β5 SSB was poor. In contrast, mβ1′β2_ESWR SSB complemented E. coli as well as EcoSSB. The inefficiently functioning SSBs resulted in an elongated cell/filamentation phenotype of E. coli. Taken together, our observations suggest that specific interactions within the DNA binding domain of the homotetrameric SSBs are crucial for their biological function.

SSB as an organizer/mobilizer of genome maintenance complexes

When duplex DNA is altered in almost any way (replicated, recombined, or repaired), single strands of DNA are usually intermediates, and single-stranded DNA binding (SSB) proteins are present. These proteins have often been described as inert, protective DNA coatings. Continuing research is demonstrating a far more complex role of SSB that includes the organization and/or mobilization of all aspects of DNA metabolism. Escherichia coli SSB is now known to interact with at least 14 other proteins that include key components of the elaborate systems involved in every aspect of DNA metabolism. Most, if not all, of these interactions are mediated by the amphipathic C-terminus of SSB. In this review, we summarize the extent of the eubacterial SSB interaction network, describe the energetics of interactions with SSB, and highlight the roles of SSB in the process of recombination. Similar themes to those highlighted in this review are evident in all biological systems.

Single-stranded DNA-binding protein recruits DNA polymerase V to primer termini on RecA-coated DNA

Translesion DNA synthesis (TLS) by DNA polymerase V (polV) in Escherichia coli involves accessory proteins, including RecA and single-stranded DNA-binding protein (SSB). To elucidate the role of SSB in TLS we used an in vitro exonuclease protection assay and found that SSB increases the accessibility of 3' primer termini located at abasic sites in RecA-coated gapped DNA. The mutant SSB-113 protein, which is defective in protein-protein interactions, but not in DNA binding, was as effective as wild-type SSB in increasing primer termini accessibility, but deficient in supporting polV-catalyzed TLS. Consistently, the heterologous SSB proteins gp32, encoded by phage T4, and ICP8, encoded by herpes simplex virus 1, could replace E. coli SSB in the TLS reaction, albeit with lower efficiency. Immunoprecipitation experiments indicated that polV directly interacts with SSB and that this interaction is disrupted by the SSB-113 mutation. Taken together our results suggest that SSB functions to recruit polV to primer termini on RecA-coated DNA, operating by two mechanisms: 1) increasing the accessibility of 3' primer termini caused by binding of SSB to DNA and 2) a direct SSB-polV interaction mediated by the C terminus of SSB.

Distinct properties of Mycobacterium tuberculosis single-stranded DNA binding protein and its functional characterization in Escherichia coli

Single-stranded DNA binding proteins (SSBs) play an essential role in various DNA functions. Characterization of SSB from Mycobacterium tuberculosis, which infects nearly one-third of the world's population and kills about 2-3 million people every year, showed that its oligomeric state and various in vitro DNA binding properties were similar to those of the SSB from Escherichia coli. In this study, use of the yeast two-hybrid assay suggests that the ECO:SSB and the MTU:SSB are even capable of heterooligomerization. However, the MTU:SSB failed to complement a Deltassb strain of E. coli. The sequence comparison suggested that MTU:SSB contained a distinct C-terminal domain. The C-terminal domain of ECO:SSB interacts with various cellular proteins. The chimeric constructs between the N- and C-terminal domains of the MTU:SSB and ECO:SSB exist as homotetramers and demonstrate DNA binding properties similar to the wild-type counterparts. Despite similar biochemical properties, the chimeric SSBs also failed to complement the Deltassb strain of E.coli. These data allude to the occurrence of a 'cross talk' between the N- and the C-terminal domains of the SSBs for their in vivo function. Further, compared with those of the ECO:SSB, the secondary/tertiary interactions within MTU:SSB were found to be less susceptible to disruption by guanidinium hydrochloride. Such structural differences could be exploited for utilizing such essential proteins as crucial molecular targets for controlling the growth of the pathogen.

Recombinational repair of DNA damage in Escherichia coli and bacteriophage lambda

Although homologous recombination and DNA repair phenomena in bacteria were initially extensively studied without regard to any relationship between the two, it is now appreciated that DNA repair and homologous recombination are related through DNA replication. In Escherichia coli, two-strand DNA damage, generated mostly during replication on a template DNA containing one-strand damage, is repaired by recombination with a homologous intact duplex, usually the sister chromosome. The two major types of two-strand DNA lesions are channeled into two distinct pathways of recombinational repair: daughter-strand gaps are closed by the RecF pathway, while disintegrated replication forks are reestablished by the RecBCD pathway. The phage lambda recombination system is simpler in that its major reaction is to link two double-stranded DNA ends by using overlapping homologous sequences. The remarkable progress in understanding the mechanisms of recombinational repair in E. coli over the last decade is due to the in vitro characterization of the activities of individual recombination proteins. Putting our knowledge about recombinational repair in the broader context of DNA replication will guide future experimentation.

The mutagenesis protein MucB interacts with single strand DNA binding protein and induces a major conformational change in its complex with single-stranded DNA

The MucA and MucB proteins are plasmid-encoded homologues of the Escherichia coli UmuD and UmuC proteins, respectively. These proteins are required for SOS mutagenesis, although their mechanism of action is unknown. By using the yeast two-hybrid system we have discovered that MucB interacts with SSB, the single strand DNA binding protein (SSB) of E. coli. To examine the interaction at the protein level, the MucA, MucA', and MucB proteins were overproduced, purified in denatured state, and refolded. Purified MucA and MucA' each formed homodimers, whereas MucB was a monomer under native conditions. RecA promoted the cleavage of MucA to MucA', and MucB was found to bind single-stranded DNA (ssDNA), similarly to the properties of the homologous UmuD and UmuC proteins. Purified MucB caused a shift in the migration of SSB in a sucrose density gradient, consistent with an interaction between these proteins. Addition of MucB to SSB-coated ssDNA caused increased electrophoretic mobility of the nucleoprotein complex and increased staining of the DNA by ethidium bromide. Analysis of radiolabeled SSB in the complexes revealed that only a marginal release of SSB occurred upon addition of MucB. These results suggest that MucB induces a major conformational change in the SSB.ssDNA complex but does not promote massive release of SSB from the DNA. The interaction with SSB might be related to the role of MucB in SOS-regulated mutagenesis.

Viability and preliminary in vivo characterization of site-directed mutants of Escherichia coli single-stranded DNA-binding protein

Site-directed mutations involving selected amino acids of Escherichia coli single-stranded DNA-binding protein (SSB) were tested for their in vivo functionality when introduced into a chromosomal ssb deletion strain on a plasmid. All mutants complemented the ssb deletion for viability when present on a pSC101 derivative. The generation time with ssbW54S doubled in comparison to the ssb+ control, and both the ssbW54S- and ssbH55K-containing strains exhibited temperature sensitivity. ssbH55K, ssbW54S, ssbW88T, and ssbH55Y (ssb-1) strains displayed reduced survival to ultraviolet irradiation, while ssbW40T and ssbF60L strains were comparable to the ssb+ control strain. This study represents the first investigation of the in vivo properties of ssb mutations constructed for in vitro analysis of DNA binding by SSB.

Requirement for the polymerization and 5'-->3' exonuclease activities of DNA polymerase I in initiation of DNA replication at oriK sites in the absence of RecA in Escherichia coli rnhA mutants

In previous studies, we found that the requirement for RecA protein in constitutive stable DNA replication (cSDR) can be bypassed by derepression of the LexA regulon and that DNA polymerase I (DNA PolI) is essential for this Rip (RecA-independent process) pathway of cSDR (Y. Cao, R. R. Rowland, and T. Kogoma, J. Bacteriol. 175:7247-7253, 1993). In this study, the role of DNA PolI in the Rip pathway was further examined. By using F' plasmids carrying different parts of the polA gene, a series of complementation tests was carried out to investigate the requirement for the three enzymatic activities, polymerization, 3'-->5' exonuclease, and 5'-->3' exonuclease activities, of DNA PolI. The result indicated that both the 5'-->3' exonuclease and polymerization activities of DNA PolI are essential for bypassing the requirement for RecA in cSDR but that the 3'-->5' exonuclease activity can be dispensed with. Complementation experiments with rat DNA Pol beta also supported the hypothesis that a nick translation activity is probably involved in cSDR in the absence of RecA. An analysis of DNA synthesis suggested that DNA PolI is involved in the initiation but not the elongation stage of cSDR. Moreover, the dnaE293(Ts) mutation was shown to render the bypass replication temperature sensitive despite the presence of active DNA PolI, suggesting that DNA PolIII is responsible for the elongation stage of the Rip pathway. A model which describes the possible roles of RecA in cSDR and the possible function of DNA PolI in the Rip pathway is proposed.

Replication of damaged DNA and the molecular mechanism of ultraviolet light mutagenesis

On UV irradiation of Escherichia coli cells, DNA replication is transiently arrested to allow removal of DNA damage by DNA repair mechanisms. This is followed by a resumption of DNA replication, a major recovery function whose mechanism is poorly understood. During the post-UV irradiation period the SOS stress response is induced, giving rise to a multiplicity of phenomena, including UV mutagenesis. The prevailing model is that UV mutagenesis occurs by the filling in of single-stranded DNA gaps present opposite UV lesions in the irradiated chromosome. These gaps can be formed by the activity of DNA replication or repair on the damaged DNA. The gap filling involves polymerization through UV lesions (also termed bypass synthesis or error-prone repair) by DNA polymerase III. The primary source of mutations is the incorporation of incorrect nucleotides opposite lesions. UV mutagenesis is a genetically regulated process, and it requires the SOS-inducible proteins RecA, UmuD, and UmuC. It may represent a minor repair pathway or a genetic program to accelerate evolution of cells under environmental stress conditions.

Overproduction of DnaE protein (alpha subunit of DNA polymerase III) restores viability in a conditionally inviable Escherichia coli strain deficient in DNA polymerase I

A polA12 recA718 double mutant of Escherichia coli, in which DNA polymerase I is temperature sensitive, was unable to maintain normal DNA synthesis or to form colonies on rich media at 42 degrees C. Overproduction of DnaE protein, the polymerizing alpha subunit of DNA polymerase III, restored bacterial DNA replication and cell viability, as well as the PolI-dependent replication of the plasmid carrying dnaE.

The single-stranded DNA-binding protein of Escherichia coli

The single-stranded DNA-binding protein (SSB) of Escherichia coli is involved in all aspects of DNA metabolism: replication, repair, and recombination. In solution, the protein exists as a homotetramer of 18,843-kilodalton subunits. As it binds tightly and cooperatively to single-stranded DNA, it has become a prototypic model protein for studying protein-nucleic acid interactions. The sequences of the gene and protein are known, and the functional domains of subunit interaction, DNA binding, and protein-protein interactions have been probed by structure-function analyses of various mutations. The ssb gene has three promoters, one of which is inducible because it lies only two nucleotides from the LexA-binding site of the adjacent uvrA gene. Induction of the SOS response, however, does not lead to significant increases in SSB levels. The binding protein has several functions in DNA replication, including enhancement of helix destabilization by DNA helicases, prevention of reannealing of the single strands and protection from nuclease digestion, organization and stabilization of replication origins, primosome assembly, priming specificity, enhancement of replication fidelity, enhancement of polymerase processivity, and promotion of polymerase binding to the template. E. coli SSB is required for methyl-directed mismatch repair, induction of the SOS response, and recombinational repair. During recombination, SSB interacts with the RecBCD enzyme to find Chi sites, promotes binding of RecA protein, and promotes strand uptake.

Biochemical events essential to the recombination activity of Escherichia coli RecA protein. I. Properties of the mutant RecA142 protein

We have characterized the biochemical properties of Escherichia coli RecA142 protein, the product of a recA allele that is phenotypically defective in genetic recombination. In vitro, this mutant RecA protein is totally defective in DNA heteroduplex formation. Despite this defect, RecA142 protein is not deficient in all other biochemical activities. RecA142 protein is proficient in single-strand (ss) DNA binding ability, ssDNA-dependent ATPase activity, and DNA-free self-association (although the first 2 properties show a greater sensitivity to NaCl concentration than does the wild-type protein). However, RecA142 protein is deficient in four properties: (1) its ssDNA-dependent ATPase activity is completely inhibited by ssDNA binding (SSB) protein, demonstrating that RecA142 protein is unable to compete effectively with SSB protein for ssDNA binding sites; (2) it is unable to promote the coaggregation of ssDNA and double-strand (ds) DNA; (3) its M13 dsDNA-dependent ATPase activity is attenuated to approximately 5% of the level of the wild-type protein; (4) it is unable fully to develop characteristics of the high-affinity ssDNA-binding state that is normally induced by ATP. The first three deficiencies correspond to defects in the presynaptic, synaptic and postsynaptic steps of the in vitro DNA strand exchange reaction, respectively; the fourth is the likely fundamental basis for defects 1 and 3. Therefore, one or more of these properties must be important to both the in vitro and in vivo processes.

Post-ultraviolet DNA synthesis in the absence of repair: role of the single-strand DNA-binding protein

Post-ultraviolet DNA synthesis kinetics were investigated in the Escherichia coli uvrA recA strain and its isogenic counterpart, overproducing single-strand DNA-binding protein (SSB). It was demonstrated that large quantities of SSB enhance the capacity of the unmodified replisome to use the UV-damaged template for DNA synthesis. DNA thus synthesized is of low molecular weight, as shown by sedimentation in alkaline sucrose gradients. It is therefore suggested that SSB actively participates in the replisome translocation past dimers and/or the initiation of new DNA chains downstream of these lesions.

Overproduction of single-stranded DNA-binding protein increases UV-induced mutagenesis in Escherichia coli

UV-induced mutagenesis was investigated in the uvrB strain and its isogenic counterpart overproducing the single-stranded DNA-binding protein (SSB). It was demonstrated that overproduction of SSB significantly increases the frequency of mutation. Our results indicate that such an increase might be due to certain abnormalities in induction of the SOS response (untimely and prolonged activation of the RecA protein).

The relative rate of synthesis and levels of single-stranded DNA binding protein during induction of SOS repair in Escherichia coli

Induction of the SOS response in Escherichia coli results in an increase in the relative rate of synthesis of single-stranded DNA binding protein (SSB). In contrast to RecA protein, this increase is slow and does not lead to higher SSB levels. The significance of ssb induction to SOS repair is discussed.

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.

A mechanism for rich-medium inhibition of the repair of daughter-strand gaps in the deoxyribonucleic acid of UV-irradiated Escherichia coli K12 uvrA

Ultraviolet-irradiated Escherichia coli K12 uvrA(B,C) cells show higher survival if plated on minimal growth medium (MM) rather than on rich growth medium (RM). This phenomenon has been referred to as 'minimal medium recovery' (MMR). UV-irradiated (4 J/m2) uvrA cells showed a similar rate of protein synthesis, whether incubated in MM or RM, however, they showed a severe depression in DNA synthesis when incubated in MM that lasted for about 30 min, and the normal rate of DNA synthesis was not reestablished until about 60 min after irradiation. When a sample of these same cells was switched to RM immediately after UV-irradiation, there was only a slight slowing of DNA synthesis, and the normal rate of synthesis was reestablished by 60 min. An additional mmrA mutation or growth retardation by valine blocked both this extra DNA synthesis in RM, and the inhibitory effect of RM on survival. These findings suggest that the absence of a marked delay in DNA synthesis observed in RM may be responsible for the inhibitory effect of RM on the survival of UV-irradiated excision-deficient cells. Two hypotheses, which are not mutually exclusive, are proposed and supported by data to explain why a fast rate of DNA synthesis after UV-irradiation partially inhibits postreplication repair and enhances cell lethality.

Two-dimensional electrophoretic analysis of the regulation of SOS proteins in three ssb mutants

A previously undescribed mutation in the ssb gene, which codes for a major single strand DNA binding protein essential for DNA replication, was mapped on the Escherichia coli chromosome. Three ssb mutants were analyzed under parallel physiological conditions for the induction of SOS proteins (products of recA, uvrA, and an unknown gene), the production of mutants, the induction of lambda prophage, and sensitivity to DNA damaging agents. Two-dimensional electrophoretic techniques were used to quantitate changes in the rate of synthesis of proteins. The previously unpublished position of the uvrA gene-product in the two-dimensional matrix of E. coli proteins was described. These ssb strains exhibited varying sensitivities to ultraviolet irradiation and methylmethane sulfonate that correlated with the rate of constitutive synthesis of SOS proteins, spontaneous commitment to virulent growth of lambda lysogens, and elevation of endogenous mutation rates.

Repair resynthesis in Escherichia coli mutants deficient in single-stranded DNA-binding protein

A series of Escherichia coli strains deficient in single-stranded DNA-binding protein (SSB) and DNA polymerase I was constructed in order to analyze the effects of these mutations on DNA repair resynthesis after UV-irradiation. Since SSB has been suggested to play a role in protecting single-stranded regions which may transiently exist during excision repair and since long single-stranded regions are believed to occur frequently as repair intermediates in strains deficient in DNA polymerase I, studies of repair resynthesis and strand rejoining were performed on strains containing both the ssb-1 and polA1 mutations. Repair resynthesis appears to be slightly decreased in the ssb-1 strain at 42 degrees C relative to the wild-type; however, this effect is not enhanced in a polA1 derivative of this strain. After UV-irradiation, the single-strand molecular weight of the DNA of an ssb-1 strain decreases and fails to recover to normal size. These results are discussed in the context of long patch repair as an inducible component of repair resynthesis and of the protection of intermediates in the excision repair process by SSB. A direct role for SSB in repair resynthesis involving modulation of the proteins involved in this mode of DNA synthesis (particularly stimulation of DNA polymerase II) is not supported by our findings.

A common regulatory region shared by divergently transcribed genes of the Escherichia coli SOS system

The Escherichia coli single-stranded DNA binding protein (SSB) is implicated in DNA replication, recombination and repair. On the chromosome, the ssb gene is located adjacent to the excision repair gene uvrA, but the two genes are transcribed in opposite directions. uvrA has been shown to be part of the E. coli SOS system by introducing Mud(Ap, lac) insertions distal to the regulatory region of the gene in the chromosome. Recent investigations suggest that SSB is also involved in the SOS response. However, because the SSB protein is essential to the cell, the inducibility of the ssb gene cannot be investigated by the insertion method. Therefore, we used plasmids harbouring the regulatory region of ssb fused to the galK structural gene, while leaving an intact ssb gene in the chromosome. We show here that expression of the ssb gene is dependent on two promoters of which one is damage inducible. Evidence is presented that the divergently transcribed ssb and uvrA genes are controlled by a common LexA binding site.

Interaction of single-strand binding protein and RecA protein at the single-stranded DNA site

Escherichia coli single-strand binding protein (SSB), which participates in DNA replication, also plays a role in DNA repair and induction of SOS functions. We show that the formation of RecA-dATP-single-stranded DNA complexes is influenced by the presence of SSB. In equilibrium reactions with limiting bacteriophage fd DNA, the mutant SSB113 protein competes more effectively than SSB with RecA protein for sites on the DNA. This result can account for the inability of strain ssb113 to amplify RecA protein synthesis and induce lambda prophage. SSB fails to displace RecA protein completely, even at very high concentrations. Both proteins inhibit the dATPase activity of RecA protein in spite of a large proportion of RecA protein still complexed to single-stranded DNA. Analysis of the multiple RecA protein activities and how they respond to the presence of SSB suggests that they fall into two distinct classes. Those that are enhanced by SSB (proteolysis and strand assimilation) and those inhibited by SSB (NTPase, reannealing of complementary single-stranded DNA). We propose a two-state model of conformational change of RecA protein, affected by the number of available free bases in single-stranded DNA relative to the number of RecA monomers, that would explain the choice of mutually exclusive catalytic activities.

F sex factor of Escherichia coli K-12 codes for a single-stranded DNA binding protein

In Escherichia coli K-12 strains that carry the mutation ssb-1 in the gene for single-stranded DNA binding protein, the presence of the F sex factor partially reverses the temperature-sensitive growth phenotype caused by the mutation. The region of F (EcoRI fragment 3) responsible for this compensation has been identified and subcloned onto pBR322. A BamHI cleavage site has been found to intersect the essential coding region for this F function. By using this site, mutational blocks in the function have been constructed and used to identify a protein product (Mr approximately 22,000, slightly larger than the E. coli K-12 single-stranded DNA binding protein) which is correlated with the ssb-1-complementing activity. Labeled extracts from maxicells were used to show that this protein binds tightly to single-stranded DNA. The gene on F that codes for this protein is denoted ssf and is located at approximately 55.2 kilobases on the standard map of F, in the region transferred very early during bacterial conjugation.

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.

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

Certain strains suppress the temperature-sensitivity caused by ssb-1, which encodes a mutant ssDNA binding protein (SSB). At 42 degrees C, such strains are extremely UV-sensitive, degrade their DNA extensively after UV irradiation, and are deficient in UV mutability and UV induction of recA protein synthesis. We transduced recC22, which eliminates Exonuclease V activity, and recAo281, which causes operator-constitutive synthesis of recA protein, into such an ssb-1 strain. Both double mutants degraded their DNA extensively at 42 degrees C after UV irradiation, and both were even more UV-sensitive than the ssb-1 single mutant. We conclude that one or more nucleases other than Exonuclease V degrades DNA in the ssb recC strain, and that recA protein, even if synthesized copiously, can function efficiently in recombinational DNA repair and in control of post-UV DNA degradation only if normal SSB is also present. Pretreatment with nalidixic acid at 30 degrees C restored normal UV mutability at 42 degrees C, but did not increase UV resistance, in an ssb-1 strain. Another ssb allele, ssb-113, which blocks SOS induction at 30 degrees C, increases spontaneous mutability more than tenfold. The ssb-113 allele was transduced into the SOS-constitutive recA730 strain SC30. This double mutant expressed the same elevated spontaneous and UV-induced mutability at 30 degrees C as the ssb+ recA730 strain, and was three times more UV-resistant than its ssb-113 recA+ parent. We conclude that ssb-1 at 42 degrees C and ssb-113 at 30 degrees C block UV-induced activation of recA protease, but that neither allele interferes with subsequent steps in SOS-mediated mutagenesis.

Amplification of ssb-1 mutant single-stranded DNA-binding protein in Escherichia coli

The ssb-1 gene encoding a mutant Escherichia coli single-stranded DNA-binding protein has been cloned into plasmid pACYC184. The amount of overproduction of the cloned ssb-1 gene is dependent upon its orientation in the plasmid. In the less efficient orientation, 25-fold more mutant protein is produced than in strains carrying only one (chromosomal) copy of the gene; the other orientation results in more than 60-fold overproduction of this protein. Analysis of the effects of overproduction of the ssb-1 encoded protein has shown that most of the deficiencies associated with the ssb-1 mutation when present in single gene copy, including temperature-sensitive conditional lethality and deficiencies in amplified synthesis of RecA protein and ultraviolet light-promoted induction of prophage lambda +, are reversed by increased production of ssb-1 mutant protein. These results provide evidence in vivo that SSB protein plays an active role in recA-dependent processes. Homogenotization of a nearby genetic locus (uvrA) was identified in the cloning of the ssb-1 mutant gene. This observation has implications in the analysis of uvrA- mutant strains and will provide a means of transferring ssb- mutations from plasmids to the chromosome. On a broader scale, the observation may provide the basis of a general strategy to transfer mutations between plasmids and chromosomes.

Suppression of the ssb-1 and ssb-113 mutations of Escherichia coli by a wild-type rep gene, NaCl, and glucose

The ssb-1 mutation confers severe temperature sensitivity and UV sensitivity on many strains of Escherichia coli K-12 and C, including strain C1412. However, ssb-1 confers only slight temperature sensitivity and slight UV sensitivity on strain C1a, suggesting that strain C1a contains extragenic suppressors of ssb-1. We found that introduction of the wild-type rep gene from C1a into strain C1412 ssb-1 gave strong suppression of temperature sensitivity and moderate suppression of UV sensitivity. Also, the C1a rep+ gene mildly suppressed the temperature sensitivity conferred by the ssb-113 mutation, formerly called lexC113. Suppression of the C1412 ssb-1 growth defect by C1a rep+ rendered the cells Gro- for phi X174. In contrast to the positive suppression of ssb-1 and ssb-113 by a wild-type rep gene, mutant rep alleles enhanced the severity of the ssb-1 defect, with several C1a ssb-1 double mutants being either more temperature sensitive or more UV sensitive than C1a ssb-1, depending on which mutant rep allele was used. As a control, the same rep alleles in combination with a dnaB mutation gave an allele-independent increase in temperature sensitivity. Our results on suppression of ssb-1 by rep and on the role of the genetic background in this suppression suggested that the rep and ssb proteins interact to form a subcomplex of the total DNA replication complex and that this subcomplex has some function in repair. The effects of NaCl and glucose on suppression of both the temperature sensitivity and the UV sensitivity conferred by ssb-1 and ssb-113 are described. The degree of suppression of temperature sensitivity by salt or glucose was dependent on the source of the wild-type rep allele, as well as on the genetic background.

Effects of the ssb-1 and ssb-113 mutations on survival and DNA repair in UV-irradiated delta uvrB strains of Escherichia coli K-12

The molecular defect in DNA repair caused by ssb mutations (single-strand binding protein) was studied by analyzing DNA synthesis and DNA double-strand break production in UV-irradiated Escherichia coli delta uvrB strains. The presence of the ssb-113 mutation produced a large inhibition of DNA synthesis and led to the formation of double-strand breaks, whereas the ssb-1 mutation produced much less inhibition of DNA synthesis and fewer double-strand breaks. We suggest that the single-strand binding protein plays an important role in the replication of damaged DNA, and that it functions by protecting single-stranded parental DNa opposite daughter-strand gaps from nuclease attack.