Stabilization of recA protein-ssDNA complexes by the single-stranded DNA binding protein of Escherichia coli

In vitro recombination reactions promoted by the recA protein of Escherichia coli are enhanced by the single-stranded DNA binding protein (SSB). SSB affects the assembly of the filamentous complexes between recA protein and ssDNA that are the active form of the recA protein. Here, we present evidence that SSB plays a complex role in maintaining the stability and activity of recA-ssDNA filaments. Results of ATPase, nuclease protection, and DNA strand exchange assays suggest that the continuous presence of SSB is required to maintain the stability of recA-ssDNA complexes under reaction conditions that support their recombination activity. We also report data that indicate that there is a functional distinction between the species of SSB present at 10 mM magnesium chloride, which enhances recA-ssDNA binding, and a species present at 1 mM magnesium chloride, which displaces recA protein from ssDNA. These results are discussed in the context of current models of SSB conformation and of SSB action in recombination activities of the recA protein.     

ADP-mediated dissociation of stable complexes of recA protein and single-stranded DNA

The complete exchange of strands between circular single-stranded and full length linear duplex DNAs promoted by the recA protein of Escherichia coli is dependent upon the hydrolysis of ATP and is strongly stimulated by the single-stranded DNA binding protein (SSB). In the presence of SSB, stable complexes of recA protein and single-stranded DNA are formed as an early step in the reaction. These complexes dissociate when the ADP/ATP ratio approaches a value of 0.6-1.5, depending upon reaction conditions. Thus, ATP hydrolysis never proceeds to completion but stops when 40-60% of the input ATP has undergone hydrolysis. recA protein can participate in a second round of strand exchange upon regeneration of the ATP. While 100-200 mol of ATP are hydrolyzed/mol of heteroduplex base pair formed under standard reaction conditions in the presence of SSB, this value is reduced to 16 at levels of ADP lower than that required to dissociate the complexes. ATP hydrolysis appears to be completely irreversible since efforts to detect exchange reactions using 18O probes have been unsuccessful.     

A postsynaptic role for single-stranded DNA-binding protein in recA protein-promoted DNA strand exchange.

The single-stranded DNA-binding protein (SSB protein) is required for efficient genetic recombination in vivo. One function for SSB protein in DNA strand exchange in vitro is to remove secondary structure from single-stranded DNA (ssDNA) and thereby aid in the formation of recA protein-saturated presynaptic complexes. In the preceding paper (Lavery, P. E., and Kowalczykowski, S. C. (1992) J. Biol. Chem. 267, 9307-9314) we demonstrated that DNA strand exchange can occur in the presence of volume-occupying agents at low magnesium ion concentration, where secondary structures are reduced. Our results suggest that SSB protein is not acting during presynapsis under these conditions, yet the DNA strand exchange reaction is stimulated by the addition of SSB protein. In this study we present biochemical evidence which suggests that SSB protein stimulates DNA strand exchange by binding to the ssDNA displaced from joint molecules, thereby stabilizing them and allowing branch migration to extend the region of heteroduplex DNA. Therefore, our results indicate dual roles for SSB protein at elevated magnesium ion concentration; it functions during presynapsis, removing secondary structure from ssDNA, as indicated previously, and it also functions postsynaptically, binding to the ssDNA displaced from joint molecules.     

recA protein promoted DNA strand exchange

recA protein and circular single-stranded DNA form a stable complex in the presence of single-stranded DNA binding protein (SSB), in which one recA protein monomer is bound per two nucleotides of DNA. These complexes are kinetically significant intermediates in the exchange of strands between the single-stranded DNA and an homologous linear duplex. After completion of strand exchange, the recA protein remains tightly associated with the circular duplex product of the reaction and the SSB is bound to the displaced linear single strand. Upon addition of ADP, the recA protein-duplex DNA complex dissociates. RecA protein also interacts with single-stranded DNA in the absence of SSB; however, the amount of recA protein bound is substantially reduced. These findings provide direct physical evidence for the participation of SSB in the formation of the recA protein-single-stranded DNA complexes inferred earlier from kinetic analysis. Moreover, they confirm the ability of recA protein to equilibrate between bound and free forms in the absence of SSB.     

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.     

Biochemical properties of the Escherichia coli recA430 protein. Analysis of a mutation that affects the interaction of the ATP-recA protein complex with single-stranded DNA

The biochemical properties of the recA430 protein have been examined and compared to those of wild-type recA protein. We find that, while the recA430 protein possesses ssDNA-dependent rATP activity, this activity is inhibited by the Escherichia coli single-stranded DNA binding protein (SSB protein) under many conditions that enhance wild-type recA protein rATPase hydrolysis. Stimulation of rATPase activity by SSB protein is observed only at high concentrations of both rATP (greater than 1 mM) and recA430 protein (greater than 5 microM). In contrast, stimulation of ssDNA-dependent dATPase activity by SSB protein is less sensitive to protein and nucleotide concentration. Consistent with the nucleotide hydrolysis data, recA430 protein can carry out DNA strand exchange in the presence of either rATP or dATP. However, in the presence of rATP, both the rate and the extent of DNA strand exchange by recA430 protein are greatly reduced compared to wild-type recA protein and are sensitive to recA430 protein concentration. This reduction is presumably due to the inability of recA430 protein to compete with SSB protein for ssDNA binding sites under these conditions. The cleavage of lexA repressor protein by recA430 protein is also sensitive to the nucleotide cofactor present and is completely inhibited by SSB protein when rATP is the cofactor but not when dATP is used. Finally, the steady-state affinity and the rate of association of the recA430 protein-ssDNA complex are reduced, suggesting that the mutation affects the interaction of the ATP-bound form of recA protein with ssDNA. This alteration is the likely molecular defect responsible for inhibition of recA430 protein rATP-dependent function by SSB protein. The biochemical properties observed in the presence of dATP and SSB protein, i.e. the reduced levels of both DNA strand exchange activity and cleavage of lexA repressor protein, are consistent with the phenotypic behavior of recA430 mutations.     

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.     

Enhancement of recA protein-promoted DNA strand exchange activity by volume-occupying agents.

To investigate the in vivo effects of macromolecular crowding we examined the effect of inert macromolecules such as polyvinyl alcohol and polyethylene glycol on the in vitro activity of recA protein. The addition of either of these volume-occupying agents enables recA protein to promote homologous pairing and exchange of DNA strands at an otherwise nonpermissive magnesium ion concentration. In the presence of these macromolecules, both the rate of recA protein association with single-stranded DNA (ssDNA) and the steady-state affinity of recA protein for ssDNA are increased. Consequently, the ability of recA protein to compete with ssDNA-binding protein (SSB protein) is enhanced, and the inhibitory effects of SSB protein on the formation of recA protein-ssDNA presynaptic complexes are eliminated. Because the ability of recA protein to bind to ssDNA-containing secondary structures is also enhanced in volume-occupied solution, joint molecule formation is not greatly reduced when SSB protein is omitted from the reaction. Thus, increased recA protein interactions with ssDNA contribute to enhanced presynaptic complex formation. In addition, polyvinyl alcohol and polyethylene glycol must also affect another property of recA protein, i.e. self-association, which is required for synapsis and DNA strand exchange. Our examination of DNA strand exchange in the presence of volume-occupying agents helps to reconcile the requirement for elevated magnesium ion concentrations in recA protein-promoted recombination reactions in vitro, with a presumably low magnesium ion concentration in vivo.     

Purification and characterization of the single-stranded DNA binding protein from Streptococcus pneumoniae

The Escherichia coli single-stranded DNA binding (SSB) protein is a non-sequence-specific DNA binding protein that functions as an accessory factor for the RecA protein-promoted three-strand exchange reaction. An open reading frame encoding a protein similar in size and sequence to the E. coli SSB protein has been identified in the Streptococcus pneumoniae genome. The open reading frame has been cloned, an overexpression system has been developed, and the protein has been purified to greater than 99% homogeneity. The purified protein binds to ssDNA in a manner similar to that of the E. coli SSB protein. The protein also stimulates the S. pneumoniae RecA protein and E. coli RecA protein-promoted strand exchange reactions to an extent similar to that observed with the E. coli SSB protein. These results indicate that the protein is the S. pneumoniae analog of the E. coli SSB protein. The availability of highly-purified S. pneumoniae SSB protein will facilitate the study of the molecular mechanisms of RecA protein-mediated transformational recombination in S. pneumoniae.     

Reversibility of strand invasion promoted by recA protein and its inhibition by Escherichia coli single-stranded DNA-binding protein or phage T4 gene 32 protein

When recA protein promotes homologous pairing and strand exchange involving circular single strands and linear duplex DNA, the protein first polymerizes on the single-stranded DNA to form a nucleoprotein filament which then binds naked duplex DNA to form nucleoprotein networks, the existence of which is independent of homology, but requires the continued presence of recA protein (Tsang, S. S., Chow, S. A., and Radding, C. M. (1985) Biochemistry 24, 3226-3232). Further experiments revealed that within a few minutes after the beginning of homologous pairing and strand exchange, these networks began to be replaced by a distinct set of networks with inverse properties: their formation depended upon homology, but they survived removal of recA protein by a variety of treatments. Formation of this second kind of network required that homology be present specifically at the end of the linear duplex molecule from which strand exchange begins. Escherichia coli single-stranded DNA-binding protein or phage T4 gene 32 protein largely suppressed the formation of this second population of networks by inactivating the newly formed heteroduplex DNA, which, however, could be reactivated when recA protein was dissociated by incubation at 0 degrees C. We interpret these observations as evidence of reinitiation of strand invasion when recA protein acts in the absence of auxiliary helix-destabilizing proteins. These observations indicate that the nature of the nucleoprotein products of strand exchange determines whether pairing and strand exchange are reversible or not, and they further suggest a new explanation for the way in which E. coli single-stranded DNA-binding protein and gene 32 protein accelerate the apparent forward rate of strand exchange promoted by recA protein, namely by suppressing initiation of the reverse reaction.     

Exchange of recA protein between adjacent recA protein-single-stranded DNA complexes

We have examined the exchange of recA protein between stable complexes formed with single-stranded DNA (ssDNA) and (a) other complexes and (b) a pool of free recA protein. We have also examined the relationship of ATP hydrolysis to these exchange reactions. Exchange was observed between two different recA X ssDNA complexes in the presence of ATP. Complete equilibration between two sets of complexes occurred with a t1/2 of 3-7 min under a set of conditions previously found to be optimal for recA protein-promoted DNA strand exchange. Approximately 200 ATPs were hydrolyzed for every detected migration of a recA monomer from one complex to another. This exchange occurred primarily between adjacent complexes, however. Little or no exchange was observed between recA X ssDNA complexes and the free recA protein pool, even after several hundred molecules of ATP had been hydrolyzed for every recA monomer present. ATP hydrolysis is not coupled to complete dissociation or association of recA protein from or with recA X ssDNA complexes under these conditions.     

Biochemical and biological function of Escherichia coli RecA protein: behavior of mutant RecA proteins

The recA protein of E coli participates in several diverse biological processes and promotes a variety of complex in vitro reactions. A careful comparison of the phenotypic behavior of E coli recA mutations to the biochemical properties of the corresponding mutant proteins reveals a close parallel both between recombination phenotype and DNA strand exchange and renaturation activities, and between inducible phenomena and repressor cleavage activity. The biochemical alterations manifest by the mutant recA proteins are reflected in the strength of their interaction with ssDNA. The defective mutant recA proteins fail to properly assume the high-affinity DNA-binding state that is characteristic of the wild-type protein and, consequently, form less stable complexes with DNA. The mutant proteins displaying an 'enhanced' activity bind ssDNA with approximately the same affinity as the wild-type protein but, due to altered protein-protein interactions, they associate more rapidly with ssDNA. These changes proportionately affect the ability of recA protein to compete with SSB protein, to interact with dsDNA, and, perhaps, to bind repressor proteins. In turn, the DNA strand exchange, DNA renaturation, and repressor cleavage activities mirror these modifications.     

The homologous recombination system of phage lambda. Pairing activities of beta protein

The red genes of phage lambda specify two proteins, exonuclease and beta protein, which are essential for its general genetic recombination in recA- cells. These proteins seem to occur in vivo as an equimolar complex. In addition, beta protein forms a complex with another polypeptide, probably of phage origin, of Mr 70,000. The 70-kDa protein appears to be neither a precursor nor an aggregated form of either exonuclease or beta protein, since antibodies directed against the latter two proteins failed to react with 70-kDa protein on Ouchterlony double diffusion analysis. beta protein promotes Mg2+-dependent renaturation of complementary strands (Kmiec, E., and Holloman, W. K. (1981) J. Biol. Chem. 256, 12636-12639). To look for other pairing activities of beta protein, we developed methods of purification to free it of associated exonuclease. Exonuclease-free beta protein appeared unable to cause the pairing of a single strand with duplex DNA; however, like Escherichia coli single strand binding protein (SSB), beta protein stimulated formation of joint molecules by recA protein from linear duplex DNA and homologous circular single strands. Like recA protein, but unlike SSB, beta protein promoted the joining of the complementary single-stranded ends of phage lambda DNA. beta protein specifically protected single-stranded DNA from digestion by pancreatic DNase. The half-time for renaturation catalyzed by beta protein was independent of DNA concentration, unlike renaturation promoted by SSB and spontaneous renaturation, which are second order reactions. Thus, beta protein resembles recA protein in its ability to bring single-stranded DNA molecules together and resembles SSB in its ability to reduce secondary structure in single-stranded DNA.     

RecA protein of Mycobacterium tuberculosis possesses pH-dependent homologous DNA pairing and strand exchange activities: implications for allele exchange in mycobacteria

To gain insights into inefficient allele exchange in mycobacteria, we compared homologous pairing and strand exchange reactions promoted by RecA protein of Mycobacterium tuberculosis to those of Escherichia coli RecA protein. The extent of single-stranded binding protein (SSB)-stimulated formation of joint molecules by MtRecA was similar to that of EcRecA over a wide range of pH values. In contrast, strand exchange promoted by MtRecA was inhibited around neutral pH due to the formation of DNA networks. At higher pH, MtRecA was able to overcome this constraint and, consequently, displayed optimal strand exchange activity. Order of addition experiments suggested that SSB, when added after MtRecA, was vital for strand exchange. Significantly, with shorter duplex DNA, MtRecA promoted efficient strand exchange without network formation in a pH-independent fashion. Increase in the length of duplex DNA led to incomplete strand exchange with concomitant rise in the formation of intermediates and networks in a pH-dependent manner. Treatment of purified networks with S1 nuclease liberated linear duplex DNA and products, consistent with a model in which the networks are formed by the invasion of hybrid DNA by the displaced linear single-stranded DNA. Titration of strand exchange reactions with ATP or salt distinguished a condition under which the formation of networks was blocked, but strand exchange was not significantly affected. We discuss how these results relate to inefficient allele exchange in mycobacteria.     

Active nucleoprotein filaments of single-stranded binding protein and recA protein on single-stranded DNA have a regular repeating structure.

When E. coli single-stranded DNA binding protein (SSB) coats single-stranded DNA (ssDNA) in the presence of 1 mM MgCl2 it inhibits the subsequent binding of recA protein, whereas SSB binding to ssDNA in 12 mM MgCl2 promotes the binding of recA protein. These two conditions correspond respectively to those which produce 'smooth' and 'beaded' forms of ssDNA-SSB filaments. By gel filtration and immunoprecipitation we observed active nucleoprotein filaments of recA protein and SSB on ssDNA that contained on average 1 monomer of recA protein per 4 nucleotides and 1 monomer of SSB per 20-22 nucleotides. Filaments in such a mixture, when digested with micrococcal nuclease produced a regular repeating pattern, approximately every 70-80 nucleotides, that differed from the pattern observed when only recA protein was bound to the ssDNA. We conclude that the beaded ssDNA-SSB nucleoprotein filament readily binds recA protein and forms an intermediate that is active in the formation of joint molecules and can retain substantially all of the SSB that was originally bound.     

Investigation of binding between recA protein and single-stranded polynucleotides with the aid of a fluorescent deoxyribonucleic acid derivative

The availability of epsilon DNA, a fluorescent ssDNA derivative, has made it possible to examine quantitatively the interactions between recA protein and single-stranded polynucleotides. Fluorescence titrations of epsilon DNA with recA protein and vice versa establish that each recA protein monomer covers 5.5 epsilon DNA nucleotides and that the dissociation constant of the recA-epsilon DNA complex is 10 nM. Fluorescence titrations of recA protein-epsilon DNA mixtures with poly(dT) establish that each recA protein monomer covers 5.1 poly(dT) nucleotides and that the dissociation constant of the recA-poly(dT) complex is 0.03 nM. Observations on how the addition of ssDNA affects the fluorescence of recA protein-epsilon DNA mixtures establish that the dissociation constant of the recA-ssDNA complex exceeds 20 microM. Stopped-flow kinetics in which excess recA protein binds to epsilon DNA indicate that k2 = 6 X 10(6) M-1 s-1 for the process. A more approximate kinetic technique indicates that recA protein binds to epsilon DNA at least one-tenth as fast as to poly(dT); the rate constant for dissociation of recA-epsilon DNA exceeds that for recA-poly(dT) by at least 30-fold. epsilon DNA is proven to be a versatile reagent for studying single-stranded polynucleotide-protein interactions. Not only can its own complexes with protein be investigated but also, under suitable circumstances, it can be used as a fluorescent probe to explore complexes incorporating nonfluorescent polynucleotides.     

Effects of various single-stranded-DNA-binding proteins on reactions promoted by RecA protein

To relate the roles of Escherichia coli SSB in recombination in vivo and in vitro, we have studied the mutant proteins SSB-1 and SSB-113, the variant SSBc produced by chymotryptic cleavage, the partially homologous variant F SSB (encoded by the E. coli sex factor), and the protein encoded by gene 32 of bacteriophage T4. All of these, with the exception of SSB-1, augmented both the initial rate of homologous pairing and strand exchange promoted by RecA protein. From these and related observations, we conclude that SSB stimulates the initial formation of joint molecules by nonspecifically promoting the binding of RecA protein to single-stranded DNA; that SSB plays no role in synapsis of the RecA nucleoprotein filament with duplex DNA; that stimulation of strand exchange by SSB is similarly nonspecific; and that all members of the class of proteins represented by SSB, F SSB, and gene 32 protein may play equivalent roles in making single-stranded DNA more accessible to RecA protein.     

Visualization of recA protein and its association with DNA: a priming effect of single-strand-binding protein

A stoichiometric interaction of RecA protein with single-stranded DNA promotes homologous pairing of the single strand with duplex DNA and subsequent polar formation of a heteroduplex joint. Escherichia coli single-strand-binding (SSB) protein augments these reactions. Electron microscopic observations suggest structural bases for these interactions. Without triphosphates or DNA, RecA protein forms short linear filaments. With added circular single-stranded DNA, it forms extended circular filaments as well as collapsed and aggregated complexes of protein and DNA. The extended circular filaments are stiff and regular in appearance, contrasting with the convoluted structure formed by SSB protein and single-stranded DNA. Together, these two proteins form mixed filaments, which mostly resemble the extended structures containing RecA protein; moreover, SSB protein accelerates formation of extended filaments more than 50-fold, increasing the yield of these structures at the expense of heterogeneous aggregates. Other observations further define the interactions of RecA protein with partially single-stranded DNA, and the effects of ATP gamma S on the tendency of RecA protein to form polymeric structures even in the absence of DNA.     

Effects of the Escherichia coli SSB protein on the binding of Escherichia coli RecA protein to single-stranded DNA. Demonstration of competitive binding and the lack of a specific protein-protein interaction

The effect of the Escherichia coli single-stranded DNA binding (SSB) protein on the stability of complexes of E. coli RecA protein with single-stranded DNA has been investigated through direct DNA binding experiments. The effect of each protein on the binding of the other to single-stranded DNA, and the effect of SSB protein on the transfer rate of RecA protein from one single-stranded DNA molecule to another, were studied. The binding of SSB protein and RecA protein to single-stranded phage M13 DNA is found to be competitive and, therefore, mutually exclusive. In the absence of a nucleotide cofactor, SSB protein binds more tightly to single-stranded DNA than does RecA protein, whereas in the presence of ATP-gamma-S, RecA protein binds more tightly than SSB protein. In the presence of ATP, an intermediate result is obtained that depends on the type of DNA used, the temperature, and the magnesium ion concentration. When complexes of RecA protein, SSB protein and single-stranded M13 DNA are formed under conditions of slight molar excess of single-stranded DNA, no effect of RecA protein on the equilibrium stability of the SSB protein-single-stranded DNA complex is observed. Under similar conditions, SSB protein has no observed effect on the stability of the RecA protein-etheno M13 DNA complex. Finally, measurements of the rate of RecA protein transfer from RecA protein-single-stranded DNA complexes to competing single-stranded DNA show that there is no kinetic stabilization of the RecA protein-etheno M13 DNA complex by SSB protein, but that a tenfold stabilization is observed when single-stranded M13 DNA is used to form the complex. However, this apparent stabilizing effect of SSB protein can be mimicked by pre-incubation of the RecA protein-single-stranded M13 DNA complex in low magnesium ion concentration, suggesting that this effect of SSB protein is indirect and is mediated through changes in the secondary structure of the DNA. Since no direct effect of SSB protein is observed on either the equilibrium or dissociation properties of the RecA protein-single-stranded DNA complex, it is concluded that the likely effect of SSB protein in the strand assimilation reaction is on a slow step in the association of RecA protein with single-stranded DNA. Direct evidence for this conclusion is presented in the accompanying paper.     

Effects of overproduction of single-stranded DNA-binding protein on RecA protein-dependent processes in Escherichia coli

Overproduction of single-stranded DNA-binding protein (SSB) in Escherichia coli led to a decrease in the basal level of repressor LexA. Expression of the LexA-controlled genes was increased differentially, depending on the affinity of the LexA repressor for each promoter: expression of the recA and sfiA genes was increased 5-fold and 1.5-fold, respectively. Despite only a slight effect on expression of sfiA, which codes for an inhibitor of cell division, bacteria overproducing SSB produced elongated cells. In fact, the effect on cell shape appeared to be essentially independent of the expression of the sfiA and recA genes. Bacteria overproducing SSB were therefore phenotypically similar to bacteria partially starved of thymine, in which filamentation results from both sfiA-dependent and sfiA-recA-independent pathways. These data indicate that excess SSB acts primarily by perturbing DNA replication, thereby favoring gratuitous activation of RecA protein to promote cleavage of LexA protein. When bacteria overproducing SSB were exposed to a DNA-damaging agent such as ultraviolet light or mitomycin C, the recA and sfiA genes were fully induced. Induction of the sfiA gene occurred, however, at higher doses in bacteria overproducing SSB protein than in bacteria with normal levels of SSB. Whereas the efficiency of excision repair was apparently increased by excess SSB, the efficiency of post-replication recombinational repair was reduced as judged by a decrease in the recombination proficiency between a prophage and ultraviolet-irradiated heteroimmune infecting phage. Following induction of ssb+ bacteria with mitomycin C, the cellular content of SSB was slightly increased. These results provide evidence that SSB modulates RecA protein-dependent activities in vivo. It is proposed that SSB favors the formation of short complexes of RecA protein and single-stranded DNA that mediate cleavage of the LexA and lambda repressors, while it delays the formation of long nucleoprotein filaments, thereby slowing down RecA-promoted recombinational events in uninduced as well as in induced bacteria.