The product of the lexC gene of Escherichia coli is single-stranded DNA-binding protein

Molecular insights into the prototypical single-stranded DNA-binding protein from E. coli

The SSB protein of Escherichia coli functions to bind single-stranded DNA wherever it occurs during DNA metabolism. Depending upon conditions, SSB occurs in several different binding modes. In the course of its function, SSB diffuses on ssDNA and transfers rapidly between different segments of ssDNA. SSB interacts with many other proteins involved in DNA metabolism, with 22 such SSB-interacting proteins, or SIPs, defined to date. These interactions chiefly involve the disordered and conserved C-terminal residues of SSB. When not bound to ssDNA, SSB can aggregate to form a phase-separated biomolecular condensate. Current understanding of the properties of SSB and the functional significance of its many intermolecular interactions are summarized in this review.

Interaction with the carboxy-terminal tip of SSB is critical for RecG function in E. coli

In Escherichia coli, the single-stranded DNA-binding protein (SSB) acts as a genome maintenance organizational hub by interacting with multiple DNA metabolism proteins. Many SSB-interacting proteins (SIPs) form complexes with SSB by docking onto its carboxy-terminal tip (SSB-Ct). An alternative interaction mode in which SIPs bind to PxxP motifs within an intrinsically-disordered linker (IDL) in SSB has been proposed for the RecG DNA helicase and other SIPs. Here, RecG binding to SSB and SSB peptides was measured in vitro and the RecG/SSB interface was identified. The results show that RecG binds directly and specifically to the SSB-Ct, and not the IDL, through an evolutionarily conserved binding site in the RecG helicase domain. Mutations that block RecG binding to SSB sensitize E. coli to DNA damaging agents and induce the SOS DNA-damage response, indicating formation of the RecG/SSB complex is important in vivo. The broader role of the SSB IDL is also investigated. E. coli ssb mutant strains encoding SSB IDL deletion variants lacking all PxxP motifs retain wildtype growth and DNA repair properties, demonstrating that the SSB PxxP motifs are not major contributors to SSB cellular functions.

Mechanism of Exonuclease I stimulation by the single-stranded DNA-binding protein

Bacterial single-stranded (ss) DNA-binding proteins (SSBs) bind and protect ssDNA intermediates formed during cellular DNA replication, recombination and repair reactions. SSBs also form complexes with an array of genome maintenance enzymes via their conserved C-terminal tail (SSB-Ct) elements. In many cases, complex formation with SSB stimulates the biochemical activities of its protein partners. Here, we investigate the mechanism by which Escherichia coli SSB stimulates hydrolysis of ssDNA by Exonuclease I (ExoI). Steady-state kinetic experiments show that SSB stimulates ExoI activity through effects on both apparent k_cat and K_m. SSB variant proteins with altered SSB-Ct sequences either stimulate more modestly or inhibit ExoI hydrolysis of ssDNA due to increases in the apparent Michaelis constant, highlighting a role for protein complex formation in ExoI substrate binding. Consistent with a model in which SSB stabilizes ExoI substrate binding and melts secondary structures that could impede ExoI processivity, the specific activity of a fusion protein in which ExoI is tethered to SSB is nearly equivalent to that of SSB-stimulated ExoI. Taken together, these studies delineate stimulatory roles for SSB in which protein interactions and ssDNA binding are both important for maximal activity of its protein partners.

Peptide inhibitors identify roles for SSB C-terminal residues in SSB/exonuclease I complex formation

Bacterial single-stranded (ss) DNA-binding proteins (SSBs) facilitate DNA replication, recombination, and repair processes in part by recruiting diverse genome maintenance enzymes to ssDNA. This function utilizes the C-terminus of SSB (SSB-Ct) as a common binding site for SSB's protein partners. The SSB-Ct is a highly conserved, amphipathic sequence comprising acidic and hydrophobic elements. A crystal structure of Escherichia coli exonuclease I (ExoI) bound to a peptide comprising the E. coli SSB-Ct sequence shows that the C-terminal-most SSB-Ct Phe anchors the peptide to a binding pocket on ExoI and implicates electrostatic binding roles for the acidic SSB-Ct residues. Here, we use SSB-Ct peptide variants in competition experiments to examine the roles of individual SSB-Ct residues in binding ExoI in solution. Altering the C-terminal-most Pro or Phe residues in the SSB-Ct strongly impairs SSB-Ct binding to ExoI, confirming a major role for the hydrophobic SSB-Ct residues in binding ExoI. Alteration of N-terminal SSB-Ct residues leads to changes that reflect cumulative electrostatic binding roles for the Asp residues in SSB-Ct. The SSB-Ct peptides also abrogate SSB stimulation of ExoI activity through a competitive inhibition mechanism, indicating that the peptides can disrupt ExoI/SSB/ssDNA ternary complexes. Differences in the potency of the SSB-Ct peptide variants in the binding and nuclease inhibition studies indicate that the acidic SSB-Ct residues play a more prominent role in the context of the ternary complex than in the minimal ExoI/SSB-Ct interaction. Together, these data identify roles for residues in the SSB-Ct that are important for SSB complex formation with its protein partners.

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.

Resolution of converging replication forks by RecQ and topoisomerase III

RecQ-like DNA helicases pair with cognate topoisomerase III enzymes to function in the maintenance of genomic integrity in many organisms. These proteins play roles in stabilizing stalled replication forks, the S phase checkpoint response, and suppressing genetic crossovers, and their inactivation results in hyper-recombination, gross chromosomal rearrangements, chromosome segregation defects, and human disease. Biochemical activities associated with these enzymes include the ability to resolve double Holliday junctions, a process thought to lead to the suppression of crossover formation. Using Escherichia coli RecQ and topoisomerase III, we demonstrate a second activity for this pair of enzymes that could account for their role in maintaining genomic stability: resolution of converging replication forks. This resolution reaction is specific for the RecQ-topoisomerase III pair and is mediated by interaction of both of these enzymes with the single-stranded DNA-binding protein SSB.

Structural basis of Escherichia coli single-stranded DNA-binding protein stimulation of exonuclease I

Bacterial single-stranded DNA (ssDNA)-binding proteins (SSBs) play essential protective roles in genome biology by shielding ssDNA from damage and preventing spurious DNA annealing. Far from being inert, ssDNA/SSB complexes are dynamic DNA processing centers where many different enzymes gain access to genomic substrates by exploiting direct interactions with SSB. In all cases examined to date, the C terminus of SSB (SSB-Ct) forms the docking site for heterologous proteins. We describe the 2.7-A-resolution crystal structure of a complex formed between a peptide comprising the SSB-Ct element and exonuclease I (ExoI) from Escherichia coli. Two SSB-Ct peptides bind to adjacent sites on ExoI. Mutagenesis studies indicate that one of these sites is important for association with the SSB-Ct peptide in solution and for SSB stimulation of ExoI activity, whereas the second has no discernable function. These studies identify a correlation between the stability of the ExoI/SSB-Ct complex and SSB-stimulation of ExoI activity. Furthermore, mutations within SSB's C terminus produce variants that fail to stimulate ExoI activity, whereas the SSB-Ct peptide alone has no effect. Together, our findings indicate that SSB stimulates ExoI by recruiting the enzyme to its substrate and provide a structural paradigm for understanding SSB's organizational role in genome maintenance.

Trading places on DNA--a three-point switch underlies primer handoff from primase to the replicative DNA polymerase

This study reports a primase-to-polymerase switch in E. coli that closely links primase action with extension by DNA polymerase III holoenzyme. We find that primase tightly grips its RNA primer, protecting it from the action of other proteins. However, primase must be displaced before the beta sliding clamp can be assembled on the primed site. A single subunit of the holoenzyme, chi, is dedicated to this primase displacement task. The displacement mechanism depends on a third protein, SSB. Primase requires contact to SSB for its grip on the primed site. The chi subunit also binds SSB, upon which the primase-to-SSB contact is destabilized leading to dissociation of primase and assembly of beta onto the RNA primer. The conservation of this three-point switch, in which two proteins exchange places on DNA via mutually exclusive interaction with a third protein, is discussed.

Linkage map of Escherichia coli K-12, edition 10: the traditional map

This map is an update of the edition 9 map by Berlyn et al. (M. K. B. Berlyn, K. B. Low, and K. E. Rudd, p. 1715-1902, in F. C. Neidhardt et al., ed., Escherichia coli and Salmonella: cellular and molecular biology, 2nd ed., vol. 2, 1996). It uses coordinates established by the completed sequence, expressed as 100 minutes for the entire circular map, and adds new genes discovered and established since 1996 and eliminates those shown to correspond to other known genes. The latter are included as synonyms. An alphabetical list of genes showing map location, synonyms, the protein or RNA product of the gene, phenotypes of mutants, and reference citations is provided. In addition to genes known to correspond to gene sequences, other genes, often older, that are described by phenotype and older mapping techniques and that have not been correlated with sequences are included.

Identification of amino acids stabilizing the tetramerization of the single stranded DNA binding protein from Escherichia coli

Mutating the histidine at position 55 present at the subunit interface of the tetrameric E. coli single stranded DNA binding (SSB) protein to tyrosine or lysine leads to cells which are UV- and temperature-sensitive. The defects of both ssbH55Y (ssb-1) and ssbH55K can be overcome by increasing protein concentration, with the ssbH55K mutation producing a less stable, readily dissociating protein whose more severe replication and repair phenotypes were less easily ameliorated by protein amplification. In this study we selected and analyzed E. coli strains where the temperature sensitivity caused by the ssbH55K mutation was suppressed by spontaneous mutations that changed the glutamine at position 76 or 110 to leucine. Using guanidinium chloride denaturation monitored by sedimentation diffusion equilibrium experiments in the analytical ultracentrifuge, we demonstrate that the double mutant SSBH55KQ76L and SSBH55KQ110L proteins form more stable homotetramers as compared to the SSBH55K single mutant protein although they are less stable than wild-type SSB. Additionally, the single mutant proteins SSBQ76L and SSBQ110L form tetramers which are more resistant to guanidinium denaturation than wild-type SSB protein.

Tetramerization and single-stranded DNA binding properties of native and mutated forms of murine mitochondrial single-stranded DNA-binding proteins

We examined previously unexplored aspects of the tetramerization and single-stranded DNA (ssDNA) binding properties of native, precursor, and mutated forms of mitochondrial ssDNA-binding protein (mtSSB) from a mammalian organism (mouse). Tetramic forms of mtSSB reassemble spontaneously after thermal denaturation and undergo subunit exchange. Binding of mtSSB to ssDNA as a function of protein concentration is nonlinear, suggesting a concentration-dependent transition in intrinsic binding affinity and in the topology of the DNA-protein complex. The cleavable presequence at the amino terminus of the precursor form of mtSSB does not disrupt tetramer formation but has a specific inhibitory effect on DNA binding that is not seen in a fusion protein that substitutes a bulkier peptide moiety in this position. Mutated forms of mtSSB bearing amino acid substitutions at highly conserved amino acid positions exhibit subtle or severe defects in ssDNA binding activity and/or tetramerization, even when assembled into heterotetramers in combination with wild-type mtSSB monomers. These experiments provide new insights into structural and functional properties of mammalian mtSSB and have implications for the pathogenesis of human diseases resulting from defects in mtDNA replication.

Biochemistry of homologous recombination in Escherichia coli

Homologous recombination is a fundamental biological process. Biochemical understanding of this process is most advanced for Escherichia coli. At least 25 gene products are involved in promoting genetic exchange. At present, this includes the RecA, RecBCD (exonuclease V), RecE (exonuclease VIII), RecF, RecG, RecJ, RecN, RecOR, RecQ, RecT, RuvAB, RuvC, SbcCD, and SSB proteins, as well as DNA polymerase I, DNA gyrase, DNA topoisomerase I, DNA ligase, and DNA helicases. The activities displayed by these enzymes include homologous DNA pairing and strand exchange, helicase, branch migration, Holliday junction binding and cleavage, nuclease, ATPase, topoisomerase, DNA binding, ATP binding, polymerase, and ligase, and, collectively, they define biochemical events that are essential for efficient recombination. In addition to these needed proteins, a cis-acting recombination hot spot known as Chi (chi: 5'-GCTGGTGG-3') plays a crucial regulatory function. The biochemical steps that comprise homologous recombination can be formally divided into four parts: (i) processing of DNA molecules into suitable recombination substrates, (ii) homologous pairing of the DNA partners and the exchange of DNA strands, (iii) extension of the nascent DNA heteroduplex; and (iv) resolution of the resulting crossover structure. This review focuses on the biochemical mechanisms underlying these steps, with particular emphases on the activities of the proteins involved and on the integration of these activities into likely biochemical pathways for recombination.

Cloning and sequencing of the Serratia marcescens gene encoding a single-stranded DNA-binding protein (SSB) and its promoter region

The gene (ssb) coding for a single-stranded DNA-binding protein (SSB) was identified on a 1.2-kb EcoRI-SalI fragment cloned from chromosomal DNA of Serratia marcescens. The cloned fragment conferred increased resistance against UV and mitomycin C (MC) to ssb- mutants of Escherichia coli. The nucleotide (nt) sequence revealed that SSB consists of 175 amino acids (aa) and has an M(r) of 18,677. It shows 89% aa sequence homology with the SSB of E. coli. The nt sequence preceding the gene contains three promoters. Two of them overlap with a presumptive SOS box, and the distal one overlaps with a second SOS box that coincides with the promoter of the adjacent uvrA (gene encoding the UvrA protein). The uvrA is transcribed in a direction opposite to that of ssb. The sequence coding for the N terminus of the UvrA of S. marcescens indicates that the first 74 aa are identical to those of the E. coli protein. The results suggest that the two bacterial SSBs are members of a group which differs from the known SSBs of prokaryotic transmissible plasmids, because their aa sequence homology with these proteins is only about 60%.

Interaction of the heat shock protein GroEL of Escherichia coli with single-stranded DNA-binding protein: suppression of ssb-113 by groEL46

Previous studies from our laboratory have shown that an allele of the heat shock protein GroEL (groEL411) is able to specifically suppress some of the physiological defects of the single-stranded DNA-binding protein mutation ssb-1. A search for additional alleles of the groE genes which may act as suppressors for ssb mutations has led to the identification of groEL46 as a specific suppressor of ssb-113. It has very little or no effect on ssb-1 or ssb-3. All of the physiological defects of ssb-113, including temperature-sensitive growth, temperature-sensitive DNA synthesis, sensitivity to UV irradiation, methyl methanesulfonate, and bleomycin, and reduced recombinational capacity, are restored to wild-type levels. The ssb-113 allele, however, is unable to restore sensitivity of groEL46 cells to phage lambda. The mechanism of suppression of ssb-113 by groEL46 appears to differ from that of ssb-1 by groEL411. The data suggest that GroEL may interact with single-stranded DNA-binding protein in more than one domain.

Monomers of the Escherichia coli SSB-1 mutant protein bind single-stranded DNA

The Escherichia coli wild-type single strand binding (SSB) protein is a stable tetramer that binds to single-stranded (ss) DNA in its role in DNA replication, recombination and repair. The ssb-1 mutation, a substitution of tyrosine for histidine-55 within the SSB-1 protein, destabilizes the tetramer with respect to monomers, resulting in a temperature-sensitive defect in a variety of DNA metabolic processes, including replication. Using quenching of the intrinsic SSB-1 tryptophan fluorescence, we have examined the equilibrium binding of the oligonucleotide, dT(pT)15, to the SSB-1 protein in order to determine whether a ssDNA binding site exists within individual SSB-1 monomers or whether the formation of the SSB tetramer is necessary for ssDNA binding. At high SSB-1 protein concentrations, such that the tetramer is stable, we find that four molecules of dT(pT)15 bind per tetramer in a manner similar to that observed for the wild-type SSB tetramer; i.e. negative co-operativity is observed for ssDNA binding to the SSB-1 protomers. As a consequence of this negative co-operativity, binding is biphasic, with two molecules of dT(pT)15 binding to the tetramer in each phase. However, the intrinsic binding constant, K16, for the SSB-1 protomer-dT(pT)15 interaction is a factor of 3 lower than for the wild-type protomer interaction and the negative co-operativity parameter, sigma 16, is larger in the case of the SSB-1 tetramer, indicating a lower degree of negative co-operativity. At lower SSB-1 concentrations, SSB-1 monomers bind dT(pT)15 without negative co-operativity; however, the intrinsic affinity of dT(pT)15 for the monomer is a factor of approximately 10 lower than for the protomer (50 mM-NaCl, pH 8.1, 25 degrees C). Therefore, an individual SSB-1 monomer does possess an independent ssDNA binding site; hence formation of the tetramer is not required for ssDNA binding, although tetramer formation does increase the binding affinity significantly. These data also show that the negative co-operativity among ssDNA binding sites within an SSB tetramer is an intrinsic property of the tetramer. On the basis of these studies, we discuss a modified explanation for the temperature-sensitivity of the ssb-1 phenotype.

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.

Suppression of the Escherichia coli ssb-1 mutation by an allele of groEL

A series of spontaneous suppressors to the temperature-sensitive phenotype of the single-stranded DNA-binding protein mutation ssb-1 were isolated. A genomic library of EcoRI fragments from one of these suppressor strains was prepared by using pBR325 as the cloning vector. A 10.0-kilobase class of inserts was identified as carrying the ssb-1 gene itself. A second class of 8.3-kilobase inserts was shown to contain the groE region by (i) restriction analysis, (ii) Southern hybridization of the 8.3-kilobase insert to groE+ DNA, and (iii) identification of the gene products by similar migration on polyacrylamide gels. Subcloning demonstrated that an intact mutant groEL gene was necessary for suppression and that plasmids carrying the 8.3-kilobase insert could suppress mutants carrying groES- but not groEL- genes for phage lambda growth. The suppressor, designated as groEL411, was specific for the ssb-1 allele. In ssb-1 groEL411 cells, DNA synthesis stopped after a shift to 42.5 degrees C but rapidly recovered within minutes. The data suggest a direct interaction between the single-stranded DNA-binding protein and GroEL proteins in DNA replication.

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.

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.