Escherichia coli single-strand binding protein forms multiple, distinct complexes with single-stranded DNA

Four distinct binding modes for the interaction of Escherichia coli single-strand binding (SSB) protein with single-stranded (ss) DNA have been identified on the basis of quantitative titrations that monitor the quenching of the SSB protein fluorescence upon binding to the homopolynucleotide poly(dT) over a range of MgCl2 and NaCl concentrations at 25 and 37 degrees C. This is the first observation of multiple binding modes for a single protein binding to DNA. These results extend previous studies performed in NaCl (25 degrees C, pH 8.1), in which two distinct SSB-ss DNA binding modes possessing site sizes of 33 and 65 nucleotides per bound SSB tetramer were observed [Lohman, T.M., & Overman, L. B. (1985) J. Biol. Chem. 260, 3594-3603]. Each of these binding modes differs in the number of nucleotides occluded upon interaction with ss DNA (i.e., site size). Along with the previously observed modes with site sizes of 35 +/- 2 and 65 +/- 3 nucleotides per tetramer, a third distinct binding mode, at 25 degrees C, has been identified, possessing a site size of 56 +/- 3 nucleotides per bound SSB tetramer, which is stable over a wide range of MgCl2 concentrations. At 37 degrees C, a fourth binding mode is observed, possessing a site size of 40 +/- 2 nucleotides per tetramer, although this mode is observable only over a small range of salt concentration.(ABSTRACT TRUNCATED AT 250 WORDS)     

Negative cooperativity within individual tetramers of Escherichia coli single strand binding protein is responsible for the transition between the (SSB)35 and (SSB)56 DNA binding modes

We have examined the binding of the oligonucleotide dT (pT)34 to the Escherichia coli SSB protein as a function of NaCl and MgCl2 concentration (25 degrees C, pH 8.1) by monitoring the quenching of the intrinsic protein fluorescence. We find two binding sites for dT(pT)34 per single strand binding (SSB) protein tetramer, with each site possessing widely different affinities depending on the salt concentration. At 200 mM NaCl, we observe nearly stoichiometric binding of dT(pT)34 to both binding sites within the SSB tetramer, although a difference in the affinities is still apparent. However, when the NaCl concentration is lowered, the overall affinity of dT(pT)34 for the second site on the SSB tetramer decreases dramatically. At 1.5 mM NaCl, only a single molecule of dT(pT)34 can bind per SSB tetramer, even with a 10-fold molar excess of dT(pT)34. MgCl2 is effective at 100-fold lower concentrations than NaCl in promoting the binding of the second molecule of dT(pT)34. This binding behavior reflects an intrinsic property of the SSb tetramer, since it is also observed upon binding of smaller oligonucleotides, and the simplest explanation is that a salt-dependent negative cooperativity exists between DNA binding sites within the SSB tetramer. This phenomenon is also responsible for the transition between the two SSB-single strand (ss) polynucleotide binding modes that cover 35 and 56 nucleotides per tetramer [Bujalowski, W., & Lohman, T. M. (1986) Biochemistry 25, 7799-7802]. Extreme negative cooperativity stabilizes the (SSB)35 binding mode, in which the SSB tetramer binds tightly to ss DNA with only two of its subunits while the other two subunits remain unligated.(ABSTRACT TRUNCATED AT 250 WORDS)     

Binding mode transitions of Escherichia coli single strand binding protein-single-stranded DNA complexes. Cation, anion, pH, and binding density effects

We have extended our investigations of the multiple binding modes that form between the Escherichia coli single strand binding (SSB) protein and single-stranded DNA (Lohman, T. M. & Overman, L. B. (1985) J. Biol. Chem. 260, 3594-3603; Bujalowski, W. & Lohman, T. M. (1986) Biochemistry 25, 7799-7802) by examining the effects of anions, pH, BaCl2, and protein binding density on the transitions among these binding modes. "Reverse" titrations that monitor the quenching of the intrinsic tryptophan fluorescence of the SSB protein upon addition of poly(dT) have been used to measure the apparent site size of the complex at 25 degrees C in pH 8.1 and 6.9 as a function of NaF, NaCl, NaBr, and MgCl2 concentrations. Under all conditions in which "reverse" titrations were performed, we observe three distinct binding modes with site sizes of 35 +/- 2, 56 +/- 3, and 65 +/- 3 nucleotides/SSB tetramer; however, the transitions among the three binding modes are strongly dependent upon both the cation and anion valence, type, and concentration as well as the pH. A net uptake of both cations and anions accompanies the transitions from the (SSB)35 to the (SSB)56 binding mode at pH 6.9, whereas at pH 8.1 this transition is anion-independent, and only a net uptake of cations occurs. The transition from the (SSB)56 to the (SSB)65 binding mode is dependent upon both cations and anions at both pH 6.9 and 8.1 (25 degrees C), and a net uptake of both cations and anions accompanies this transition. We have also examined the transitions by monitoring the change in the sedimentation coefficient of the SSB protein-poly(dT) complex as a function of MgCl2 concentration (20 degrees C, pH 8.1) and observe an increase in s20,w, which coincides with the increase in apparent site size of the complex, as measured by fluorescence titrations. The frictional coefficient of the complex decreases by a factor of two in progressing from the (SSB)35 to the (SSB)65 binding mode, indicating a progressive compaction of the complex throughout the transition. The transition between the (SSB)35 and the (SSB)56 complex is dependent on the protein binding density, with the lower site size (SSB)35 complex favored at higher binding density. These results indicate that the transitions among the various SSB protein-single-stranded DNA binding modes are complex processes that depend on a number of solution variables that are thermodynamically linked.(ABSTRACT TRUNCATED AT 400 WORDS)     

Microsecond dynamics of protein-DNA interactions: direct observation of the wrapping/unwrapping kinetics of single-stranded DNA around the E. coli SSB tetramer

The Escherichia coli single-stranded DNA binding protein (SSB) binds selectively to single-stranded (ss) DNA intermediates during DNA replication, recombination and repair. Each subunit of the homo-tetrameric protein contains a potential ssDNA binding site, thus the protein can bind to ssDNA in multiple binding modes, one of which is the (SSB)(65) mode, in which a 65 nucleotide stretch of ssDNA interacts with and wraps around all four subunits of the tetramer. Previous stopped-flow kinetic studies of (SSB)(65) complex formation using the oligodeoxynucleotide, (dT)70, were unable to resolve the initial binding step from the rapid wrapping of ssDNA around the tetramer. Here we report a laser temperature-jump study with resolution in the approximately 500 ns to 4 ms time range, which directly detects these ssDNA wrapping/unwrapping steps. Biphasic time courses are observed with a fast phase that is concentration-independent and which occurs on a time-scale of tens of microseconds, reflecting the wrapping/unwrapping of ssDNA around the SSB tetramer. Analysis of the slower binding phase, in combination with equilibrium binding and stopped-flow kinetic studies, also provides evidence for a previously undetected intermediate along the pathway to forming the (SSB)(65) complex.     

Effect of Mg2+ on the DNA binding modes of the Streptococcus pneumoniae SsbA and SsbB proteins

The effect of Mg2+ on the binding of the Streptococcus pneumoniae single-stranded DNA binding (SSB) proteins, SsbA and SsbB, to various dT(n) oligomers was examined by polyacrylamide gel electrophoresis. The results were then compared with those that were obtained with the well characterized SSB protein from Escherichia coli, SsbEc. In the absence of Mg2+, the results indicated that the SsbEc protein was able to bind to the dT(n) oligomers in the SSB(35) mode, with only two of the four subunits of the tetramer interacting with the dT(n) oligomers. In the presence of Mg2+, however, the results indicated that the SsbEc protein was bound to the dT(n) oligomers in the SSB(65) mode, with all four subunits of the tetramer interacting with the dT(n) oligomers. The SsbA protein behaved similarly to the SsbEc protein under all conditions, indicating that it undergoes Mg2+ -dependent changes in its DNA binding modes that are analogous to those of the SsbEc protein. The SsbB protein, in contrast, appeared to bind to the dT(n) oligomers in an SSB(65)-like mode in either the presence or the absence of Mg2+, suggesting that it may not exhibit the pronounced negative intrasubunit cooperativity in the absence of Mg2+ that is required for the formation of the SSB(35) mode. Additional experiments with a chimeric SsbA/B protein indicated that the structural determinants that govern the transitions between the different DNA binding modes may be contained within the N-terminal domains of the SSB proteins.     

Two binding modes in Escherichia coli single strand binding protein-single stranded DNA complexes. Modulation by NaCl concentration

The binding properties of the Escherichia coli encoded single strand binding protein (SSB) to a variety of synthetic homopolynucleotides, as well as to single stranded M13 DNA, have been examined as a function of the NaCl concentration (25.0 degrees C, pH 8.1). Quenching of the intrinsic tryptophan fluorescence of the SSB protein by the nucleic acid is used to monitor binding. We find that the site size (n) for binding of SSB to all single stranded nucleic acids is quite dependent on the NaCl concentration. For SSB-poly(dT), n = 33 +/- 3 nucleotides/tetramer below 10 mM NaCl and 65 +/- 5 nucleotides/tetramer above 0.20 M NaCl (up to 5 M). Between 10 mM and 0.2 M NaCl, the apparent site size increases continuously with [NaCl]. The extent of quenching of the bound SSB fluorescence by poly(dT) also displays two-state behavior, 51 +/- 3% quenching below 10 mM NaCl and 83 +/- 3% quenching at high [NaCl] (greater than 01.-0.2 M NaCl), which correlates with the observed changes in the occluded site size. On the basis of these observations as well as the data of Krauss et al. (Krauss, G., Sindermann, H., Schomburg, U., and Maass, G. (1981) Biochemistry 20, 5346-5352) and Chrysogelos and Griffith (Chrysogelos, S., and Griffith, J. (1982) Proc. Natl. Acad. Sci. U. S. A. 79,5803-5807) we propose a model in which E. coli SSB binds to single stranded nucleic acids in two binding modes, a low salt mode (n = 33 +/- 3), referred to as (SSB)33, in which the nucleic acid interacts with only two protomers of the tetramer, and one at higher [NaCl], n = 65 +/- 5, (SSB)65, in which the nucleic acid interacts with all 4 protomers of the tetramer. At intermediate NaCl concentrations a mixture of these two binding modes exists which explains the variable site sizes and other apparent discrepancies previously reported for SSB binding. The transition between the two binding modes is reversible, although the kinetics are slow, and it is modulated by NaCl concentrations within the physiological range. We suggest that SSB may utilize both binding modes in its range of functions (replication, recombination, repair) and that in vivo changes in the ionic media may play a role in regulating some of these processes.     

Salt-dependent changes in the DNA binding co-operativity of Escherichia coli single strand binding protein

The co-operative nature of the binding of the Escherichia coli single strand binding protein (SSB) to single-stranded nucleic acids has been examined over a range of salt concentrations (NaCl and MgCl2) to determine if different degrees of binding co-operativity are associated with the two SSB binding modes that have been identified recently. Quantitative estimates of the binding properties, including the co-operativity parameter, omega, of SSB to single-stranded DNA and RNA homopolynucleotides have been obtained from equilibrium binding isotherms, at high salt (greater than or equal to 0.2 M-NaCl), by monitoring the fluorescence quenching of the SSB upon binding. Under these high salt conditions, where only the high site size SSB binding mode exists (65 +/- 5 nucleotides per tetramer), we find only moderate co-operativity for SSB binding to both DNA and RNA, (omega = 50 +/- 10), independent of the concentration of salt. This value for omega is much lower than most previous estimates. At lower concentrations of NaCl, where the low site size SSB binding mode (33 +/- 3 nucleotides/tetramer) exists, but where SSB affinity for single-stranded DNA is too high to estimate co-operativity from classical binding isotherms, we have used an agarose gel electrophoresis technique to qualitatively examine SSB co-operativity with single-stranded (ss) M13 phage DNA. The apparent binding co-operativity increases dramatically below 0.20 M-NaCl, as judged by the extremely non-random distribution of SSB among the ssM13 DNA population at low SSB to DNA ratios. However, the highly co-operative complexes are not at equilibrium at low SSB/DNA binding densities, but are formed only transiently when SSB and ssDNA are directly mixed at low concentrations of NaCl. The conversions of these metastable, highly co-operative SSB-ssDNA complexes to their equilibrium, low co-operativity form is very slow at low concentrations of NaCl. At equilibrium, the SSB-ssDNA complexes seem to possess the same low degree of co-operativity (omega = 50 +/- 10) under all conditions tested. However, the highly co-operative mode of SSB binding, although metastable, may be important during non-equilibrium processes such as DNA replication. The possible relation between the two SSB binding modes, which differ in site size by a factor of two, and the high and low co-operativity complexes, which we report here, is discussed.     

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.     

Dynamic structural rearrangements between DNA binding modes of E. coli SSB protein

Escherichia coli single-stranded (ss)DNA binding (SSB) protein binds ssDNA in multiple binding modes and regulates many DNA processes via protein-protein interactions. Here, we present direct evidence for fluctuations between the two major modes of SSB binding, (SSB)(35) and (SSB)(65) formed on (dT)(70), with rates of interconversion on time scales that vary as much as 200-fold for a mere fourfold change in NaCl concentration. Such remarkable electrostatic effects allow only one of the two modes to be significantly populated outside a narrow range of salt concentration, providing a context for precise control of SSB function in cellular processes via SSB expression levels and interactions with other proteins. Deletion of the acidic C terminus of SSB, the site of binding of several proteins involved in DNA metabolism, does not affect the strong salt dependence, but shifts the equilibrium towards the highly cooperative (SSB)(35) mode, suggesting that interactions of proteins with the C terminus may regulate the binding mode transition and vice versa. Single molecule analysis further revealed a novel low abundance binding configuration and provides a direct demonstration that the SSB-ssDNA complex is a finely tuned assembly in dynamic equilibrium among several well-defined structural and functional states.     

Single molecule analysis of Thermus thermophilus SSB protein dynamics on single-stranded DNA

Single-stranded (ss) DNA binding (SSB) proteins play central roles in DNA replication, recombination and repair in all organisms. We previously showed that Escherichia coli (Eco) SSB, a homotetrameric bacterial SSB, undergoes not only rapid ssDNA-binding mode transitions but also one-dimensional diffusion (or migration) while remaining bound to ssDNA. Whereas the majority of bacterial SSB family members function as homotetramers, dimeric SSB proteins were recently discovered in a distinct bacterial lineage of extremophiles, the Thermus–Deinococcus group. Here we show, using single-molecule fluorescence resonance energy transfer (FRET), that homodimeric bacterial SSB from Thermus thermophilus (Tth) is able to diffuse spontaneously along ssDNA over a wide range of salt concentrations (20–500 mM NaCl), and that TthSSB diffusion can help transiently melt the DNA hairpin structures. Furthermore, we show that two TthSSB molecules undergo transitions among different DNA-binding modes while remaining bound to ssDNA. Our results extend our previous observations on homotetrameric SSBs to homodimeric SSBs, indicating that the dynamic features may be shared among different types of SSB proteins. These dynamic features of SSBs may facilitate SSB redistribution and removal on/from ssDNA, and help recruit other SSB-interacting proteins onto ssDNA for subsequent DNA processing in DNA replication, recombination and repair.     

Plasmodium falciparum SSB tetramer binds single-stranded DNA only in a fully wrapped mode

The tetrameric Escherichia coli single-stranded DNA (ssDNA) binding protein (Ec-SSB) functions in DNA metabolism by binding to ssDNA and interacting directly with numerous DNA repair and replication proteins. Ec-SSB tetramers can bind ssDNA in multiple DNA binding modes that differ in the extent of ssDNA wrapping. Here, we show that the structurally similar SSB protein from the malarial parasite Plasmodium falciparum (Pf-SSB) also binds tightly to ssDNA but does not display the same number of ssDNA binding modes as Ec-SSB, binding ssDNA exclusively in fully wrapped complexes with site sizes of 52-65 nt/tetramer. Pf-SSB does not transition to the more cooperative (SSB)(35) DNA binding mode observed for Ec-SSB. Consistent with this, Pf-SSB tetramers also do not display the dramatic intra-tetramer negative cooperativity for binding of a second (dT)(35) molecule that is evident in Ec-SSB. These findings highlight variations in the DNA binding properties of these two highly conserved homotetrameric SSB proteins, and these differences might be tailored to suit their specific functions in the cell.     

Probing E. coli SSB protein-DNA topology by reversing DNA backbone polarity

Escherichia coli single-strand (ss) DNA binding protein (SSB) is an essential protein that binds ssDNA intermediates formed during genome maintenance. SSB homotetramers bind ssDNA in two major modes, differing in occluded site size and cooperativity. The (SSB)₃₅ mode in which ssDNA wraps, on average, around two subunits is favored at low [NaCl] and high SSB/DNA ratios and displays high unlimited, nearest-neighbor cooperativity forming long protein clusters. The (SSB)₆₅ mode, in which ssDNA wraps completely around four subunits of the tetramer, is favored at higher [NaCl] (>200 mM) and displays limited low cooperativity. Crystal structures of E. coli SSB and Plasmodium falciparum SSB show ssDNA bound to the SSB subunits (OB folds) with opposite polarities of the sugar phosphate backbones. To investigate whether SSB subunits show a polarity preference for binding ssDNA, we examined EcSSB and PfSSB binding to a series of (dT)₇₀ constructs in which the backbone polarity was switched in the middle of the DNA by incorporating a reverse-polarity (RP) phosphodiester linkage, either 3′-3′ or 5′-5′. We find only minor effects on the DNA binding properties for these RP constructs, although (dT)₇₀ with a 3′-3′ polarity switch shows decreased affinity for EcSSB in the (SSB)₆₅ mode and lower cooperativity in the (SSB)₃₅ mode. However, (dT)₇₀ in which every phosphodiester linkage is reversed does not form a completely wrapped (SSB)₆₅ mode but, rather, binds EcSSB in the (SSB)₃₅ mode with little cooperativity. In contrast, PfSSB, which binds ssDNA only in an (SSB)₆₅ mode and with opposite backbone polarity and different topology, shows little effect of backbone polarity on its DNA binding properties. We present structural models suggesting that strict backbone polarity can be maintained for ssDNA binding to the individual OB folds if there is a change in ssDNA wrapping topology of the RP ssDNA.     

Plasmodium falciparum SSB tetramer wraps single-stranded DNA with similar topology but opposite polarity to E. coli SSB

Single-stranded DNA binding (SSB) proteins play central roles in genome maintenance in all organisms. Plasmodium falciparum, the causative agent of malaria, encodes an SSB protein that localizes to the apicoplast and likely functions in the replication and maintenance of its genome. P. falciparum SSB (Pf-SSB) shares a high degree of sequence homology with bacterial SSB proteins but differs in the composition of its C-terminus, which interacts with more than a dozen other proteins in Escherichia coli SSB (Ec-SSB). Using sedimentation methods, we show that Pf-SSB forms a stable homo-tetramer alone and when bound to single-stranded DNA (ssDNA). We also present a crystal structure at 2.1 ? resolution of the Pf-SSB tetramer bound to two (dT)(35) molecules. The Pf-SSB tetramer is structurally similar to the Ec-SSB tetramer, and ssDNA wraps completely around the tetramer with a "baseball seam" topology that is similar to Ec-SSB in its "65 binding mode". However, the polarity of the ssDNA wrapping around Pf-SSB is opposite to that observed for Ec-SSB. The interactions between the bases in the DNA and the amino acid side chains also differ from those observed in the Ec-SSB-DNA structure, suggesting that other differences may exist in the DNA binding properties of these structurally similar proteins.     

Negative co-operativity in Escherichia coli single strand binding protein-oligonucleotide interactions. II. Salt, temperature and oligonucleotide length effects

We have examined the salt and temperature dependences of the equilibrium binding of the Escherichia coli single strand binding (SSB) tetramer to a series of oligodeoxythymidylates, dT(pT)N-1, with N = 16, 28, 35, 56 and 70. Absolute binding isotherms were obtained, based on the quenching of the intrinsic protein fluorescence upon formation of the complexes. The shorter oligonucleotides, with N = 16, 28 and 35, bind to multiple sites on the SSB tetramer and negative co-operativity is observed among these binding sites. We have quantitatively analyzed these isotherms, using a statistical thermodynamic ("square") model to obtain the intrinsic binding constant KN, and the negative co-operativity constant, sigma N. For all oligonucleotides, we find that KN decreases significantly with increasing concentration of monovalent salt, indicating a large electrostatic component to the free energy of the interaction (e.g. delta log KN/delta log [NaBr] = -2.7, -4.6 and -7.1 for N = 16, 35 and 70, respectively), with contributions from both cations and anions. For oligonucleotides that span two or more subunits, there is a significant unfavorable contribution to the binding free energy for each intersubunit crossing, with an accompanying uptake of anions. Therefore, the extent of anion uptake increases as the number of intersubunit crossings increase. There is a strong temperature dependence for the intrinsic binding of dT(pT)15, such that delta Ho = -26(+/- 3) kcal/mol dT(pT)15. Negative co-operativity exists under all solution conditions tested, i.e. sigma N less than 1, and this is independent of anion concentration and type. However, the negative co-operativity constant does decrease with decreasing concentration of cation. The dependence of sigma 16 on Na+ concentration indicates that an average of one sodium ion is taken up as a result of the negative co-operativity between two dT(pT)15 binding sites. These data and the lack of a temperature dependence for sigma 16 suggest that the molecular basis for the negative co-operativity is predominantly electrostatic and may be due to the repulsion of regions of single-stranded DNA that are required to bind in close proximity on an individual SSB tetramer.     

Kinetics of binding of single-stranded DNA binding protein from Escherichia coli to single-stranded nuclei acids

The time course of the reaction of Escherichia coli single-stranded DNA binding protein (E. coli SSB) with poly(dT) and M13mp8 single-stranded DNA has been measured by fluorescence stopped-flow experiments. For poly(dT), the fluorescence traces follow simple bimolecular behavior up to 80% saturation of the polymer with E. coli SSB. A mechanistic explanation of this binding behavior can be given as follows: (1) E. coli SSB is able to translocate very rapidly on the polymer, forming cooperative clusters. (2) In the rate-limiting step of the association reaction, E. coli SSB is bound to the polymer only by one or two of its four contact sites. As compared to poly(dT), association to single-stranded M13mp8 phage DNA is slower by at least 2 orders of magnitude. We attribute this finding to the presence of secondary structure elements (double-stranded structures) in the natural single-stranded DNA. These structures cannot be broken by E. coli SSB in a fast reaction. In order to fulfill its physiological function in reasonable time, E. coli SSB must bind newly formed single-stranded DNA immediately. The protein can, however, bind to such pieces of the newly formed single-stranded DNA which are too short to cover all four binding sites of the E. coli SSB tetramer.     

Cloning, over-expression and biochemical characterization of the single-stranded DNA binding protein from Mycobacterium tuberculosis.

The single-stranded DNA binding protein (SSB) plays an important role in DNA replication, repair and recombination. To study the biochemical properties of SSB from Mycobacterium tuberculosis (MtuSSB), we have used the recently published genome sequence to clone the ssb open reading frame by PCR and have developed an overexpression system. Sequence comparison reveals that the MtuSSB lacks many of the highly conserved amino acids crucial for the Escherichia coli SSB (EcoSSB) structure-function relationship. A highly conserved His55, important for homotetramerization of EcoSSB is represented by a leucine in MtuSSB. Similarly, Trp40, Trp54 and Trp88 of EcoSSB required for stabilizing SSB-DNA complexes are represented by Ile40, Phe54 and Phe88 in MtuSSB. In addition, a group of positively charged amino acids oriented towards the DNA binding cleft in EcoSSB contains several nonconserved changes in MtuSSB. We show that in spite of these changes in the primary sequence MtuSSB is similar to EcoSSB in its biochemical properties. It exists as a tetramer, it has the same minimal size requirement for its efficient binding to DNA and its binding affinity towards DNA oligonucleotides is indistinguishable from that of EcoSSB. Furthermore, MtuSSB interacts with DNA in at least two distinct modes corresponding to the SSB35 and SSB56/65 modes of EcoSSB interaction with DNA. However, MtuSSB does not form heterotetramers with EcoSSB. MtuSSB therefore presents us with an interesting system with which to investigate further the role of the conserved amino acids in the biological properties of SSBs.     

Single-stranded DNA binding proteins unwind the newly synthesized double-stranded DNA of model miniforks

Single-stranded DNA binding (SSB) proteins are essential proteins of DNA metabolism. We characterized the binding of the bacteriophage T4 SSB, Escherichia coli SSB, human replication protein A (hRPA), and human hSSB1 proteins onto model miniforks and double-stranded-single-stranded (ds-ss) junctions exposing 3' or 5' ssDNA overhangs. T4 SSB proteins, E. coli SSB proteins, and hRPA have a different binding preference for the ss tail exposed on model miniforks and ds-ss junctions. The T4 SSB protein preferentially binds substrates with 5' ss tails, whereas the E. coli SSB protein and hRPA show a preference for substrates with 3' ss overhangs. When interacting with ds-ss junctions or miniforks, the T4 SSB protein, E. coli SSB protein, and hRPA can destabilize not only the ds part of a ds-ss junction but also the daughter ds arm of a minifork. The T4 SSB protein displays these unwinding activities in a polar manner. Taken together, our results position the SSB protein as a potential key player in the reversal of a stalled replication fork and in gap repair-mediated repetitive sequence expansion.     

Mechanism of RecO recruitment to DNA by single-stranded DNA binding protein

RecO is a recombination mediator protein (RMP) important for homologous recombination, replication repair and DNA annealing in bacteria. In all pathways, the single-stranded (ss) DNA binding protein, SSB, plays an inhibitory role by protecting ssDNA from annealing and recombinase binding. Conversely, SSB may stimulate each reaction through direct interaction with RecO. We present a crystal structure of Escherichia coli RecO bound to the conserved SSB C-terminus (SSB-Ct). SSB-Ct binds the hydrophobic pocket of RecO in a conformation similar to that observed in the ExoI/SSB-Ct complex. Hydrophobic interactions facilitate binding of SSB-Ct to RecO and RecO/RecR complex in both low and moderate ionic strength solutions. In contrast, RecO interaction with DNA is inhibited by an elevated salt concentration. The SSB mutant lacking SSB-Ct also inhibits RecO-mediated DNA annealing activity in a salt-dependent manner. Neither RecO nor RecOR dissociates SSB from ssDNA. Therefore, in E. coli, SSB recruits RMPs to ssDNA through SSB-Ct, and RMPs are likely to alter the conformation of SSB-bound ssDNA without SSB dissociation to initiate annealing or recombination. Intriguingly, Deinococcus radiodurans RecO does not bind SSB-Ct and weakly interacts with the peptide in the presence of RecR, suggesting the diverse mechanisms of DNA repair pathways mediated by RecO in different organisms.     

Characterization of a Single-Stranded DNA-Binding Protein from <Emphasis Type="Italic">Pseudomonas aeruginosa</Emphasis> PAO1

Single-stranded DNA-binding protein (SSB) plays an important role in DNA metabolism, such as in DNA replication, repair, and recombination, and is essential for cell survival. We characterized the single-stranded DNA (ssDNA)-binding properties of Pseudomonas aeruginosa PAO1 SSB (PaSSB) by using fluorescence quenching measurements and electrophoretic mobility shift analysis (EMSA). Analysis of purified PaSSB by gel filtration chromatography revealed a stable tetramer in solution. In fluorescence titrations, PaSSB bound 22–32 nucleotides (nt) per tetramer depending on salt concentration. Using EMSA, we characterized the stoichiometry of PaSSB complexed with a series of ssDNA homopolymers, and the size of the binding site was determined to be 29 ± 1 nt. Furthermore, EMSA results indicated that the dissociation constants of PaSSB for the first tetramer were less than those for the second tetramer. On the basis of these biophysical analyses, the ssDNA binding mode of PaSSB is expected to be noncooperative.