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.     

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)     

Monomer-tetramer equilibrium of the Escherichia coli ssb-1 mutant single strand binding protein

The Escherichia coli single strand binding (SSB) protein is an essential protein required for DNA replication and involved in recombination and a number of repair processes. It is a stable homotetramer in solution; however the ssb-1 mutation (His-55 to Tyr) destabilizes the tetramer with respect to monomers and this defect seems to explain the observed phenotype (Williams, K. R., Murphy, J. B., and Chase, J. W. (1984) J. Biol. Chem. 259, 11804-11811). We report a quantitative study of the SSB-1 monomer-tetramer equilibrium in vitro as a function of temperature, pH, NaCl, MgCl2, urea, and guanidine hydrochloride concentrations. The self-assembly equilibrium was monitored by the increase in intrinsic protein fluorescence anisotropy accompanying the formation of the tetramer. The experimental isotherms indicate that SSB-1 dimers are not highly populated at equilibrium, hence the formation of the tetramer is well-described as a one-step association of four monomers. At 25 degrees C, pH 8.1, the monomer concentration for 50% tetramer dissociation is (MT)1/2 = 0.87 microM, corresponding to a monomer-tetramer equilibrium constant, KT = 3 +/- 1 x 10(18) M-3. The tetramerization constant, KT, is highly dependent upon temperature and pH, with delta H0 = -51 +/- 7 kcal/mol (pH 8.1) and delta H0 = -37 +/- 5 kcal/mol (pH 6.9). There is no effect of NaCl on the monomer-tetramer association in the range from 0.20 to 1.0 M; however, MgCl2 decreases the stability of the SSB-1 tetramer. In the presence of high concentrations of the single-stranded oligonucleotide, dT(pT)15, the tetramerization constant is slightly increased indicating that binding of the oligonucleotide to the SSB-1 monomer promotes the assembly process, although not dramatically. The large negative delta H0 that is associated with formation of the tetramer provides a likely explanation for the temperature sensitivity of the ssb-1 mutation.     

Adenine base unstacking dominates the observed enthalpy and heat capacity changes for the Escherichia coli SSB tetramer binding to single-stranded oligoadenylates.

Isothermal titration calorimetry (ITC) was used to test the hypothesis that the relatively small enthalpy change (DeltaHobs) and large negative heat capacity change (DeltaCp,obs) observed for the binding of the Escherichia coli SSB protein to single-stranded (ss) oligodeoxyadenylates result from the temperature-dependent adenine base unstacking equilibrium that is thermodynamically coupled to binding. We have determined DeltaH1,obs for the binding of 1 mole of each of dT(pT)34, dC(pC)34, and dA(pA)34 to the SSB tetramer (20 mM NaCl at pH 8.1). For dT(pT)34 and dC(pC)34, we found large, negative values for DeltaH1,obs of -75 +/- 1 and -85 +/- 2 kcal/mol at 25 degrees C, with DeltaCp,obs values of -540 +/- 20 and -570 +/- 30 cal mol-1 K-1 (7-50 degrees C), respectively. However, for SSB-dA(pA)34 binding, DeltaH1,obs is considerably less negative (-14 +/- 1 kcal/mol at 25 degrees C), even becoming positive at temperatures below 13 degrees C, and DeltaCp,obs is nearly twice as large in magnitude (-1180 +/- 40 cal mol-1 K-1). These very different thermodynamic properties for SSB-dA(pA)34 binding appear to result from the fact that the bases in dA(pA)34 are more stacked at any temperature than are the bases in dC(pC)34 or dT(pT)34 and that the bases become unstacked within the SSB-ssDNA complexes. Therefore, the DeltaCp,obs for SSB-ssDNA binding has multiple contributions, a major one being the coupling to binding of a temperature-dependent conformational change in the ssDNA, although SSB binding to unstacked ssDNA still has an "intrinsic" negative DeltaCp,0. In general, such temperature-dependent changes in the conformational "end states" of interacting macromolecules can contribute significantly to both DeltaCp,obs and DeltaHobs.     

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.     

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.     

Stopped-flow studies of the kinetics of single-stranded DNA binding and wrapping around the Escherichia coli SSB tetramer

We have examined the kinetic mechanism for binding of the homotetrameric Escherichia coliSSB protein to single-stranded oligodeoxynucleotides [(dT)(70) and (dT)(35)] under conditions that favor the formation of a fully wrapped ssDNA complex in which all four subunits interact with DNA. Under these conditions, a so-called (SSB)(65) complex is formed in which either one molecule of (dT)(70) or two molecules of (dT)(35) bind per tetramer. Stopped-flow studies monitoring quenching of the intrinsic SSB Trp fluorescence were used to examine the initial binding step. To examine the kinetics of ssDNA wrapping, we used a single-stranded oligodeoxythymidylate, (dT)(66), that was labeled on its 3'-end with a fluorescent donor (Cy3) and on its 5'-end with a fluorescent acceptor (Cy5). Formation of the fully wrapped structure was accompanied by extensive fluorescence resonance energy transfer (FRET) from Cy3 to Cy5 since the two ends of (dT)(66) are in close proximity in the fully wrapped complex. Our results indicate that initial ssDNA binding to the tetramer is very rapid, with a bimolecular rate constant, k(1,app), of nearly 10(9) M(-1) s(-1) in the limit of low salt concentration (<0.2 M NaCl, pH 8.1, 25.0 degrees C), whereas the rate of dissociation is very low at all salt concentrations that were examined (20 mM to 2 M NaCl or NaBr). However, the rate of initial binding and the rate of formation of the fully wrapped complex are identical, indicating that the rate of wrapping of the ssDNA around the SSB tetramer is very rapid, with a lower limit rate of 700 s(-1). The implications of this rapid binding and wrapping reaction are discussed.     

Large contributions of coupled protonation equilibria to the observed enthalpy and heat capacity changes for ssDNA binding to Escherichia coli SSB protein

Many macromolecular interactions, including protein‐nucleic acid interactions, are accompanied by a substantial negative heat capacity change, the molecular origins of which have generated substantial interest. We have shown previously that temperature‐dependent unstacking of the bases within oligo(dA) upon binding to the Escherichia coli SSB tetramer dominates the binding enthalpy, ΔH_obs, and accounts for as much as a half of the observed heat capacity change, ΔC_p. However, there is still a substantial ΔC_p associated with SSB binding to ssDNA, such as oligo(dT), that does not undergo substantial base stacking. In an attempt to determine the origins of this heat capacity change, we have examined by isothermal titration calorimetry (ITC) the equilibrium binding of dT(pT)₃₄ to SSB over a broad pH range (pH 5.0–10.0) at 0.02 M, 0.2 M NaCl and 1 M NaCl (25°C), and as a function of temperature at pH 8.1. A net protonation of the SSB protein occurs upon dT(pT)₃₄ binding over this entire pH range, with contributions from at least three sets of protonation sites (pK_a1 = 5.9–6.6, pK_a2 = 8.2–8.4, and pK_a3 = 10.2–10.3) and these protonation equilibria contribute substantially to the observed ΔH and ΔC_p for the SSB‐dT(pT)₃₄ interaction. The contribution of this coupled protonation (∼ −260 to −320 cal mol⁻¹ K⁻¹) accounts for as much as half of the total ΔC_p. The values of the “intrinsic” ΔC_p,0 range from −210 ± 33 cal mol⁻¹ °K⁻¹ to −237 ± 36 cal mol⁻¹K⁻¹, independent of [NaCl]. These results indicate that the coupling of a temperature‐dependent protonation equilibria to a macromolecular interaction can result in a large negative ΔC_p, and this finding needs to be considered in interpretations of the molecular origins of heat capacity changes associated with ligand‐macromolecular interactions, as well as protein folding. Proteins 2000;Suppl 4:8–22. © 2000 Wiley‐Liss, Inc.     

Escherichia coli single-stranded DNA binding protein is mobile on DNA: 1H NMR study of its interaction with oligo- and polynucleotides

The interaction of the Escherichia coli single-stranded DNA binding protein (SSB) with oligo- and poly-nucleotides has been studied by 270-MHz 1H NMR spectroscopy and fast kinetic techniques. d(pT)8 and poly(dT) were used to study noncooperative and cooperative binding, respectively. The H6, H1', and CH3 resonances of d(pT)8 are high-field shifted by less than 0.05 ppm, and H8 and H2 of poly(dA) are low-field shifted upon complexation. The protein resonances remain virtually unshifted. The small shifts upon complexation provide no evidence for extensive stacking interactions between the nucleotide bases and aromatic amino acid side chains of SSB. The d(pT)8 and poly(dA) signals are broadened to about 30 Hz whereas the resonances of poly(dT) are broadened beyond detection upon stoichiometric complexation. Continuous broadening of all poly(dT) signals even at a 10-fold excess of poly(dT) indicates fast exchange of SSB between different binding sites. Dissociation and reassociation rates determined from stopped-flow experiments are too slow by at least 2 orders of magnitude to account for the experimental line widths. Therefore, we conclude that SSB translocates without dissociation from the DNA template. A model for the translocation is outlined. It is based on partial dissociation of octamer sections of poly(dT) from the complex with a rate constant as previously published for the dissociation of d(pT)8 from SSB.     

T4 gene 32 protein trypsin-generated fragments. Fluorescence measurement of DNA-binding parameters.

The intrinsic fluorescence of the T4 helix-destabilizing protein specified by gene 32 (32P) is not altered by the proteolytic removal of either the 6200-dalton COOH-terminal "A" region (32P*-A) or both the A and the 2300-dalton NH2-terminal "B" region (32P*-(A + B)). The intrinsic fluorescence of 32P, 32P*-A, and 32P*-(A + B) is decreased 23% by the addition of d(pT)8 and 34% by the addition of poly(dT). Saturation binding curves of the percentage of change in protein fluorescence as a function of nucleotide concentration show that the intact 32P as well as the two proteolysis-generated fragments all have association constants of approximately 10(6) M-1 for d(pT)8. This demonstrates that the DNA binding site is not contained within either the A or B regions of 32P. Both 32P and 32P*-A bind cooperatively to poly(dT) as evidenced by a 400- to 1000-fold increase in association constant for poly(dT) compared to d(pT)8. Since within the limits of our measurements 32P and 32P*-A bind equally well to poly(dT) (Kassoc approximately 5 . 10(8) M-1), the enhanced helix-destabilizing properties previously reported for 32P*-A cannot be accounted for by a significant increase in binding affinity of 32P*-A for single-stranded DNA. The binding constant for the 32P*-(A + B):poly(dT) complex is only 3-fold higher than that for the 32P*-(A + B):d(pT)8 complex, which confirms our proposal that the B region is essential for cooperative 32P:32P protein interactions.     

An EPR study to determine the relative nucleic acid binding affinity of single-stranded DNA-binding protein from Escherichia coli.

A direct quantitative determination by EPR of the nucleic acid binding affinity relationship of the single-stranded DNA-binding protein (SSB) from Escherichia coli at close to physiological NaCl concentration is reported. Titrations of (DUAP, dT)n, an enzymatically spin-labeled (dT)n, with SSB in 20 mM Tris-HCl (pH 8.1), 1 mM sodium EDTA, 0.1 mM dithiothreitol, 10% (w/v) glycerol, 0.05% Triton with either low (5 mM), intermediate (125 mM) or high 200 mM) NaCl content, reveal the formation of a high nucleic acid density complex with a binding stoichiometry (s) of 60 to 75 nucleotides per SSB tetramer. Reverse titrations, achieved by adding (DUAP, dT)n to SSB-containing solutions, form a low nucleic acid density complex with an s = 25 to 35 in the buffer with low NaCl content (5 mM NaCl). The complex with an s = 25 to 35 is converted to the high nucleic acid density complex by increasing the NaCl content to 200 mM. It is, therefore, metastable and forms only under reverse titration conditions in low NaCl. The relative apparent affinity constant Kapp of SSB for various unlabeled single-stranded nucleic acids was determined by EPR competition experiments with spin-labeled nucleic acids as macromolecular probes in the presence of the high nucleic acid density complex. The Kapp of SSB exhibits the greatest affinity for (dT)n as was previously found for T4 gene 32 protein (Bobst, A.M., Langemeier, P.W., Warwick-Koochaki, P.E., Bobst, E.V. and Ireland, J.C. (1982) J. Biol. Chem. 257, 6184) and gene 5 protein (Bobst, A.M., Ireland, J.C. and Bobst, E.V. (1984) J. Biol. Chem. 259, 2130) by EPR competition assays. In contrast, however, SSB does not display several orders of magnitude greater affinity for (dT)n than for other single stranded DNAs as is the case with both gene 5 and T4 gene 32 protein. The relative Kapp values for SSB in the above buffer with 125 mM NaCl are: Kapp(dT)n = 4KappfdDNA = 40Kapp(dA)n = 200Kapp(A)n.     

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)     

Cooperative binding of polyamines induces the Escherichia coli single-strand binding protein-DNA binding mode transitions.

The Escherichia coli single-strand binding (SSB) protein is an essential protein involved in DNA replication, recombination, and repair processes. The tetrameric protein binds to ss nucleic acids in a number of different binding modes in vitro. These modes differ in the number of nucleotides occluded per SSB tetramer and in the type and degree of cooperative complexes that are formed with ss DNA. Although it is not yet known whether only one or all of these modes function in vivo, based on the dramatically different properties of the SSB tetramer in these different ss DNA binding modes, it has been suggested that the different modes may function selectively in replication, recombination, and/or repair. The transitions between these different modes are very sensitive to solution conditions, including salt (concentration, as well as cation and anion type), pH, and temperature. We have examined the effects of multivalent cations, principally the polyamine spermine, on the SSB-ss poly(dT) binding mode transitions and find that the transition from the (SSB)35 to the (SSB)56 binding mode can be induced by micromolar concentrations of polyamines as well as the inorganic cation Co(NH3)6(3+). Furthermore, these multivalent cations, as well as Mg2+, induce the binding mode transition by binding cooperatively to the SSB-poly(dT) complexes. These observations are interesting in light of the fact that polyamines, such as spermidine, are part of the ionic environment in E. coli and hence these cations are likely to affect the distribution of SSB-ss DNA binding modes in vivo.(ABSTRACT TRUNCATED AT 250 WORDS)     

Klenow fragment of DNA-polymerase I from E. coli. III. The role of internucleotide phosphate groups of the matrix in its binding with the enzyme

The modification of Klenow fragment of DNA polymerase I E. coli was investigated by the affinity reagents d(Tp)2C[Pt2+(NH3)2OH](pT)7 and d(pT)2pC[Pt2+(NH3)2OH](pT)7. The template binding site of the enzyme was modified by these reagents in the presence of NaF (5 mM), which inhibits selectively the 3'----5'-exonuclease activity of the enzyme and therefore prevents the reagent from degradation. NaCN destroyed covalent bonds between reagents and enzyme, restoring activity of the Klenow fragment. The affinity of different ligands (inorganic phosphate, nucleoside monophosphates, oligonucleotides) to the template binding site of Klenow fragment was estimated. Minimal ligands capable to bind with the template site were shown to be triethylphosphate (Kd 290 microM) and phosphate (Kd 26 microM). Ligand affinity increases by the factor 1.76 per an added (monomer unit from phosphate to d(pT) and then for oligonucleotides d(Tp)nT (n 1 to 19-20). At n greater than 19-20, the ligand affinity remained constant. The complete ethylation of phosphodiester groups lowers affinity of the oligothymidylates to the enzyme by approximately 10 times, and comparable decrease of Pt2+-oligonucleotide affinity to polymerase is caused by the absence of Mn2+-ions. The data obtained led to suggestion that one Me2+-dependent electrostatic contact of the template phosphodiester group with the enzyme takes place (delta G = -1.45...-1.75 kcal/mole). Formation of a hydrogen bond with the oxygen atom of P = O group of the same template phosphate is also assumed (delta G = -4.8...-4.9 kcal/mole). Other template internucleotide phosphates do not interact with the enzyme but the bases of oligonucleotides take part in hydrophobic interactions with the template binding site. Gibbs energy changes by -0.34 kcal/mole when the template is lengthened by one unit.     

Kinetic mechanism of direct transfer of Escherichia coli SSB tetramers between single-stranded DNA molecules

The kinetic mechanism of transfer of the homotetrameric Escherichia coli SSB protein between ssDNA molecules was studied using stopped-flow experiments. Dissociation of SSB from the donor ssDNA was monitored after addition of a large excess of unlabeled acceptor ssDNA by using either SSB tryptophan fluorescence or the fluorescence of a ssDNA labeled with an extrinsic fluorophore [fluorescein (F) or Cy3]. The dominant pathway for SSB dissociation occurs by a "direct transfer" mechanism in which an intermediate composed of two DNA molecules bound to one SSB tetramer forms transiently prior to the release of the acceptor DNA. When an initial 1:1 SSB-ssDNA complex is formed with (dT)(70) in the fully wrapped (SSB)(65) mode so that all four SSB subunits are bound to (dT)(70), the formation of the ternary intermediate complex occurs slowly with an apparent bimolecular rate constant, k(2,app), ranging from 1.2 x 10(3) M(-1) s(-1) (0.2 M NaCl) to approximately 5.1 x 10(3) M(-1) s(-1) (0.4 M NaBr), and this rate limits the overall rate of the transfer reaction (pH 8.1, 25 degrees C). These rate constants are approximately 7 x 10(5)- and approximately 7 x 10(4)-fold lower, respectively, than those measured for binding of the same ssDNA to an unligated SSB tetramer to form a singly ligated complex. However, when an initial SSB-ssDNA complex is formed with (dT)(35) so that only two SSB subunits interact with the DNA in an (SSB)(35) complex, the formation of the ternary intermediate occurs much faster with a k(2,app) ranging from >6.3 x 10(7) M(-1) s(-1) (0.2 M NaCl) to 2.6 x 10(7) M(-1) s(-1) (0.4 M NaBr). For these experiments, the rate of dissociation of the donor ssDNA determines the overall rate of the transfer reaction. Hence, an SSB tetramer can be transferred from one ssDNA molecule to another without proceeding through a free protein intermediate, and the rate of transfer is determined by the availability of free DNA binding sites within the initial SSB-ssDNA donor complex. Such a mechanism may be used to recycle SSB tetramers between old and newly formed ssDNA regions during lagging strand DNA replication.     

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.     

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)     

Thermodynamic analysis of stacking hybridization of oligonucleotides with DNA template.

Contiguous stacking hybridization of oligodeoxyribonucleotides with DNA as template was investigated using three types of complexes: oligonucleotide contiguously stacked with the stem of the preformed minihairpin (complexes I), oligonucleotide tandems containing two (complexes II) or three (complexes III) short oligomers with a common DNA template. Enthalpy Delta H degrees and entropy Delta S degrees of the coaxial stacking of adjacent duplexes were determined for GC/G*pC, GT/A*pC, AC/G*pT, AT/A*pT, CT/A*pG, AG/C*pT, AA/T*pT and TT/A*pA nicked (*) dinucleotide base pairs. The maximal efficiency of co-operative interaction was found for the GC/G*pC interface (Delta G degrees(NN/N*pN)=-2.7 kcal/mol) and the minimal one for the AA/T*pT interface (Delta G degrees(NN/N*pN)=-1.2 kcal/mol) at 37 degrees C. As a whole, the efficiency of the base pairs interaction Delta G degrees(NN/N*pN) in the nick is not lower than that within the intact DNA helix (Delta G degrees(NN/NN)).These observed Delta G degrees(NN/N*pN) values are proposed may include the effect of the partial removal of fraying at the adjacent helix ends additionally to the effect of the direct stacking of the terminal base pairs in the duplex junction (Delta G degrees(NN/NN). The thermodynamic parameters have been found to describe adequately the formation of all tandem complexes of the II and III types with oligonucleotides of various length and hybridization properties. The performed thermodynamic analysis reveals features of stacking oligonucleotide hybridization which allow one to predict the temperature dependence of association of oligonucleotides and the DNA template within tandem complexes as well as to determine optimal concentration for formation of these complexes characterized by high co-operativity level.