E. coli Rep oligomers are required to initiate DNA unwinding in vitro

E. coli Rep protein is a 3' to 5' SF1 superfamily DNA helicase which is monomeric in the absence of DNA, but can dimerize upon binding either single-stranded or duplex DNA. A variety of biochemical studies have led to proposals that Rep dimerization is important for its helicase activity; however, recent structural studies of Bacillus stearothermophilus PcrA have led to suggestions that SF1 helicases, such as E. coli Rep and E. coli UvrD, function as monomeric helicases. We have examined the question of whether Rep oligomerization is important for its DNA helicase activity using pre-steady state stopped-flow and chemical quenched-flow kinetic studies of Rep-catalyzed DNA unwinding. The results from four independent experiments demonstrate that Rep oligomerization is required for initiation of DNA helicase activity in vitro. No DNA unwinding is observed when only a Rep monomer is bound to the DNA substrate, even when fluorescent DNA substrates are used that can detect partial unwinding of the first few base-pairs at the ss-ds-DNA junction. In fact, under these conditions, ATP hydrolysis causes dissociation of the Rep monomer from the DNA, rather than DNA unwinding. These studies demonstrate that wild-type Rep monomers are unable to initiate DNA unwinding in vitro, and that oligomerization is required.

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, DeltaH(obs), and accounts for as much as a half of the observed heat capacity change, DeltaC(p). However, there is still a substantial DeltaC(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 degrees 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 DeltaH and DeltaC(p) for the SSB-dT(pT)(34) interaction. The contribution of this coupled protonation ( approximately -260 to -320 cal mol(-1) K(-1)) accounts for as much as half of the total DeltaC(p). The values of the "intrinsic" DeltaC(p,0) range from -210 +/- 33 cal mol(-1) degrees K(-1) to -237 +/- 36 cal mol(-1)K(-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 DeltaC(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.

Structure of the DNA binding domain of E. coli SSB bound to ssDNA

The structure of the homotetrameric DNA binding domain of the single stranded DNA binding protein from Escherichia coli (Eco SSB) bound to two 35-mer single stranded DNAs was determined to a resolution of 2.8 A. This structure describes the vast network of interactions that results in the extensive wrapping of single stranded DNA around the SSB tetramer and suggests a structural basis for its various binding modes.

An oligomeric form of E. coli UvrD is required for optimal helicase activity

Pre-steady-state chemical quenched-flow techniques were used to study DNA unwinding catalyzed by Escherichia coli UvrD helicase (helicase II), a member of the SF1 helicase superfamily. Single turnover experiments, with respect to unwinding of a DNA oligonucleotide, were used to examine the DNA substrate and UvrD concentration requirements for rapid DNA unwinding by pre-bound UvrD helicase. In excess UvrD at low DNA concentrations (1 nM), the bulk of the DNA is unwound rapidly by pre-bound UvrD complexes upon addition of ATP, but with time-courses that display a distinct lag phase for formation of fully unwound DNA, indicating that unwinding occurs in discrete steps, with a "step size" of four to five base-pairs as previously reported. Optimum unwinding by pre-bound UvrD-DNA complexes requires a 3' single-stranded (ss) DNA tail of 36-40 nt, whereas productive complexes do not form readily on DNA with 3'-tail lengths </=16 nt. A 5'-ssDNA tail is neither sufficient nor does it stimulate unwinding, even in the presence of a 3'-ssDNA tail. Nitrocellulose filter binding studies show that UvrD binding affinity also increases with increasing 3'-ssDNA tail length, showing apparent positive cooperativity for binding to DNA with a 40 nt 3'-ssDNA tail. Single turnover DNA unwinding experiments performed at higher DNA concentrations (50 nM) show a sigmoidal dependence of the extent of unwinding on the pre-incubated [UvrD], also indicating cooperativity. These results indicate that the form of the UvrD helicase with optimal helicase activity is oligomeric with at least two sites for binding the DNA substrate, where one site contacts regions of the 3'-ssDNA tail that are distal from the single-stranded/double-stranded DNA junction.

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.

A two-site kinetic mechanism for ATP binding and hydrolysis by E. coli Rep helicase dimer bound to a single-stranded oligodeoxynucleotide

Escherichia coli Rep helicase catalyzes the unwinding of duplex DNA in reactions that are coupled to ATP binding and hydrolysis. We have investigated the kinetic mechanism of ATP binding and hydrolysis by a proposed intermediate in Rep-catalyzed DNA unwinding, the Rep "P2S" dimer (formed with the single-stranded (ss) oligodeoxynucleotide, (dT)16), in which only one subunit of a Rep homo-dimer is bound to ssDNA. Pre-steady-state quenched-flow studies under both single turnover and multiple turnover conditions as well as fluorescence stopped-flow studies were used (4 degrees C, pH 7.5, 6 mM NaCl, 5 mM MgCl2, 10 % (v/v) glycerol). Although steady-state studies indicate that a single ATPase site dominates the kinetics (kcat=17(+/-2) s-1; KM=3 microM), pre-steady-state studies provide evidence for a two-ATP site mechanism in which both sites of the dimer are catalytically active and communicate allosterically. Single turnover ATPase studies indicate that ATP hydrolysis does not require the simultaneous binding of two ATP molecules, and under these conditions release of product (ADP-Pi) is preceded by a slow rate-limiting isomerization ( approximately 0.2 s-1). However, product (ADP or Pi) release is not rate-limiting under multiple turnover conditions, indicating the involvement of a second ATP site under conditions of excess ATP. Stopped-flow fluorescence studies monitoring ATP-induced changes in Rep's tryptophan fluorescence displayed biphasic time courses. The binding of the first ATP occurs by a two-step mechanism in which binding (k+1=1.5(+/-0.2)x10(7) M-1 s-1, k-1=29(+/-2) s-1) is followed by a protein conformational change (k+2=23(+/-3) s-1), monitored by an enhancement of Trp fluorescence. The second Trp fluorescence quenching phase is associated with binding of a second ATP. The first ATP appears to bind to the DNA-free subunit and hydrolysis induces a global conformational change to form a high energy intermediate state with tightly bound (ADP-Pi). Binding of the second ATP then leads to the steady-state ATP cycle. As proposed previously, the role of steady-state ATP hydrolysis by the DNA-bound Rep subunit may be to maintain the DNA-free subunit in an activated state in preparation for binding a second fragment of DNA as needed for translocation and/or DNA unwinding. We propose that the roles of the two ATP sites may alternate upon binding DNA to the second subunit of the Rep dimer during unwinding and translocation using a subunit switching mechanism.

The importance of coulombic end effects: experimental characterization of the effects of oligonucleotide flanking charges on the strength and salt dependence of oligocation (L8+) binding to single-stranded DNA oligomers

Binding constants Kobs, expressed per site and evaluated in the limit of zero binding density, are quantified as functions of salt (sodium acetate) concentration for the interactions of the oligopeptide ligand KWK6NH2 (designated L8+, with ZL = 8 charges) with three single-stranded DNA oligomers (ss dT-mers, with |ZD| = 15, 39, and 69 charges). These results provide the first systematic experimental information about the effect of changing |ZD| on the strength and salt dependence of oligocation-oligonucleotide binding interactions. In a comparative study of L8+ binding to poly dT and to a short dT oligomer (|ZD| = 10),. Proc. Natl. Acad. Sci. USA. 93:2511-2516) demonstrated the profound thermodynamic effects of phosphate charges that flank isolated nonspecific L8+ binding sites on DNA. Here we find that both Kobs and the magnitude of its power dependence on salt activity (|SaKobs|) increase monotonically with increasing |ZD|. The dependences of Kobs and SaKobs on |ZD| are interpreted by introducing a simple two-state thermodynamic model for Coulombic end effects, which accounts for our finding that when L8+ binds to sufficiently long dT-mers, both DeltaGobso = -RT ln Kobs and SaKobs approach the values characteristic of binding to poly-dT as linear functions of the reciprocal of the number of potential oligocation binding sites on the DNA lattice. Analysis of our L8+-dT-mer binding data in terms of this model indicates that the axial range of the Coulombic end effect for ss DNA extends over approximately 10 phosphate charges. We conclude that Coulombic interactions cause an oligocation (with ZL < |ZD|) to bind preferentially to interior rather than terminal binding sites on oligoanionic or polyanionic DNA, and we quantify the strong increase of this preference with decreasing salt concentration. Coulombic end effects must be considered when oligonucleotides are used as models for polyanionic DNA in thermodynamic studies of the binding of charged ligands, including proteins.

Calorimetric studies of E. coli SSB protein-single-stranded DNA interactions. Effects of monovalent salts on binding enthalpy

Isothermal titration calorimetry (ITC) was used to examine the effects of monovalent salts (NaCl, NaBr, NaF and ChCl) on the binding enthalpy (DeltaHobs) for E. coli SSB tetramer binding to the single-stranded oligodeoxythymidylates, dT(pT)69 and dT(pT)34 over a wide range of salt concentrations from 10 mM to 2.0 M (25 degrees C, pH 8.1), and when possible, the binding free energy and entropy (DeltaG degrees obs, DeltaS degrees obs). At low monovalent salt concentrations (<0.1 M), the total DeltaHobs for saturating all sites on the SSB tetramer with ssDNA shows little dependence on salt concentration, but is extremely large and exothermic (DeltaHobs=-150(+/-5) kcal/mol). This is much larger than any DeltaHobs previously reported for a protein-nucleic acid interaction. However, at salt concentrations above 0.1 M, DeltaHobs is quite sensitive to NaCl and NaBr concentration, becoming less negative with increasing salt concentration (DeltaHobs=-70(+/-1)-kcal/mol in 2 M NaBr). These salt effects on DeltaHobs were mainly a function of anion type and concentration, with the largest effects observed in NaBr, and then NaCl, with little effect of [NaF]. These large effects of salt on DeltaHobs appear to be coupled to a net release of weakly bound anions (Br- and Cl-) from the SSB protein upon DNA binding. However, at lower salt concentrations (</=0.1 M), specific cation effects on DeltaHobs also are observed. Under conditions where we can determine DeltaG degrees obs, DeltaS degrees obs, and DeltaHobs (25 degrees C, pH 8.1, 0.17 to 2 M NaBr), SSB binding to dT(pT)69 is enthalpically driven with a large unfavorable entropic contribution, both of which are dependent upon [NaBr]. These studies show that weak anion binding to a protein can result in large effects of salt concentration on DeltaHobs (as well as DeltaG degrees obs and DeltaS degrees obs) for a protein-ssDNA interaction. The possibility of such effects needs to be considered in any interpretation of the thermodynamics of this and other protein-nucleic acid interactions.

Comparisons between the structures of HCV and Rep helicases reveal structural similarities between SF1 and SF2 super-families of helicases

Three helicase structures have been determined recently: that of the DNA helicase PcrA, that of the hepatitis C virus RNA helicase, and that of the Escherichia coli DNA helicase Rep. PcrA and Rep belong to the same super-family of helicases (SF1) and are structurally very similar. In contrast, the HCV helicase belongs to a different super-family of helicases, SF2, and shows little sequence homology with the PcrA/Rep helicases. Yet, the HCV helicase is structurally similar to Rep/PcrA, suggesting preservation of structural scaffolds and relationships between helicase motifs across these two super-families. The comparison study presented here also reveals the existence of a new helicase motif in the SF1 family of helicases.

Kinetic mechanism for the sequential binding of two single-stranded oligodeoxynucleotides to the Escherichia coli Rep helicase dimer

Escherichia coli Rep helicase is a DNA motor protein that unwinds duplex DNA as a dimeric enzyme. Using fluorescence probes positioned asymmetrically within a series of single-stranded (ss) oligodeoxynucleotides, we show that ss-DNA binds with a defined polarity to Rep monomers and to individual subunits of the Rep dimer. Using fluorescence resonance energy transfer and stopped-flow techniques, we have examined the mechanism of ss-oligodeoxynucleotide binding to preformed Rep dimers in which one binding site is occupied by a single-stranded oligodeoxynucleotide, while the other site is free (P2S dimer). We show that ss-DNA binding to the P2S Rep dimer to form the doubly ligated P2S2 dimer occurs by a multistep process with the initial binding step occurring relatively rapidly with a bimolecular rate constant of k1 = approximately 2 x 10(6) M-1 s-1 [20 mM Tris (pH 7.5), 6 mM NaCl, 5 mM MgCl2, 5 mM 2-mercaptoethanol, and 10% (v/v) glycerol, 4 degrees C]. A minimal kinetic mechanism is proposed which suggests that the two strands of ss-DNA bound to the Rep homodimer are kinetically distinct even within the P2S2 Rep dimer, indicating that this dimer is functionally asymmetric. The implications of these results for the mechanisms of DNA unwinding and translocation by the functional Rep dimer are discussed.

Major domain swiveling revealed by the crystal structures of complexes of E. coli Rep helicase bound to single-stranded DNA and ADP

Crystal structures of binary and ternary complexes of the E. coli Rep helicase bound to single-stranded (ss) DNA or ssDNA and ADP were determined to a resolution of 3.0 A and 3.2 A, respectively. The asymmetric unit in the crystals contains two Rep monomers differing from each other by a large reorientation of one of the domains, corresponding to a swiveling of 130 degrees about a hinge region. Such domain movements are sufficiently large to suggest that these may be coupled to translocation of the Rep dimer along DNA. The ssDNA binding site involves the helicase motifs Ia, III, and V, whereas the ADP binding site involves helicase motifs I and IV. Residues in motifs II and VI may function to transduce the allosteric effects of nucleotides on DNA binding. These structures represent the first view of a DNA helicase bound to DNA.

Crystal structure of the homo-tetrameric DNA binding domain of Escherichia coli single-stranded DNA-binding protein determined by multiwavelength x-ray diffraction on the selenomethionyl protein at 2.9-A resolution

The crystal structure of the tetrameric DNA-binding domain of the single-stranded DNA binding protein from Escherichia coli was determined at a resolution of 2.9 A using multiwavelength anomalous dispersion. Each monomer in the tetramer is topologically similar to an oligomer-binding fold. Two monomers each contribute three beta-strands to a single six-stranded beta-sheet to form a dimer. Two dimer-dimer interfaces are observed within the crystal. One of these stabilizes the tetramer in solution. The other interface promotes a superhelical structure within the crystal that may reflect tetramer-tetramer interactions involved in the positive cooperative binding of the single-stranded DNA-binding protein to single-stranded DNA.

Thermodynamics of oligoarginines binding to RNA and DNA

We have examined the equilibrium binding of a series of synthetic oligoarginines (net charge z = +2 to +6) containing tryptophan to poly(U), poly(A), poly(C), poly(I), and double-stranded (ds) DNA. Equilibrium association constants, K(obs), measured by monitoring tryptophan fluorescence quenching, were examined as functions of monovalent salt (MX) concentration and type, as well as temperature, from which deltaG(standard)obs, deltaH(obs), and deltaS(standard)obs were determined. For each peptide, K(obs) decreases with increasing [K+], and the magnitude of the dependence of K(obs) on [K+], delta log K(obs)/delta log[K+], increases with increasing net peptide charge. In fact, the values of delta log K(obs)/delta log[K+] are equivalent for oligolysines and oligoarginines possessing the same net positive charge. However, the values of K(obs) are systematically greater for oligoarginines binding to all polynucleotides, when compared to oligolysines with the same net charge. The origin of this difference is entirely enthalpic, with deltaH(obs), determined from van't Hoff analysis, being more exothermic for oligoarginine binding. The values of deltaH(obs) are also independent of [K+]; therefore, the salt concentration dependence of deltaG(standard)obs is entirely entropic in origin, reflecting the release of cations from the nucleic acid upon complex formation. These results suggest that hydrogen bonding of arginine to the phosphate backbone of the nucleic acids contributes to the increased stability of these complexes.

A two-site mechanism for ATP hydrolysis by the asymmetric Rep dimer P2S as revealed by site-specific inhibition with ADP-A1F4

The Escherichia coli Rep helicase is a dimeric motor protein that catalyzes the transient unwinding of duplex DNA to form single-stranded (ss) DNA using energy derived from the binding and hydrolysis of ATP. In an effort to understand this mechanism of energy transduction, we have used pre-steady-state methods to study the kinetics of ATP binding and hydrolysis by an important intermediate in the DNA unwinding reaction--the asymmetric Rep dimer state, P2S, where ss DNA [dT(pT)15] is bound to only one subunit of the Rep dimer. To differentiate between the two potential ATPase active sites inherent in the dimer, we constructed dimers with one subunit covalently cross-linked to ss DNA and where one or the other of the ATPase sites was selectively complexed to the tightly bound transition state analog ADP-A1F4. We found that when ADP-A1F4 is bound to the Rep subunit in trans from the subunit bound to ss DNA, steady-state ATPase activity of 18 s(-1) per dimer (equivalent to wild-type P2S) was recovered. However, when the ADP-A1F4 and ss DNA are both bound to the same subunit (cis), then a titratable burst of ATP hydrolysis is observed corresponding to a single turnover of ATP. Rapid chemical quenched-flow techniques were used to resolve the following minimal mechanism for ATP hydrolysis by the unligated Rep subunit of the cis dimer: E + ATP <==> E-ATP <==> E'-ATP <==> E'-ADP-Pi <==> E-ADP-Pi <==> E-ADP + Pi <==> E + ADP + Pi, with K1 = (2.0 +/- 0.85) x 10(5) M(-1), k2 = 22 +/- 3.5 s(-1), k(-2) < 0.12 s(-1), K3 = 4.0 +/- 0.4 (k3 > 200 s(-1)), k4 = 1.2 +/- 0.14 s(-1), k(-4) << 1.2 s(-1), K5 = 1.0 +/- 0.2 mM, and K6 = 80 +/- 8 microM. A salient feature of this mechanism is the presence of a kinetically trapped long-lived tight nucleotide binding state, E'-ADP-Pi. In the context of our "subunit switching" model for Rep dimer translocation during processive DNA unwinding [Bjornson, K. B., Wong, I., & Lohman, T. M. (1996) J. Mol. Biol. 263, 411-422], this state may serve an energy storage function, allowing the energy from the binding and hydrolysis of ATP to be harnessed and held in reserve for DNA unwinding.

A mutation in E. coli SSB protein (W54S) alters intra-tetramer negative cooperativity and inter-tetramer positive cooperativity for single-stranded DNA binding

E. coli SSB tetramer binds with high affinity and cooperatively to single-stranded (ss) DNA and functions in replication, recombination and repair. Curth et al. (Biochemistry, 32 (1993) 2585-2591) have shown that a mutant SSB protein, in which Trp-54 has been replaced by Ser (W54S) in each subunit, binds preferentially to ss-polynucleotides in the (SSB)35 mode in which only 35 nucleotides are occluded per tetramer under conditions in which wild-type (wt) SSB binds in its (SSB)65 mode. The W54S mutant also displays increased UV sensitivity and slow growth phenotypes, suggesting defects in vivo in both repair and replication (Carlini et al. (Molecular Microbiology, 10 (1993) 1067)). We have characterized the energetics of SSBW54S binding to poly(dT) as well as short oligodeoxyribonucleotides (dA(pA)69, dT(pT)34, dC(pC)34) to determine the basis for this dramatic change in binding mode preference. We find that the W54S mutant remains a stable tetramer; however, its affinity for ss-DNA as well as both the intra-tetramer negative cooperativity and its inter-tetramer positive cooperativity in the (SSB)35 mode (omega 35) are altered significantly compared to wtSSB. The increased intra-tetramer negative cooperativity makes it more difficult for ss-DNA to bind the third and fourth subunits of the W54S tetramer, explaining the increased stability of the (SSB)35 mode in complexes with poly(dT). When bound to dA(pA)69 in the (SSB)35 mode, W54S tetramer also displays a dramatically lower inter-tetramer positive cooperativity (omega 35 = 77(+/-20)) than wtSSB (omega 35 > or = 10(5)) as well as a significantly lower affinity for ss-DNA. These results indicate that a single amino acid change can dramatically influence the ability of SSB tetramers to bind in the different SSB binding modes. The altered ss-DNA properties of the W54S SSB mutant are probably responsible for the observed defects in replication and repair and support the proposal that the different SSB binding modes may function selectively in replication, recombination and/or repair.

Kinetic measurement of the step size of DNA unwinding by Escherichia coli UvrD helicase

The kinetic mechanism by which the DNA repair helicase UvrD of Escherichia coli unwinds duplex DNA was examined with the use of a series of oligodeoxynucleotides with duplex regions ranging from 10 to 40 base pairs. Single-turnover unwinding experiments showed distinct lag phases that increased with duplex length because partially unwound DNA intermediate states are highly populated during unwinding. Analysis of these kinetics indicates that UvrD unwinds duplex DNA in discrete steps, with an average "step size" of 4 to 5 base pairs (approximately one-half turn of the DNA helix). This suggests an unwinding mechanism in which alternating subunits of the dimeric helicase interact directly with duplex DNA.

ATP hydrolysis stimulates binding and release of single stranded DNA from alternating subunits of the dimeric E. coli Rep helicase: implications for ATP-driven helicase translocation

DNA helicases are motor proteins that unwind duplex DNA during DNA replication, recombination and repair in reactions that are coupled to ATP binding and hydrolysis. In the process of unwinding duplex DNA processively, DNA helicases must also translocate along the DNA filament. To probe the mechanism of ATP-driven translocation by the dimeric E. coli Rep helicase along single stranded (ss) DNA, we examined the effects of ATP on the dissociation kinetics of ssDNA from the Rep dimer. Stopped-flow experiments show that the dissociation rate of a fluorescent ss oligodeoxynucleotide bound to one subunit of the dimeric Rep helicase is stimulated by ssDNA binding to the other subunit, and that the rate of this ssDNA exchange reaction is further stimulated approximately 60-fold upon ATP hydrolysis. This ssDNA exchange process occurs via an intermediate in which ssDNA is transiently bound to both subunits of the Rep dimer. These results suggest a rolling or subunit switching mechanism for processive ATP-driven translocation of the dimeric Rep helicase along ssDNA. Such a mechanism requires the extreme negative cooperativity for DNA binding to the second subunit of the Rep dimer, which insures that the doubly DNA-ligated Rep (P2S2) dimer is formed only transiently and relaxes back to the singly ligated Rep (P2S) dimer. The fact that other oligomeric DNA helicases share many functional features with the dimeric Rep helicase suggests that similar mechanisms for translocation and DNA unwinding may apply to other dimeric as well as hexameric DNA helicases.

ATPase activity of Escherichia coli Rep helicase crosslinked to single-stranded DNA: implications for ATP driven helicase translocation

To examine the coupling of ATP hydrolysis to helicase translocation along DNA, we have purified and characterized complexes of the Escherichia coli Rep protein, a dimeric DNA helicase, covalently crosslinked to a single-stranded hexadecameric oligodeoxynucleotide (S). Crosslinked Rep monomers (PS) as well as singly ligated (P2S) and doubly ligated (P2S2) Rep dimers were characterized. The equilibrium and kinetic constants for Rep dimerization as well as the steady-state ATPase activities of both PS and P2S crosslinked complexes were identical to the values determined for un-crosslinked Rep complexes formed with dT16. Therefore, ATP hydrolysis by both PS and P2S complexes are not coupled to DNA dissociation. This also rules out a strictly unidirectional sliding mechanism for ATP-driven translocation along single-stranded DNA by either PS or the P2S dimer. However, ATP hydrolysis by the doubly ligated P2S2 Rep dimer is coupled to single-stranded DNA dissociation from one subunit of the dimer, although loosely (low efficiency). These results suggest that ATP hydrolysis can drive translocation of the dimeric Rep helicase along DNA by a "rolling" mechanism where the two DNA binding sites of the dimer alternately bind and release DNA. Such a mechanism is biologically important when one subunit binds duplex DNA, followed by subsequent unwinding.

Mechanisms of helicase-catalyzed DNA unwinding

DNA helicases are essential motor proteins that function to unwind duplex DNA to yield the transient single-stranded DNA intermediates required for replication, recombination, and repair. These enzymes unwind duplex DNA and translocate along DNA in reactions that are coupled to the binding and hydrolysis of 5'-nucleoside triphosphates (NTP). Although these enzymes are essential for DNA metabolism, the molecular details of their mechanisms are only beginning to emerge. This review discusses mechanistic aspects of helicase-catalyzed DNA unwinding and translocation with a focus on energetic (thermodynamic), kinetic, and structural studies of the few DNA helicases for which such information is available. Recent studies of DNA and NTP binding and DNA unwinding by the Escherichia coli (E. coli) Rep helicase suggest that the Rep helicase dimer unwinds DNA by an active, rolling mechanism. In fact, DNA helicases appear to be generally oligomeric (usually dimers or hexamers), which provides the helicase with multiple DNA binding sites. The apparent mechanistic similarities and differences among these DNA helicases are discussed.

ATPase activity of Escherichia coli Rep helicase is dramatically dependent on DNA ligation and protein oligomeric states

The Escherichia coli Rep helicase catalyzes the unwinding of duplex DNA using the energy derived from ATP binding and hydrolysis. Rep functions as a dimer but assembles to its active dimeric form only on binding DNA. Each promoter of a dimer contains a DNA binding site that can bind either single-stranded (S) or duplex (D) DNA. The dimer can bind up to two oligodeoxynucleotides in five DNA-ligation states: two half-ligated states, P2S and P2D, and three fully-ligated states, P2S2, P2D2, and P2SD. We have previously shown that the relative stabilities of these ligation states are allosterically regulated by the binding and hydrolysis of ATP and have proposed an "active rolling" model for DNA unwinding where the enzyme cycles through a series of these ligation states in a process that is coupled to the catalytic cycle of ATP hydrolysis [Wong, I., & Lohman, T.M., (1992), Science 256, 350-355]. THe basal ATPase activity of Rep protein is stimulated by ss DNA binding and by protein dimerization. We have measured the steady-state ATPase activities of Rep bound to dT(pT)15 in each distinct ss DNA ligation state (PS, P2S, and P2S2) to compare with our previous measurements with unligated Rep monomer (P) [Moore, K.J.M., & Lohman, T.M. (1994) Biochemistry 33, 14550]. We find the ATPase activity of Rep is influenced dramatically by both dimerization and ss DNA ligation state, with the following kcat values for ATP hydrolysis increasing by over 4 orders of magnitude: 2.1 x 10(-3) s(-1) for P, 2.17 +/- 0.04 s(-1) for PS, 16.5 +/- 0.2 s(-1) for P2S, and 71 +/- 2.5 s(-1) for P2S2 (20 mM Tris-HCl, pH 7.5, 6mM NaCl, 5 mM MgCl2, 10% glycerol, 4 degrees C). The apparent KM's for ATP hydrolysis are 2.05 +/- 0.1 microM for PS and 2.7 +/- 0.2 microM for P2S. These widely different ATPase activities reflect the allosteric effects of DNA ligation and demonstrate that cooperative communication occurs between the ATP and DNA site of both subunits of the Rep dimer. These results further emphasize the need to explicitly consider the population distribution of oligomerization and DNA ligation states of the helicase when attempting to infer information about elementary processes such as helicase translocation based solely on macroscopic steady-state ATPase measurements.

A highly salt-dependent enthalpy change for Escherichia coli SSB protein-nucleic acid binding due to ion-protein interactions

We have examined the linkage between salt concentration and temperature for the equilibrium binding of the tetrameric Escherichia coli single-stranded binding (SSB) protein to three single-stranded nucleic acids, poly(U), dA(pA)69, and dT(pT)69, by van't Hoff analysis and isothermal titration calorimetry (ITC). For SSB binding to poly(U) in its (SSB)65 mode, the equilibrium association constant, Kobs, decreases with increasing salt concentration at all temperatures examined, and binding is enthalpy-drive; however, the value of [symbol see text] log Kobs/ [symbol see text] log [NaCl] is highly temperature- dependent, varying from -9.3 +/- 0.3 at 10 degrees C to -5.1 +/- 0.4 at 37 degrees C. This indicates that delta Hobs for SSB-poly(U) binding is strongly dependent on [NaCl]; based on van't Hoff analyses, delta Hobs varies from -57 +/- 3 kcal/mol at 0.18 M NaCl to -34 +/- 3 kcal/mol at 042 M NaCl ([symbol see text] delta Hobs/[symbol see text] log [NaCl] = 60 +/- 5 kcal/mol). However, [symbol see text] delta Hobs/[symbol see text] log [NaF] is independent of temperature (25-37 degrees C), indicating that the effect of [NaCl] on delta Hobs is due primarily to Cl-. Similar effects were also observed for SSB binding to dA(pA)69. We also measured delta Hobs and its dependence on [NaCl] for SSB binding dT(pT)69 by ITC and find delta Hobs = -144 +/- 4 kcal/mol (0.175 M NaCl, pH 8.1, 25 degrees C) and [symbol see text] delta Hobs/ [symbol see text] log [NaCl] = 46 +/- 2 kcal/ mol (0.175-2.0 M NaCl). These large effects of [NaCl] on delta Hobs appear to result, at least partly, from the release of preferentially bound Cl- from SSB protein upon binding nucleic acid, with the release of Cl- being linked to a process with delta H > > 0. Effects of salt concentration on delta Hobs are not observed for processes in which only monovalent cations are released from the nucleic acid, presumably since Na+ of K+ are bound to linear nucleic acids as delocalized, fully hydrated cations. Such salt effects on delta Hobs may serve as a signature for differential ion-protein binding. These results underscore the need to examine the linkage of [salt] to delta Hobs, as well as delta Hobs degrees and delta S(obs) degrees, in order to understand the bases for stability and specificity of protein-nucleic acid interactions.

Large electrostatic differences in the binding thermodynamics of a cationic peptide to oligomeric and polymeric DNA

Results presented here demonstrate that the thermodynamics of oligocation binding to polymeric and oligomeric DNA are not equivalent because of long-range electrostatic effects. At physiological cation concentrations (0.1-0.3 M) the binding of an oligolysine octacation KWK6-NH2 (+8 charge) to single-stranded poly(dT) is much stronger per site and significantly more salt concentration dependent than the binding of the same ligand to an oligonucleotide, dT(pdT)10 (-10 charge). These large differences are consistent with Poisson-Boltzmann calculations for a model that characterizes the charge distributions with key preaveraged structural parameters. Therefore, both the experimental and the theoretical results presented here show that the polyelectrolyte character of a polymeric nucleic acid makes a large contribution to both the magnitude and the salt concentration dependence of its binding interactions with simple oligocationic ligands.

Kinetic mechanism of DNA binding and DNA-induced dimerization of the Escherichia coli Rep helicase

The monomeric Escherichia coli Rep protein undergoes a DNA-induced dimerization upon binding either single-stranded (ss) or duplex DNA with the dimer being the active form of the Rep helicase. Using stopped-flow fluorescence, we have determined a minimal kinetic mechanism for this reaction in which Rep monomer (P) binds to ss oligodeoxynucleotides (dN(pN)15) (S) by a two-step mechanism to form PS*, which can then dimerize with P to form P2S as indicated: [reaction in text]. This minimal mechanism is supported by four independent studies in which the kinetics were monitored by changes in fluorescence intensity of three different probes: the intrinsic Rep tryptophan fluorescence, the fluorescence of d(T5(2-AP)T4(2-AP)T5), containing the fluorescent base, 2-aminopurine (2-AP), and dT(pT)15 labeled at its 3'-end with fluorescein (3'-F-dT(pT)15). Simultaneous (global) analysis of the time courses of d(T5(2-AP)T4(2-AP)T5) (100 nM) binding to a range of Rep monomer concentrations (25-400 nM) yields the following rate constants: k1 = (3.3 +/- 0.5) x 10(7) M-1 s-1; k-1 = 1.4 +/- 0.4 s-1; k2 = 2.7 +/- 0.9 s-1; k-2 = 0.21 +/- 0.06 s-1; k3 = (4.5 +/- 0.3) x 10(5) M-1 s-1; k-3 = 0.0027 +/- 0.0008 s-1 [20 mM Tris-HCl, pH 7.5, 6 mM NaCl, 5 mM MgCl2, 5 mM 2-mercaptoethanol, and 10% (v/v) glycerol, 4.0 degrees C]. This mechanism provides direct evidence that Rep monomers can bind ss DNA and that ss DNA binding induces a conformational change in the Rep monomer that is probably required for Rep dimerization. This conformational change is likely to be large and global since it is detected by all three fluorescence probes. The apparent bimolecular rate constant for Rep monomer binding to 3'-F-dT(pT)15 [k1(app) = (6.0 +/- 0.7) x 10(7) M-1 s-1] is slightly larger than measured with d(T5(2-AP)T4(2-AP)T5) binding. The apparent rate constant for dissociation of d(T5(2-AP)T4(2-AP)T5) (S) from the half-ligated Rep dimer, P2S, increases with increasing concentration of a nonfluorescent competitor ss DNA (d(T5-AT4AT5)) (C), indicating transient formation of a doubly ligated P2SC intermediate. However, the apparent bimolecular rate constant for binding of C to P2S is extremely slow (> or = 250 M-1 s-1), suggesting the occurrence of a multistep process before dissociation of ss DNA. In the absence of competitor DNA, dissociation of ss DNA from P2S occurs only after slow dissociation of the Rep dimer to form PS* + P. The implications of these results for Rep-catalyzed DNA unwinding are discussed.

Helicase-catalyzed DNA unwinding: energy coupling by DNA motor proteins

DNA helicases catalyze the unwinding of double-stranded (ds) DNA to yield the single-stranded (ss) DNA intermediates required in DNA replication, recombination, and repair. DNA helicases couple the free energy of nucleoside triphosphate (NTP) binding and hydrolysis to separate the two complementary DNA strands while also translocating vectorially along the DNA substrate. As such, helicases are functionally DNA motor proteins. The functional form of helicases generally appears to be oligomeric (usually dimers or hexamers), which provides the helicase with multiple DNA binding sites that are required for translocation and DNA unwinding. The affinity of ss- versus dsDNA for these multiple DNA binding sites is modulated allosterically by NTP binding, hydrolysis, and product release, which is central to helicase-catalyzed DNA unwinding. The mechanistic details of the DNA unwinding, translocation, and NTPase reactions are only starting to emerge. We discuss energy coupling by DNA helicases in general, and by the dimeric E. coli Rep helicase in particular, focusing on the similarities of these enzymes to classical motor proteins.

Thermodynamics of charged oligopeptide-heparin interactions

To better understand the electrostatic component of the interaction between proteins and the polyanion heparin, we have investigated the thermodynamics of heparin binding to positively charged oligopeptides containing lysine or arginine and tryptophan (KWK-CO2 and RWR-CO2). The binding of these peptides to heparin is accompanied by an enhancement of the peptide tryptophan fluorescence, and we have used this to determine equilibrium binding constants. The extent of fluorescence enhancement is similar for both peptides, suggesting that the tryptophan interaction is similar for both. Titrations of these peptides with a series of simple salts suggest that this fluorescence enhancement is due to the interaction of tryptophan with sulfate moieties on the heparin. Equilibrium association constants, Kobs (M-1), for each peptide binding to heparin were measured as a function of temperature and monovalent salt concentration in the limit of low peptide binding density. At pH 6.0, 25 degrees C, 20 mM KCH3CO2, Kobs = 3.2 (+/- 0.3) x 10(3) M-1 for KWK-CO2 binding, whereas Kobs = 4.5 (+/- 0.5) x 10(3) M-1 for RWR-CO2. However, the dependence of Kobs on KCH3CO2 concentration is the same for both oligopeptides, each of which possesses a net charge of +2 at pH 6.0. The logarithm of Kobs is a linear function of the logarithm of [KCH3CO2] over the range from 12 mM < or = KCH3CO2 < or = 30 mM (pH 6.0, 25 degrees C), with (delta log Kobs/delta log [KCH3CO2]) = -2.0 +/- 0.3, indicating that approximately 2 ions are released per bound peptide upon formation of the complex.(ABSTRACT TRUNCATED AT 250 WORDS)

Kinetic mechanism of adenine nucleotide binding to and hydrolysis by the Escherichia coli Rep monomer. 1. Use of fluorescent nucleotide analogues

The Escherichia coli Rep helicase catalyzes the unwinding of duplex DNA in a reaction that is coupled to ATP binding and hydrolysis. The Rep protein is a stable monomer in the absence of DNA but dimerizes upon binding either single-stranded or duplex DNA, and the dimer appears to be the functionally active form of the Rep helicase. As a first step toward understanding how ATP binding and hydrolysis are coupled energetically to DNA unwinding, we have investigated the kinetic mechanism of nucleotide binding to the Rep monomer (P) using stopped-flow techniques and the fluorescent ATP analogue, 2'(3')-O-(N-methylanthraniloyl-ATP (mantATP). The fluorescence of mantATP is enhanced upon Rep binding due to energy transfer from tryptophan. The results are consistent with the following two-step mechanism, in which the bimolecular association step is followed by a conformational change in the P-mantATP complex: P + mantATP [formula: see text] P-mantATP [formula: see text] (P-mantATP). The following rate and equilibrium constants were determined at 4 degrees C in 20 mM Tris.HCl (pH 7.5), 6 mM NaCl, 5 mM MgCl2, and 10% (v/v) glycerol: k+1 = (1.1 +/- 0.2) x 10(7) M-1 s-1; k-1 = 3.2 (+/- 0.5) s-1; k+2 = 2.9 (+/- 0.5) s-1; k-2 = 0.04 (+/- 0.005) s-1; K1 = k+1/k-1 = (3.4 +/- 0.8) x 10(6) M-1; K2 = k+2/k-2 = 73 (+/- 10); Koverall = K1K2 = (2.30 +/- 0.6) x 10(8) M-1. Similar rate and equilibrium constants are obtained with mantATP gamma S, whereas the apparent rate constant for mantAMPPNP binding is 15-fold lower than for mantATP and equilibrium binding is weaker (Koverall approximately 10(6) M-1). Rep monomer does bind mantATP in the absence of Mg2+ (Koverall approximately 5 x 10(5) M-1), although the four rate constants in the above reaction increase by at least 8-fold (k-1 and k-2 increase by approximately 100- and approximately 1000-fold, respectively). The affinities of Mg2+ for P-mantATP and (P-mantATP)* are 10- and 1000-fold higher than those for nucleotide-free Rep monomer, indicating that the second step in the reaction is associated with a marked increase in Mg2+ affinity. The bound Mg2+ in a (P-mantATP)*-Mg2+ complex dissociates at a rate that is comparable to the rate of mantATP release.(ABSTRACT TRUNCATED AT 400 WORDS)

Kinetic mechanism of adenine nucleotide binding to and hydrolysis by the Escherichia coli Rep monomer. 2. Application of a kinetic competition approach

The Escherichia coli Rep protein is a DNA helicase that functions as a homodimer to catalyze the unwinding of duplex DNA during DNA replication in a reaction that is coupled to the binding and hydrolysis of ATP. As a first step toward a molecular understanding of the interactions of Rep with adenine nucleotides, we have investigated the kinetic mechanism of adenine nucleotide binding to the Rep monomer, which is the state of the protein in the absence of DNA. Although ATP binding to Rep does not significantly change the intrinsic tryptophan fluorescence, the binding of the fluorescent nucleotide analogue, 2'(3')-O-(N-methylanthraniloyl)-ATP (mantATP) is associated with a large increase in mant nucleotide fluorescence intensity [lambda ex = 290 nm, lambda em > 420 nm; Moore, K. J. M., & Lohman, T. M. (1994) Biochemistry (preceding article in this issue)]. We have used the fluorescence signal from mantATP binding to monitor the kinetics of nonfluorescent nucleotide binding to Rep by a kinetic competition approach. The simultaneous and parallel binding of a mixture of mantATP and ATP to the Rep monomer is associated with a complex triphasic fluorescence transient during the approach to equilibrium. Global analysis of the fluorescence transients over a range of [ATP] by numerical integration techniques was used to define the kinetic mechanism of ATP binding and to determine the elementary rate constants. Using this approach, the kinetic rate constants for ADP, ATP gamma S, AMPPNP, AMP, adenosine, and inorganic phosphate were also determined at 4 degrees C in 20 mM Tris.HCl (pH 7.5), 6 mM NaCl, 10% (v/v) glycerol, and 5 mM MgCl2. The kinetics of adenine nucleotide binding to the Rep monomer are similar to those observed with the mant nucleotides under identical experimental conditions (Moore & Lohman, 1994). The kinetic competition data are consistent with the following two-step mechanism for the binding of ATP, ADP, and ATP gamma S, where P is the Rep monomer and A is the adenine nucleotide: P+A [formula: see text] P-A [formula: see text] (P-A). In the presence of 5 mM MgCl2, the values of K+1 (approximately 10(7) M-1 s-1) and k+2 (approximately 10 s-1) are comparable for each nucleotide, whereas k+2 > k-1 for ATP and ATP gamma S while for ADP k+2 << k-1; hence, differences in the overall equilibrium binding affinities of these nucleotides are primarily due to changes in k-1.(ABSTRACT TRUNCATED AT 400 WORDS)

Single-turnover kinetics of helicase-catalyzed DNA unwinding monitored continuously by fluorescence energy transfer

We describe a fluorescence assay that can be used to monitor helicase-catalyzed unwinding of duplex DNA continuously in real time. The assay is based on the observation that fluorescence resonance energy transfer (FRET) occurs between donor (fluorescein) and acceptor (hexachlorofluorescein) fluorophores that are in close proximity due to their covalent attachment to the 3' and 5' ends of the complementary strands of a duplex oligodeoxynucleotide. FRET results in a reduction in the fluorescence emission intensity of fluorescein in the duplex DNA substrate relative to that observed for fluorescein-labeled single stranded DNA. Therefore, an enhancement of fluorescein fluorescence (lambda ex = 492 nm; lambda em = 520 nm) occurs upon helicase-catalyzed unwinding of the duplex DNA and separation of the complementary strands. The fluorescence assay is extremely sensitive, allowing DNA unwinding reactions to be monitored continuously at DNA concentrations as low as 1 nM in a fluorescence stopped-flow experiment. We demonstrate the use of this DNA substrate in pre-steady state, single turnover studies of duplex DNA unwinding catalyzed by the Escherichia coli Rep helicase, monitored by fluorescence stopped flow. We show that the fluorescence enhancement monitors Rep-catalyzed DNA unwinding by comparisons with identical kinetic studies carried out using rapid chemical quench-flow techniques. Single turnover kinetic studies performed at 1 nM DNA as a function of excess Rep concentration show that Rep-catalyzed unwinding of an 18 base pair duplex containing a 3'-ss-(dT)20 tail is biphasic and can be described by the sum of two exponential terms. The observed rate constant of the first phase is independent of [Rep] (20-300 nM) and measures the rapid single turnover, unwinding of the duplex DNA by Rep dimers bound in productive complexes (1.3 +/- 0.2 s-1; 23 +/- 3 base pairs s-1 at 25.0 degrees C). The observed rate constant for the second phase increases linearly with [Rep], reflecting DNA unwinding that is limited by a Rep binding event occurring with a bimolecular rate constant of (1.8 +/- 0.1) x 10(5) M-1 s-1, which may reflect the rate constant for Rep dimerization on DNA. Kinetic competition studies indicate that both Rep subunits are bound stably to the DNA substrate in the productive complex that is unwound in the fast phase. The results of these kinetic studies are consistent with an active, rolling mechanism for Rep-catalyzed unwinding of DNA [Wong, I., & Lohman, T. M., (1992) Science 256, 350].(ABSTRACT TRUNCATED AT 400 WORDS)

Apparent heat capacity change accompanying a nonspecific protein-DNA interaction. Escherichia coli SSB tetramer binding to oligodeoxyadenylates

We have examined the effects of temperature on the equilibrium constant, Kobs, for Escherichia coli SSB tetramer binding to a series of single-stranded (ss) oligodeoxyribonucleotides, dT(pT)n, dC(pC)n, and dA(pA)n (n = 34, 55, and 69) in order to investigate the thermodynamic basis for the strong preference of E. coli SSB (and other SSB proteins) for binding polypyrimidine stretches of ss-DNA. In addition to the expected base-dependent differences in the magnitude of Kobs, we also observe qualitatively different temperature dependencies for the binding of the SSB tetramer to oligodeoxyadenylates. Linear van't Hoff plots are obtained for SSB tetramer binding to dT(pT)n and dC(pC)n, with delta H0obs ranging from -50 to -100 kcal/mol depending on the oligodeoxynucleotide length and salt concentration. In contrast, all van't Hoff plots for SSB tetramer binding to dA(pA)N are distinctly nonlinear with maxima in K(obs) occurring near 25 degrees C, indicative of an apparent large negative change in molar heat capacity (delta C0P,obs < 0). Thus for the SSB-dA(pA)n interaction, delta H0obs and delta S0obs are both highly temperature dependent, but compensate such that delta G0obs is relatively insensitive to temperature. These nonlinear nonlinear van't Hoff plots are not due to coupling of SSB assembly to dA(pA)n binding or to temperature-dependent shifts in the formation of other SSB-DNA binding modes. The nonlinear van't Hoff plots for SSB tetramer binding to dA(pA)n appear to result from the coupling of two processes: (1) the unstacking of the dA(pA)n bases (occurring with delta H0 > 0 and delta C0P = 0) and (2) the binding of SSB to the unstacked DNA (occurring with delta H0 < 0 and delta C0P = 0). Therefore, although each isolated equilibrium occurs with delta C0P approximately 0, the overall equilibrium displays an apparent delta C0P,obs < 0 due to the coupled equilibrium. The binding of SSB to dT(pT)n and dC(pC)n occurs with delta H0 < 0 and delta C0P,obs = 0, since the bases in these ss-DNA molecules do not stack appreciably. These results indicate that a nonspecific protein-DNA interaction can display a large negative apparent delta C0P; however, this effect appears not to be due to the hydrophobic effect, but rather to a temperature-dependent conformational transition in the DNA that is coupled to protein binding. Implications of these observations for other protein-nucleic acid systems are discussed.

Escherichia coli single-stranded DNA-binding protein: multiple DNA-binding modes and cooperativities

There are now several well-documented SSBs from both prokaryotes and eukaryotes that function in replication, recombination, and repair; however, no "consensus" view of their interactions with ssDNA has emerged. Although these proteins all bind preferentially and with high affinity to ssDNA, their modes of binding to ssDNA in vitro, including whether they bind with cooperativity, often differ dramatically. This point is most clear upon comparing the properties of the phage T4 gene 32 protein and the E. coli SSB protein. Depending on the solution conditions, Eco SSB can bind ssDNA in several different modes, which display quite different properties, including cooperativity. The wide range of interactions with ssDNA observed for Eco SSB is due principally to its tetrameric structure and the fact that each SSB protomer (subunit) can bind ssDNA. This reflects a major difference between Eco SSB and the T4 gene 32 protein, which binds DNA as a monomer and displays "unlimited" positive cooperativity in its binding to ssDNA. The Eco SSB tetramer can bind ssDNA with at least two different types of nearest-neighbor positive cooperativity ("limited" and "unlimited"), as well as negative cooperativity among the subunits within an individual tetramer. In fact, this latter property, which is dependent upon salt concentration and nucleotide base composition, is a major factor influencing whether ssDNA interacts with all four or only two SSB subunits, which in turn determines the type of intertetramer positive cooperativity. Hence, it is clear that the interactions of Eco SSB with ssDNA are quite different from those of T4 gene 32 protein, and the idea that all SSBs bind to ssDNA as does the T4 gene 32 protein must be amended. Although it is not yet known which of the Eco SSB-binding modes is functionally important in vivo, it is possible that some of the modes are used preferentially in different DNA metabolic processes. In any event, the vastly different properties of the Eco SSB-binding modes must be considered in studies of DNA replication, recombination, and repair in vitro. Since eukaryotic mitochondrial SSBs as well as SSBs encoded by prokaryotic conjugative plasmids are highly similar to Eco SSB, these proteins are likely to show similar complexities. However, based on their heterotrimeric subunit composition, the eukaryotic nuclear SSBs (RP-A proteins) are significantly different from either Eco SSB or T4 gene 32 proteins. Further subclassification of these proteins must await more detailed biochemical and biophysical studies.

Effects of base composition on the negative cooperativity and binding mode transitions of Escherichia coli SSB-single-stranded DNA complexes

We have examined the ability of the Escherichia coli single-stranded DNA binding protein (SSB) tetramer to form its different binding modes on poly(dC), poly(U), and poly(A) over a range of NaCl and NaF concentrations for comparison with previous studies with poly(dT). In reverse titrations with poly(U) and poly(A) at 25 degrees C, pH 8.1, SSB forms all four binding modes previously observed with poly(dT), namely, (SSB)35, (SSB)40, (SSB)56, and (SSB)65, where the subscript denotes the site size (i.e., the average number of nucleotides occluded per SSB tetramer). As with poly(dT), the low site size modes are favored at low monovalent salt concentration (< 10 mM), whereas increasing salt concentration facilitates the transitions to the higher site size modes. Surprisingly, SSB does not form a stable (SSB)35 complex on poly(dC), even at 1 mM NaCl; rather, the (SSB)56 mode is formed under these conditions. Upon raising the [NaCl], the (SSB)56 complex undergoes a transition to the (SSB)65 complex (transition midpoint, 40 mM NaCl). On the basis of studies with dC(pC)34, dT(pT)34, and dA(pA)34, the inability of the SSB tetramer to form the (SSB)35 complex with poly(dC) is due mainly to a much lower degree of negative cooperativity for binding oligodeoxycytidylates to the SSB tetramer. At low salt concentration, the negative cooperativity parameter, sigma 35, is lowest for dA(pA)34, intermediate for dT(pT)34, and highest for dC(pC)34, indicating that it is most difficult to saturate the SSB tetramer with two molecules of dA(pA)34. We have also measured the equilibrium constants for binding the oligodeoxynucleotides dC(pC)34, dC(pC)69, dA(pA)34, and dA(pA)69 as a function of [NaCl] and [NaBr] and find that the salt dependencies of these oligonucleotides are dependent upon base composition. These studies also indicate that ion binding accompanies formation of these SSB-ss-DNA complexes, although there is a net release of ions upon formation of the complex. This influence of both salt concentration and base composition indicates that both electrostatic and nonelectrostatic factors contribute to the negative cooperativity associated with ss-DNA binding to the SSB tetramer.

Linkage of pH, anion and cation effects in protein-nucleic acid equilibria. Escherichia coli SSB protein-single stranded nucleic acid interactions

We have examined the linkage between pH and monovalent salt concentration (NaCl and NaF) on the equilibrium binding of the Escherichia coli SSB protein to single stranded poly(U) in its (SSB)65 binding mode. In this mode, single-stranded nucleic acid interacts with all four subunits of the SSB tetramer covering approximately 65 nucleotides and nearest-neighbor cooperative interactions can form between DNA bound SSB tetramers, although protein clusters are limited to dimers of tetramers (octamers). The intrinsic association equilibrium constant, K(obs), and the "limited" cooperativity parameter, omega T/O, have been determined from titrations that monitor the quenching of the SSB tryptophan fluorescence upon binding poly(U). The cooperativity parameter, omega T/O, is independent of salt concentration and type and increases only slightly with increasing pH. However, K(obs) decreases with increasing salt concentration due to a net release of ions accompanying complex formation. This net ion release has contributions from cation release from the nucleic acid as well as differential binding of both cations and anions to the protein. The dependence of K(obs) on [NaF] is independent of pH with delta logK(obs)/delta log[NaF] = -4.5(+/- 0.5). However, there is a strong linkage between the effects of [NaCl] and pH, such that (delta logK(obs)/delta log[NaCl]) ranges from -12.0(+/- 0.8) at pH 5.5, to -6.0(+/- 0.5) at pH 9.0 (at 25 degrees C). Thus Cl- release increases with decreasing pH due to a linkage between chloride binding and protonation of the protein, whereas there is essentially no release of F-. The linkages of ion concentration and pH on K(obs) can be described in terms of: (1) cation release from the polynucleotide; (2) release of Cl- from sites on the SSB tetramer that require protonation to bind Cl-; (3) binding of cations to sites on the SSB tetramer which require deprotonation for cation binding, and (4) required binding of two-to-three protons by the SSB tetramer in order to form the SSB-poly(U) complex. Thus, the influence of salt concentration on protein-nucleic acid equilibria can be quite complex with contributions from differential ion binding to both the protein and the nucleic acid; however, these can be resolved by examining the linked effects of pH and salt concentration on these interactions.

Co-operative binding of Escherichia coli SSB tetramers to single-stranded DNA in the (SSB)35 binding mode

Escherichia coli SSB tetramers can bind to single stranded (ss) DNA in several binding modes. At 25 degrees C, pH 8.1, SSB can form at least three distinct binding modes, (SSB)n, where the number of nucleotides occluded per tetramer (n), can have values of 35, 56 or 65. Stability of the different modes is modulated by solution conditions, primarily the salt concentration and type, as well as the free SSB concentration. At least two different types of positive co-operative binding of SSB to ssDNA have also been observed, which appear to be correlated with different SSB binding modes. The (SSB)65 mode, which dominates at monovalent salt concentrations > 0.2 M, displays only moderate, "limited" co-operative binding in which clustering of SSB is limited to the formation of dimers of tetramers (octamers). However, at lower salt concentrations, "unlimited" co-operative binding is observed in which long SSB clusters can form, similar to the behavior observed for the phage T4 gene 32 protein. It has been proposed that unlimited co-operativity is linked to the (SSB)35 binding mode; however, this has not been verified since quantitative estimates of the co-operativity in this binding mode are difficult on long ssDNA. To estimate the nearest-neighbor co-operativity parameter in the (SSB)35 mode, we have examined the equilibrium binding of SSB to the oligodeoxynucleotide, dA(pA)69. Under certain conditions, 1:1 complexes, in which all four SSB subunits interact with the dA(pA)69, can form at low SSB binding densities, whereas 2:1 complexes, in which both SSB tetramers bind to DNA using only two subunits, can form at high SSB binding densities. These 2:1 complexes serve as a model for co-operative binding in the (SSB)35 binding mode. We show that SSB tetramers bind in this mode with a minimum nearest-neighbor co-operativity parameter of omega 35 = 1.0 x 10(5) (0.125 M NaCl, pH 8.1, 25 degrees C). This indicates that the nearest-neighbor co-operativities for SSB tetramers bound to ssDNA in the (SSB)35 versus the (SSB)65 mode differ qualitatively and quantitatively and suggests that the (SSB)35 mode is responsible for the ability of SSB protein to form long clusters on ssDNA. If the ability of helix destabilizing proteins to form uninterrupted protein clusters on ssDNA is important in DNA replication, then it is likely that SSB uses its (SSB)35 mode to function in this capacity.

Thermodynamics of single-stranded RNA and DNA interactions with oligolysines containing tryptophan. Effects of base composition

We have examined the thermodynamics of binding of a series of oligolysines (net charge z = +2 to +10) containing one, two, or three tryptophans to several single-stranded (ss) homo-polynucleotides [poly(A), poly(C), poly(I), poly(dU), poly(dT)] and duplex (ds) DNA in order to investigate the effects of peptide charge, tryptophan content, and polynucleotide base and sugar type. Equilibrium association constants, Kobs, were measured as a function of monovalent salt concentration (KCH3CO2) and temperature by monitoring the quenching of the peptide tryptophan fluorescence upon interaction with the polynucleotides, from which the dependence of delta G(o)obs, delta H(o)obs, and delta S(o)obs on [KCH3CO2] was obtained. As observed previously with poly(U) [Mascotti, D.P., & Lohman, T.M. (1992) Biochemistry 31, 8932], the dependence of delta G(o)obs on [K+] for peptide binding to each polynucleotide is entirely entropic in origin (i.e., delta H(o)obs is independent of [K+]), consistent with the conclusion that Kobs increases with decreasing salt concentration due to the favorable increase in entropy resulting from the displacement of bound cations (K+) from the nucleic acid upon formation of the complex. For each ss polynucleotide, we find that significantly less than one potassium ion is released thermodynamically per net positive peptide charge, as determined from the value of delta log Kobs/delta log [K+]. Interestingly, (-delta log Kobs/delta log [K+])/z decreases with increasing peptide charge for poly(A), poly(C), and poly(dT), contrary to the behavior observed with poly(U) and ds-DNA, which may reflect a significant release of bound water upon formation of peptide complexes with these ss homo-polynucleotides or an increased binding of K+ to the ss polynucleotide with increasing [K+]. Alternatively, there may be conformational differences between the bound states of oligolysines of low charge, relative to oligolysines of higher charge. However, in all cases, peptides with z < +4 display different thermodynamics of binding than peptides with z > +4. The presence of tryptophan (Trp) within these peptides does not influence the salt dependence of Kobs for binding to poly(A), poly(C), or poly(dT). However, the Trp content of the peptide does contribute significantly to the thermodynamics of these interactions: Trp interactions result in a favorable contribution to delta H(o)obs, but an unfavorable contribution to delta S(o)obs, with little effect on delta G(o)obs due to entropy-enthalpy compensations. Oligolysines containing Trp also display a small, but significant, dependence of Kobs on base composition, with Kobs decreasing in the order poly(I) >> poly(dT) approximately poly(U) approximately poly(A) >> poly(C).

Heterodimer formation between Escherichia coli Rep and UvrD proteins

DNA helicases catalyze the essential process of unwinding duplex DNA to form the single-stranded DNA intermediates required for DNA metabolic processes including replication, recombination, and repair. Most cells, possibly all, encode multiple helicases that function selectively in different processes, although some helicases can complement each other in vivo. Thus, although Escherichia coli can survive mutations or deletions of either the uvrD gene (encoding Helicase II) or the rep gene (encoding Rep helicase) separately, deletion of both rep and uvrD genes is lethal (Washburn, B. K., and Kushner, S. R. (1991) J. Bacteriol. 173,2569-2575). The Rep and UvrD polypeptides share approximately 40% sequence homology, and we have previously shown that both form homodimeric species and that the Rep homodimer appears to be the functionally active helicase. We report here that these two proteins can also interact in vitro to form a heterodimer. The heterodimer appears to be energetically more stable than the Rep homodimer but less stable than the UvrD homodimer under our conditions. The observation of Rep/UvrD heterodimer formation in vitro opens up the intriguing possibility that the heterodimer may play a physiologically important role that is distinct from the role of the Rep or UvrD homodimers. Therefore, considerations of the role of either protein in DNA metabolic processes, such as replication and repair, must include a potential role for a Rep/UvrD heterodimer.

Escherichia coli rep helicase unwinds DNA by an active mechanism

DNA helicases unwind duplex DNA to form the single-stranded (ss) DNA intermediates required for replication, recombination, and repair in reactions that require nucleoside 5'-triphosphate hydrolysis. Helicases generally require a ss-DNA flanking the duplex in order to initiate unwinding in vitro; however, the precise function of the ss-DNA is not understood. If a helicase unwinds DNA by a "passive" mechanism, it would bind to and translocate unidirectionally along the ss-DNA and facilitate duplex unwinding by translocating onto the ss-DNA that is formed transiently by thermal fluctuations in the duplex. We have examined the kinetics of DNA unwinding by Escherichia coli Rep protein (a 3' to 5' helicase) by rapid quench-flow methods using a series of novel, nonnatural DNA substrates possessing 3' flanking ss-DNA within which is embedded either a segment of ss-DNA possessing reversed backbone polarity or a non-DNA [poly(ethylene glycol)] spacer, either of which should block unwinding by a passive helicase. The E. coli Rep helicase effectively unwinds these DNA substrates, ruling out a passive mechanism of unwinding. Instead, the results are consistent with an "active" rolling mechanism during which Rep binds to ss-DNA and duplex DNA simultaneously.

A double-filter method for nitrocellulose-filter binding: application to protein-nucleic acid interactions

Nitrocellulose-filter binding is a powerful technique commonly used to study protein-nucleic acid interactions; however, its utility in quantitative studies is often compromised by its lack of precision. To improve precision and accuracy, we have introduced two modifications to the traditional technique: the use of a 96-well dot-blot apparatus and the addition of a DEAE membrane beneath the nitrocellulose membrane. Using the dot-blot apparatus, an entire triplicate set of data spanning 20-24 titrant concentrations can be collected on a single 4.5 x 5 inch sheet of nitrocellulose, obviating the need to manipulate separate filters for each titration point. The entire titration can then be quantitated simultaneously with direct two-dimensional beta-emission imaging technology. The DEAE second membrane traps all DNA that does not bind to the nitrocellulose, enabling a direct determination of the total amount of DNA filtered. This measurement improves precision by allowing the amount of DNA retained by the nitrocellulose to be normalized against the total amount of DNA filtered. The DEAE membrane also permits a more accurate quantitation of filter-retention efficiency and nonspecific background retention based on free DNA rather than total DNA filtered. The general approach and methods of analysis to obtain equilibrium binding isotherms are discussed, using as examples our studies of the Escherichia coli Rep protein, a helicase, and its interactions with short oligodeoxynucleotides.

Kinetics of Escherichia coli helicase II-catalyzed unwinding of fully duplex and nicked circular DNA

Escherichia coli helicase II (UvrD) protein can initiate unwinding of duplex DNA at blunt ends or nicks, although these reactions require excess protein. We have undertaken kinetic studies of these reactions in order to probe the mechanism of initiation of unwinding. DNA unwinding was monitored directly by using agarose gel electrophoresis and indirectly through the rate of ATP hydrolysis by helicase II in the presence of an ATP-regenerating system. In the presence of fully duplex DNA and excess helicase II, the rate of ATP hydrolysis displays a distinct lag phase before the final steady-state rate of hydrolysis is reached. This reflects the fact that ATP hydrolysis under these conditions results from helicase II binding to the ssDNA products of the unwinding reaction, rather than from an intrinsic duplex DNA-dependent ATPase activity. Unwinding of short blunt-ended duplex DNA (341 and 849 base pairs) occurs in an "all-or-none" reaction, indicating that initiation of unwinding by helicase II is rate-limiting. We propose a minimal mechanism for the initiation of DNA unwinding by helicase II which includes a binding step followed by the rate-limiting formation of an initiation complex, possibly involving protein dimerization, and we have determined the phenomenological kinetic parameters describing this mechanism. Unwinding of a series of DNA substrates containing different initiation sites (e.g., blunt ends, internal nicks, and four-nucleotide 3' vs 5' ssDNA flanking regions) indicates that the rate of initiation is slowest at nicks and, surprisingly, at ends possessing a four-nucleotide 3' ssDNA flanking region.

Helicase-catalyzed DNA unwinding

DNA helicases are ubiquitous and multiple helicases have been identified in a number of prokaryotes and eukaryotes. Although it is clear that not all helicases function identically, many of these enzymes possess similar properties that appear to be of general importance for their mechanism of action. For example, the assembly states of most (possibly all) helicases are oligomeric. The prime consequence of an oligomeric helicase is that it possesses multiple DNA binding sites, a feature that is required for any "active" mechanism of DNA unwinding, since it enables a helicase to bind both ss- and duplex DNA or two strands of ss-DNA simultaneously at an unwinding fork. Modulation of the relative affinities of ss- versus duplex DNA for these multiple binding sites through ATP binding and hydrolysis, as has been observed for the E. coli Rep dimer, can provide a mechanism for translocation and processive unwinding of DNA. Along with studies of DNA unwinding, further understanding of helicase mechanisms requires quantitative studies of the equilibria and kinetics of the multiple, linked reactions among protein, DNA, and nucleotide cofactors, including the protein-protein interactions involved in assembly of the oligomeric helicase.

Overexpression, purification, DNA binding, and dimerization of the Escherichia coli uvrD gene product (helicase II)

We have subcloned the Escherichia coli uvrD gene under control of the inducible phage lambda PL promoter and report a procedure for the large-scale purification of helicase II protein. Yields of approximately 60 mg of > 99% pure helicase II protein, free of detectable nuclease activity, are obtained starting from 250 g of induced E. coli cells containing the overexpression plasmid. Overproduction of helicase II protein at these levels is lethal in E. coli. The extinction coefficient of helicase II protein was determined to be epsilon 280 = 1.06 (+/- 0.05) x 10(5) M-1 (monomer) cm-1 [20 mM Tris-HCl (pH 8.3 at 25 degrees C), 0.2 M NaCl, and 20% (v/v) glycerol, 25 degrees C]. We also present a preliminary characterization of the dimerization and DNA binding properties of helicase II and a systematic examination of its solubility properties. The apparent site size of a helicase II monomer on ss-DNA is 10 +/- 2 nucleotides as determined by quenching of the intrinsic tryptophan fluorescence of the protein upon binding poly(dT). In the absence of DNA, helicase II protein can self-assemble to form at least a dimeric species at concentrations > 0.25 microM (monomer) and exists in a monomer-dimer equilibrium under a variety of solution conditions. However, upon binding short oligodeoxynucleotides, the dimeric form of helicase II is stabilized, and dimerization stimulates the ss-DNA-dependent ATPase activity, suggesting that the dimer is functionally important. On the basis of these observations and similarities between helicase II and the E. coli Rep helicase, which appears to function as a dimer [Chao, K., & Lohman, T. (1991) J. Mol. Biol. 221, 1165-1181], we suggest that the active form of helicase II may also be a dimer or larger oligomer.

Thermodynamics of single-stranded RNA binding to oligolysines containing tryptophan

The equilibrium binding to the synthetic RNA poly(U) of a series of oligolysines containing one, two, or three tryptophans has been examined as a function of pH, monovalent salt concentration (MX), temperature, and Mg2+. Oligopeptides containing lysine (K) and tryptophan (W) of the type KWKp-NH2 and KWKp-CO2 (p = 1-8), as well as peptides containing additional tryptophans or glycines, were studied by monitoring the quenching of the peptide tryptophan fluorescence upon binding poly(U). Equilibrium association constants, K(obs), and the thermodynamic quantities delta G(o)obs, delta H(o)obs, and delta S(o)obs describing peptide-poly(U) binding were measured as well as their dependences on monovalent salt concentration, temperature, and pH. In all cases, K(obs) decreases significantly with increasing monovalent salt concentration, with (delta log K(obs)/delta log [K+]) = -0.74 (+/- 0.04)z, independent of temperature and salt concentration, where z is the net positive charge on the peptide. The origin of these salt effects is entropic, consistent with the release of counterions from the poly(U) upon formation of the complex. Upon extrapolation to 1 M K+, the value of delta G(o)obs is observed to be near zero for all oligolysines binding to poly(U), supporting the conclusion that these complexes are stabilized at lower salt concentrations due to the increase in entropy accompanying the release of monovalent counterions from the poly(U). Only the net peptide charge appears to influence the thermodynamics of these interactions, since no effects of peptide charge distribution were observed. The binding of poly(U) to the monotryptophan peptides displays interesting behavior as a function of the peptide charge. The extent of tryptophan fluorescence quenching, Qmax, is dependent upon the peptide charge for z less than or equal to +4, and the value of Qmax correlates with z-dependent changes in delta H(o)obs and delta S(o)obs(1 M K+), whereas for z greater than or equal to +4, Qmax, delta H(o)obs, and delta S(o)obs (1 M K+) are constant. The correlation between Qmax and delta H(o)obs and delta S(o)obs(1 M K+) suggests a context (peptide charge)-dependence of the interaction of the peptide tryptophan with poly(U). However the interaction of the peptide tryptophan does not contribute substantially to delta G(o)obs for any of the peptides, independent of z, due to enthalpy-entropy compensations. Each of the tryptophans in multiple Trp-containing peptides appear to bind to poly(U) independently, with delta H(o)Trp = -2.9 +/- 0.7, although delta G(o)Trp is near zero due to enthalpy-entropy compensations.(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)

Allosteric effects of nucleotide cofactors on Escherichia coli Rep helicase-DNA binding

The Escherichia coli Rep helicase unwinds duplex DNA during replication. The functional helicase appears to be a dimer that forms only on binding DNA. Both protomers of the dimer can bind either single-stranded or duplex DNA. Because binding and hydrolysis of adenosine triphosphate (ATP) are essential for helicase function, the energetics of DNA binding and DNA-induced Rep dimerization were studied quantitatively in the presence of the nucleotide cofactors adenosine diphosphate (ADP) and the nonhydrolyzable ATP analog AMPP(NH)P. Large allosteric effects of nucleotide cofactors on DNA binding to Rep were observed. Binding of ADP favored Rep dimers in which both protomers bound single-stranded DNA, whereas binding of AMPP(NH)P favored simultaneous binding of both single-stranded and duplex DNA to the Rep dimer. A rolling model for the active unwinding of duplex DNA by the dimeric Rep helicase is proposed that explains vectorial unwinding and predicts that helicase translocation along DNA is coupled to ATP binding, whereas ATP hydrolysis drives unwinding of multiple DNA base pairs for each catalytic event.

DNA-induced dimerization of the Escherichia coli rep helicase. Allosteric effects of single-stranded and duplex DNA

The Escherichia coli Rep helicase is a stable monomer (Mr = 72,802) in the absence of DNA; however, binding of single-stranded (ss) or duplex (ds) DNA induces Rep monomers to dimerize. Furthermore, a chemically cross-linked Rep dimer retains both its DNA-dependent ATPase and helicase activities, suggesting that the functionally active Rep helicase is a dimer (Chao, K., and Lohman, T. M. (1991) J. Mol. Biol. 221, 1165-1181). Using a modified "double-filter" nitrocellulose filter binding assay, we have examined quantitatively the equilibrium binding of Rep to a series of ss-oligodeoxynucleotides, d(pN)n (8 less than or equal to n less than or equal to 20) and two 16-base pair duplex oligodeoxynucleotides, which are short enough so that only a single Rep monomer can bind to each oligonucleotide. This strategy has enabled us to examine the linkage between DNA binding and dimerization. We also present a statistical thermodynamic model to describe the DNA-induced Rep dimerization in the presence of ss- and/or ds-oligodeoxynucleotides. We observe quantitative agreement between this model and the experimental binding isotherms and have analyzed these isotherms to obtain the seven independent interaction constants that describe Rep-DNA binding and Rep dimerization. We find that Rep monomers (P) can bind either ss-DNA (S) or ds-DNA (D) to form PS or PD, respectively, which can then dimerize to form P2S or P2D. Furthermore, both protomers of the DNA-induced Rep dimer can bind DNA to form either P2S2, P2D2 or the mixed dimer species P2SD and ss- and ds-DNA compete for the same sites on the Rep protein. When bound to DNA, the Rep dimerization constants are approximately 1-2 x 10(8) M-1 (6 mM NaCl, pH 7.5, 4 degrees C), which are greater than the dimerization constant for free Rep monomers by at least 10(4)-fold. The Rep-ss-DNA interaction constants are independent of base composition and sequence, consistent with its role as a nonspecific DNA-binding protein. Allosteric effects are associated with ss- and ds-DNA binding to the half-saturated Rep dimers, i.e. the affinity of either ss- or ds-DNA to the free promoter of a half-saturated Rep dimer is clearly influenced by the conformation of DNA bound to the first protomer. These allosteric effects further support the proposal that the Rep dimer is functionally important and that the Rep-DNA species P2S2 and P2SD may serve as useful models for intermediates that occur during DNA unwinding.(ABSTRACT TRUNCATED AT 400 WORDS)

Thermodynamics of ligand-nucleic acid interactions

Ligand-and protein-DNA equilibria are extremely sensitive to solution conditions (e.g., salt, temperature, and pH), and, in general, the effects of different solution variables are interdependent (i.e., linked). As a result, an assessment of the basis for the stability and specificity of ligand-or protein-DNA interactions requires quantitative studies of these interactions as a function of a range of solution variables. Many of the most dramatic effects on the stability of these interactions result from changes in the entropy of the system, caused by the preferential interaction of small molecules, principally ions which are released into solution on complex formation. A determination of the contributions of these entropy changes to the stability and specificity of protein-and ligand-DNA interactions requires thermodynamic approaches and cannot be assessed from structural studies alone.

Escherichia coli DNA helicases: mechanisms of DNA unwinding

DNA helicases are ubiquitous enzymes that catalyse the unwinding of duplex DNA during replication, recombination and repair. These enzymes have been studied extensively; however, the specific details of how any helicase unwinds duplex DNA are unknown. Although it is clear that not all helicases unwind duplex DNA in an identical way, many helicases possess similar properties, which are thus likely to be of general importance to their mechanism of action. For example, since helicases appear generally to be oligomeric enzymes, the hypothesis is presented in this review that the functionally active forms of DNA helicases are oligomeric. The oligomeric nature of helicases provides them with multiple DNA-binding sites, allowing the transient formation of ternary structures, such that at an unwinding fork, the helicase can bind either single-stranded and duplex DNA simultaneously or two strands of single-stranded DNA. Modulation of the relative affinities of these binding sites for single-stranded versus duplex DNA through ATP binding and hydrolysis would then provide the basis for a cycling mechanism for processive unwinding of DNA by helicases. The properties of the Escherichia coli DNA helicases are reviewed and possible mechanisms by which helicases might unwind duplex DNA are discussed in view of their oligomeric structures, with emphasis on the E. coli Rep, RecBCD and phage T7 gene 4 helicases.

DNA-induced dimerization of the Escherichia coli Rep helicase

The Escherichia coli Rep protein is a DNA helicase that is involved in DNA replication. We have examined the effects of DNA binding on the assembly state of the Rep protein using small-zone gel permeation chromatography and chemical crosslinking of the protein. Complexes of Rep protein were formed with short single-stranded and duplex hairpin oligodeoxynucleotides with lengths such that only a single Rep monomer could bind per oligodeoxynucleotide (i.e. 2 Rep monomers could not bind contiguously on the oligodeoxynucleotides). In the absence of DNA, Rep protein is monomeric (Mr 72,800) up to concentrations of at least 8 microM (monomer), even in the presence of its nucleotide cofactors (ATP, ADP, ATP-gamma-S). However, the binding of Rep monomers to single-stranded (ss) oligodeoxynucleotides, d(pN)n (12 less than or equal to n less than or equal to 20), induces the Rep monomers to oligomerize. Upon treatment of the Rep-ss oligodeoxynucleotide complexes with the protein crosslinking reagent dimethyl-suberimidate (DMS) and subsequent removal of the DNA, crosslinked Rep dimers are observed, independent of oligodeoxynucleotide length (n less than or equal to 20). Furthermore, short duplex oligodeoxynucleotides also induce the Rep monomers to dimerize. Formation of the Rep dimers results from an actual DNA-induced dimerization, rather than the adventitious crosslinking of Rep monomers bound contiguously to a single oligodeoxynucleotide. The purified DMS-crosslinked Rep dimer shows increased affinity for DNA and retains DNA-dependent ATPase and DNA helicase activities, as shown by its ability to unwind M13 RF DNA in the presence of the bacteriophage f1 gene II protein. On the basis of these observations and since the dimer is the major species when Rep is bound to DNA, we suggest that a DNA-induced Rep dimer is the functionally active form of the Rep helicase.