Close proximity of tryptophan residues and ATP-binding site in Escherichia coli primary replicative helicase DnaB protein. Molecular topography of the enzyme

The ATPase mechanism of UvrA2 reveals the distinct roles of proximal and distal ATPase sites in nucleotide excision repair

The UvrA₂ dimer finds lesions in DNA and initiates nucleotide excision repair. Each UvrA monomer contains two essential ATPase sites: proximal (P) and distal (D). The manner whereby their activities enable UvrA₂ damage sensing and response remains to be clarified. We report three key findings from the first pre-steady state kinetic analysis of each site. Absent DNA, a P_2ATP-D_2ADP species accumulates when the low-affinity proximal sites bind ATP and enable rapid ATP hydrolysis and phosphate release by the high-affinity distal sites, and ADP release limits catalytic turnover. Native DNA stimulates ATP hydrolysis by all four sites, causing UvrA₂ to transition through a different species, P_2ADP-D_2ADP. Lesion-containing DNA changes the mechanism again, suppressing ATP hydrolysis by the proximal sites while distal sites cycle through hydrolysis and ADP release, to populate proximal ATP-bound species, P_2ATP-D_empty and P_2ATP-D_2ATP. Thus, damaged and native DNA trigger distinct ATPase site activities, which could explain why UvrA₂ forms stable complexes with UvrB on damaged DNA compared with weaker, more dynamic complexes on native DNA. Such specific coupling between the DNA substrate and the ATPase mechanism of each site provides new insights into how UvrA₂ utilizes ATP for lesion search, recognition and repair.

Signal and binding. I. Physico-chemical response to macromolecule-ligand interactions

Obtaining a detailed knowledge about energetics of ligand-macromolecule interactions is a prerequisite for elucidation of the nature, behavior, and activities of the formed complexes. The most commonly used methods in characterizing molecular interactions are physico-chemical techniques based mainly on spectroscopic, calorimetric, hydrodynamic, etc., measurements. The major advantage of the physico-chemical methods is that they do not require large quantities of material and, if performed carefully, do not perturb examined reactions. Applications of several different physico-chemical approaches, commonly encountered in analyses of biochemical interactions, are here reviewed and discussed, using examples of simple binding reactions. It is stressed that without determination of the relationship between the measured signal and the total average degree of binding, the performed analysis of a single physico-chemical titration curve may provide only fitting parameters, instead of meaningful interaction parameters, already for the binding systems with only two ligand molecules. Some possible pitfalls in the analyses of single titration curves are discussed.

Autolysis control and structural changes of purified ficin from Iranian fig latex with synthetic inhibitors

The fig's ficin is a cysteine endoproteolytic enzyme, which plays fundamental roles in many plant physiological processes, and has many applications in different industries such as pharmaceutical and food. In this work, we report the inhibition and activation of autolysis and structural changes associated with reaction of ficin with iodoacetamide and tetrathionate using high-performance liquid chromatography (HPLC), ultra filtration membrane, and dynamic light scattering (DLS) methods. The ficin structural changes were also determined using UV-absorption, circular dichroism (CD), fluorescence spectroscopy, and differential scanning calorimetry (DSC) techniques. These techniques demonstrated that iodoacetamide completely inhibited ficin autolysis, which was irreversible. However, tetrathionate partially and reversibility inhibited its autolysis. The ficin structural changes with two synthetic inhibitors were associated with secondary structural changes related to decreased alpha-helix and increased beta sheet and random coil conformations, contributing to its aggregation.

Structural characterization of MG and pre-MG states of proteins by MD simulations, NMR, and other techniques

Almost all proteins fold via a number of partially structured intermediates such as molten globule (MG) and pre-molten globule states. Understanding the structure of these intermediates at atomic level is often a challenge, as these states are observed under extreme conditions of pH, temperature, and chemical denaturants. Furthermore, several other processes such as chemical modification, site-directed mutagenesis (or point mutation), and cleavage of covalent bond of natural proteins often lead to MG like partially unfolded conformation. However, the dynamic nature of proteins in these states makes them unsuitable for most structure determination at atomic level. Intermediate states studied so far have been characterized mostly by circular dichroism, fluorescence, viscosity, dynamic light scattering measurements, dye binding, infrared techniques, molecular dynamics simulations, etc. There is a limited amount of structural data available on these intermediate states by nuclear magnetic resonance (NMR) and hence there is a need to characterize these states at the molecular level. In this review, we present characterization of equilibrium intermediates by biophysical techniques with special reference to NMR.

Energetics of the Escherichia coli DnaT protein trimerization reaction

Thermodynamic and structural characteristics of the Escherichia coli DnaT protein trimerization reaction have been quantitatively examined using fluorescence anisotropy and analytical ultracentrifugation methods. Binding of magnesium to the DnaT monomers regulates the intrinsic affinity of the DnaT trimerization reaction. Comparison between the DnaT trimer and the isolated N-terminal core domain suggests that magnesium binds to the N-terminal domain but does not associate with the C-terminal region of the protein. The magnesium binding process is complex and involves approximately three Mg(2+) cations per protein monomer. The observed effect seems to be specific for Mg(2+). In the examined salt concentration range, monovalent cations and anions do not affect the trimer assembly process. However, magnesium affects neither the cooperativity of the trimerization reaction nor the GnHCl-induced trimer dissociation, strongly indicating that Mg(2+) indirectly stabilizes the trimer through the induced changes in the monomer structures. Nevertheless, formation of the trimer also involves specific conformational changes of the monomers, which are independent of the presence of magnesium. Binding of Mg(2+) cations dramatically changes the thermodynamic functions of the DnaT trimerization, transforming the reaction from a temperature-dependent to temperature-independent process. Highly cooperative dissociation of the trimer by GnHCl indicates that both interacting sites of the monomer, located on the N-terminal core domain and formed by the small C-terminal region, are intimately integrated with the entire protein structure. In the intact protein, the C-terminal region most probably interacts with the corresponding binding site on the N-terminal domain of the monomer. Functional implications of these findings are discussed.

Using structure-function constraints in FRET studies of large macromolecular complexes

The structural aspects of large macromolecular systems in solution can be conveniently addressed using the fluorescence resonance energy transfer (FRET) approach. FRET efficiency is the major parameter examined in such studies. However, its quantitative determination in associating macromolecular systems requires careful incorporation of thermodynamic quantities into specific expressions defining the FRET efficiencies. There are two widely used methods of obtaining FRET efficiencies, examination of both the donor quenching and of the sensitized emission of the FRET acceptor. Both approaches provide only apparent FRET efficiencies, not the true Förster FRET efficiency, which should be independent of the means to measure the efficiency.The accuracy of the determined distances in macromolecular systems depends on the accuracy of the determination of the FRET efficiency and the estimate of the parameter, κ², which depends on the mutual orientation of the donor and the acceptor. Known procedures, based on limiting anisotropy measurements, to estimate κ² are of limited use to deducing the functional conclusions about the studied systems. On the other hand, using multiple donor-acceptor pairs and/or donors and acceptors placed in interchanged locations in the macromolecular system is an equally rigorous procedure to empirically evaluate the possible effect of κ² on the measured distance. Protein-nucleic acid systems are particularly suited for FRET methodology. There is a plethora of commercial fluorescent markers, which can serve as donor-acceptor pairs. In the case of the nucleic acid, the markers can specifically be introduced in practically any location of the molecule. Application of the FRET measurements to examine structures of the large protein-nucleic acid complexes is particularly fruitful in cases where the presence of known structural constraints allows the experimenter to address the fundamental topology of the complexes. The discussed methodology can be applied to any associating macromolecular system.

Macromolecular competition titration method accessing thermodynamics of the unmodified macromolecule-ligand interactions through spectroscopic titrations of fluorescent analogs

Analysis of thermodynamically rigorous binding isotherms provides fundamental information about the energetics of the ligand-macromolecule interactions and often an invaluable insight about the structure of the formed complexes. The Macromolecular Competition Titration (MCT) method enables one to quantitatively obtain interaction parameters of protein-nucleic acid interactions, which may not be available by other methods, particularly for the unmodified long polymer lattices and specific nucleic acid substrates, if the binding is not accompanied by adequate spectroscopic signal changes. The method can be applied using different fluorescent nucleic acids or fluorophores, although the etheno-derivatives of nucleic acid are especially suitable as they are relatively easy to prepare, have significant blue fluorescence, their excitation band lies far from the protein absorption spectrum, and the modification eliminates the possibility of base pairing with other nucleic acids. The MCT method is not limited to the specific size of the reference nucleic acid. Particularly, a simple analysis of the competition titration experiments is described in which the fluorescent, short fragment of nucleic acid, spanning the exact site-size of the protein-nucleic acid complex, and binding with only a 1:1 stoichiometry to the protein, is used as a reference macromolecule. Although the MCT method is predominantly discussed as applied to studying protein-nucleic acid interactions, it can generally be applied to any ligand-macromolecule system by monitoring the association reaction using the spectroscopic signal originating from the reference macromolecule in the presence of the competing macromolecule, whose interaction parameters with the ligand are to be determined.

Escherichia coli DnaB helicase-DnaC protein complex: allosteric effects of the nucleotides on the nucleic acid binding and the kinetic mechanism of NTP hydrolysis. 3

Allosteric interactions between the DNA- and NTP-binding sites of the Escherichia coli DnaB helicase engaged in the DnaB-DnaC complex and the mechanism of NTP hydrolysis by the complex have been examined using the fluorescence titration, analytical ultracentrifugation, and rapid quench-flow technique. Surprisingly, the ssDNA affinity of the DnaB-DnaC complex is independent of the structure of the phosphate group of the cofactor bound to the helicase. Thus, the DnaC protein eliminates the antagonistic allosteric effect of NTP and NDP on the ssDNA affinity of the enzyme. The protein changes the engagement of the DNA-binding subsites of the helicase in interactions with the nucleic acid, depending on the structure of the phosphate group of the present nucleotide cofactor and profoundly affects the structure of the bound DNA. Moreover, the ssDNA affinity of the helicase in the DnaB-DnaC complex is under the control of the nucleotide-binding site of the DnaC protein. The protein does not affect the NTP hydrolysis mechanism of the helicase. Nevertheless, the rate of the chemical step is diminished in the DnaB-DnaC complex. In the tertiary DnaB-DnaC-ssDNA complex, the ssDNA changes the internal dynamics between intermediates of the pyrimidine cofactor, in a manner independent of the base composition of the DNA, while the hydrolysis step of the purine cofactor is specifically stimulated by the homoadenosine ssDNA. The significance of these results for functional activities of the DnaB-DnaC complex is discussed.

Mechanism of NTP hydrolysis by the Escherichia coli primary replicative helicase DnaB protein. 2. Nucleotide and nucleic acid specificities

The kinetic mechanism of NTP binding and hydrolysis by the Escherichia coli replicative helicase, the DnaB protein, in the absence and presence of the single-stranded DNA (ssDNA), has been quantitatively examined using the rapid quench-flow technique, under single-turnover conditions. In the case of both the free helicase and the enzyme-ssDNA complexes, the mechanism is independent of the type of base of the cofactor or the DNA; the bimolecular association is followed by the reversible chemical hydrolysis and subsequent conformational transition of the enzyme-product complex. The NTP hydrolysis step is significantly faster for the purine than for the pyrimidine cofactor, both in the absence and in the presence of the DNA. The temperature effect indicates that the nature of intermediates of the purine nucleotide, ATP, is different from the nature of the analogous intermediates of the pyrimidine nucleotide, CTP. Nevertheless, both types of cofactors seem to approach a similar "exit" state at the end of the reaction. The effect of ssDNA on the kinetics of NTP hydrolysis depends on the type of nucleotide cofactor and the base composition of the DNA and is centered at the hydrolysis step. Homoadenosine ssDNA oligomers are particularly effective in increasing the hydrolysis rate. The allosteric signal from the DNA, which activates the NTP hydrolysis, comes predominantly from the strong DNA-binding subsite. The role of the weak DNA-binding subsite is to modulate the allosteric effect of the strong subsite. The significance of these results for the mechanism of the free energy transduction by the DnaB helicase is discussed.

Interactions of the Escherichia coli DnaB-DnaC protein complex with nucleotide cofactors. 1. Allosteric conformational transitions of the complex

Interactions of nucleotide cofactors with both protein components of the Escherichia coli DnaB helicase complex with the replication factor, the DnaC protein, have been examined using MANT-nucleotide analogues. At saturation, in all examined stationary complexes, including the binary, DnaB-DnaC, and tertiary, DnaB-DnaC-ssDNA, complexes, the helicase binds six cofactor molecules. Thus, protein-protein and protein-DNA interactions do not affect the maximum stoichiometry of the helicase-nucleotide interactions. The single-stranded DNA dramatically increases the ATP analogue affinity, while it has little effect on the affinity of the NDP analogues, indicating that stationary complexes reflect allosteric interactions between the DNA- and NTP-binding site prior to the cofactor hydrolysis step and subsequent to product release. In the binary complex, the DnaC protein diminishes the intrinsic affinity and increases the negative cooperativity in the cofactor binding to the helicase; an opposite effect of the protein on the cofactor-helicase interactions occurs in the tertiary complex. The DnaC protein retains its nucleotide binding capability in the binary and tertiary complexes with the helicase. Surprisingly, the DnaC protein-nucleotide interactions, in the binary and tertiary complexes, are characterized by positive cooperativity. The DnaC assembles on the helicase as a hexamer, which exists in two conformational states and undergoes an allosteric transition, induced by the cofactor. Cooperativity of the allosteric transition depends on the structure of the phosphate group of the nucleotide. The significance of the results for the DnaB-DnaC complex activities is discussed.

Mycobacterium tuberculosis UsfX (Rv3287c) exhibits novel nucleotide binding and hydrolysis properties

The Mycobacterium tuberculosis UsfX protein is an anti-sigma factor which regulates its cognate sigma factor SigF. UsfX shares low sequence homology with other anti-sigma factors making it difficult to identify the nucleotide binding site and characterize its properties. We have identified that the NTP binding site occurs close to Trp106 and the area around the nucleotide binding site is predominantly negatively charged. UsfX binds to a variety of nucleotides unlike other reported anti-sigma factors and exhibits an unusual dual NTPase activity. In silico computational experiments have identified a XGSFS motif close to the nucleotide binding site for metal ion binding. This motif is analogous to the DXSXS motif reported earlier in the human integrin CR3 protein superfamily. Overall, the experiments suggest that the M. tuberculosis UsfX represents a distinct anti-sigma factor family with a novel nucleotide binding motif.

Long range communication in the envelope protein domain III and its effect on the resistance of West Nile virus to antibody-mediated neutralization

The envelope protein domain III (ED3) of West Nile virus is the major virus-specific neutralization domain and harbors most of the critical mutations that induce resistance against antibody-mediated neutralization. We investigated the molecular mechanisms of neutralization resistance by studying the biophysical perturbations of monoclonal antibody (mAb)-resistant mutations on ED3 wild type. Our results showed that although the solution structure between ED3 wild type and mutants was preserved, the mutations that confer the highest degree of resistance to mAbs showed low protein stability and high local dynamic motions. Interestingly, the latter was observed in regions outside the mutation sites, indicating long range communications within ED3. Thus, we hypothesized that the mechanisms involved in resistance to mAb neutralization may include, in addition to mutations in the epitope, long range effects among distant structural elements. This hypothesis is consistent with reported mutations in other flaviviruses whose surfaces are not exposed for the interaction with other macromolecules, yet they confer mAb neutralization resistance.

Interactions of the DNA polymerase X of African swine fever virus with double-stranded DNA. Functional structure of the complex

Interactions of the polymerase X of African swine fever virus with the double-stranded DNA (dsDNA) have been studied with fluorescent dsDNA oligomers, using quantitative fluorescence titrations, analytical ultracentrifugation, and fluorescence energy transfer techniques. Studies with unmodified dsDNAs were performed, using competition titration method. ASV pol X binds the dsDNA with a site-size of n=10(+/-2) base-pairs, which is significantly shorter than the total site-size of 16(+/-2) nucleotides of the enzyme-ssDNA complex. The small site size indicates that the enzyme binds the dsDNA exclusively using the proper DNA-binding subsite. Fluorescence energy transfer studies between the tryptophan residue W92 and the acceptor, located at the 5' or 3' end of the dsDNA, suggest strongly that the proper DNA-binding subsite is located on the non-catalytic C-terminal domain. Moreover, intrinsic interactions with the dsDNA 10-mer or 20-mer are accompanied by the same net number of ions released, independent of the length of the DNA, indicating the same length of the DNA engaged in the complex. The dsDNA intrinsic affinity is about two orders of magnitude higher than the ssDNA affinity, indicating that the proper DNA-binding subsite is, in fact, the specific dsDNA-binding site. Surprisingly, ASFV pol X binds the dsDNA with significant positive cooperativity, which results from protein-protein interactions. Cooperative interactions are accompanied by the net ion release, with anions participating in the ion-exchange process. The significance of these results for ASFV pol X activity in the recognition of damaged DNA is discussed.

Unzipping mechanism of the double-stranded DNA unwinding by a hexameric helicase: quantitative analysis of the rate of the dsDNA unwinding, processivity and kinetic step-size of the Escherichia coli DnaB helicase using rapid quench-flow method

Kinetics of the double-stranded (ds) DNA unwinding by the Escherichia coli replicative helicase DnaB protein has been examined under single-turnover conditions using the chemical quench-flow technique. The unwinding reaction proceeds through an initial conformational transition followed by the unwinding catalytic steps and the release of the single-stranded (ss) DNA. Analyses of the reaction as a function of the number of base-pairs in the dsDNA reveal that the number of catalytic steps is not strictly proportional to the length of the dsDNA. As the helicase approaches the end of the substrate, the remaining approximately 11 bp of the DNA melts without catalytic participation of the enzyme. The kinetic step-size of the DnaB helicase, i.e. the number of the base-pairs unwound in a single catalytic step is only 1.4(+/- 0.2). The low value of the step-size indicates that the helicase unwinds a single base-pair in a single catalytic step. Thus, the DnaB helicase unzips the dsDNA in a reverse process to the zipping mechanism of the non-enzymatic double helix formation. The protein is a fast helicase that at 25 degrees C unwinds approximately 291 bp/s, much faster than previously thought, and the unwinding rate can be much higher at higher temperatures. However, the ATP-state of the enzyme has an increased dissociation rate, resulting in only a moderate unwinding processivity, P = 0.89(+/- 0.03), little dependent on the temperature. The conformational transition of the DnaB helicase-DNA complex, preceding the unwinding, is an intrinsic transition of the enzyme from the stationary conformation to the ATP-state of the helicase.

Differences in nucleotide-binding site of isoapyrases deduced from tryptophan fluorescence

Comparative studies of intrinsic and extrinsic fluorescence of apyrases purified from two potato tuber varieties (Pimpernel and Desirée) were performed to determine differences in the microenvironment of the nucleotide binding site. The dissociation constants (K(d)) of Pimpernel apyrase for the binding of different fluorescent substrate analogs: methylanthranoyl (MANT-), trinitrophenyl (TNP-), and epsilon -derivatives of ATP and ADP were determined from the quenching of Trp fluorescence, and compared with K(d) values previously reported for Desirée enzyme. Binding of non-fluorescent substrate analogues decreased the Trp emission of both isoapyrases, indicating conformational changes in the vicinity of these residues. Similar effect was observed with fluorescent derivatives where, in the quenching effect, the transfer of energy from tryptophan residues to the fluorophore moiety could be additionally involved. The existence of energy transfer between Trp residues in the Pimpernel enzyme was demonstrated with epsilon -analogues, similar to our previous observations with the Desirée. From these results we deduced that tryptophan residues are close to or in the nucleotide binding site in both enzymes. Experiments with quenchers like acrylamide, Cs(+) and I(-), both in the presence and absence of nucleotide analogues, suggest the existence of differences in the nucleotide binding site of the two enzymes. From the results obtained in this work, we can conclude that the differences found in the microenvironment of the nucleotide binding site can explain, at least in part, the kinetic behaviour of both isoenzymes.

Multiple-step kinetic mechanism of DNA-independent ATP binding and hydrolysis by Escherichia coli replicative helicase DnaB protein: quantitative analysis using the rapid quench-flow method

The kinetic mechanism of DNA-independent binding and hydrolysis of ATP by the E. coli replicative helicase DnaB protein has been quantitatively examined using the rapid quench-flow technique. Single-turnover studies of ATP hydrolysis, in a non-interacting active site of the helicase, indicate that bimolecular association of ATP with the site is followed by the reversible hydrolysis of nucleotide triphosphate and subsequent conformational transition of the enzyme-product complex. The simplest mechanism, which describes the data, is a three-step sequential process defined by:¿eqalign¿¿¿rm Helicase+ATP¿&¿mathop¿¿rightleftharpoons¿ ¿k_1¿_¿k_¿-1¿¿¿¿rm (H-ATP)¿¿mathop¿¿rightleftharpoons¿ ¿k_2¿_¿k_¿-2¿¿¿¿rm (H-ADP¿cdot Pi)¿¿cr &¿mathop¿¿rightleftharpoons¿ ¿k_3¿_¿k_¿-3¿¿¿¿rm (H-ADP¿cdot Pi)¿ *¿The sequential character of the mechanism excludes conformational transitions of the DnaB helicase prior to ATP binding. Analysis of relaxation times and amplitudes of the reaction allowed us to estimate all rate and equilibrium constants of partial steps of the proposed mechanism. The intrinsic binding constant for the formation of the (H-ATP) complex is K(ATP)=(1.3+/-0.5)x10(5) M(-1). The analysis of the data indicates that a part of the ATP binding energy originates from induced structural changes of the DnaB protein-ATP complex prior to ATP hydrolysis. The equilibrium constant of the chemical interconversion is K(H)=k(2)/k(-2) approximately 2 while the subsequent conformational transition is characterized by K(3)=k(3)/k(-3) approximately 30. The low value of K(H) and the presence of the subsequent energetically favorable conformational step(s) strongly suggest that free energy is released from the enzyme-product complex in the conformational transitions following the chemical step and before the product release.The combined application of single and multiple-turnover approaches show that all six nucleotide-binding sites of the DnaB hexamer are active ATPase sites. Binding of ATP to the DnaB hexamer is characterized by the negative cooperativity parameter sigma=0.25(+/-0.1). The negative cooperative interactions predominantly affect the ground state of the enzyme-ATP complex. The significance of these results for the mechanism of the free energy transduction of the DnaB helicase is discussed.

Escherichia coli replicative helicase PriA protein-single-stranded DNA complex. Stoichiometries, free energy of binding, and cooperativities

Analyses of interactions of the Escherichia coli replicative helicase, PriA protein, with a single-stranded (ss) DNA have been performed, using the quantitative fluorescence titration technique. The stoichiometry of the PriA helicase.ssDNA complex has been examined in binding experiments with a series of ssDNA oligomers. The total site-size of the PriA.ssDNA complex, i.e. the maximum number of nucleotide residues occluded by the PriA helicase in the complex, is 20 +/- 3 residues per protein monomer. However, the protein can efficiently form a complex with a minimum of 8 nucleotides. Thus, the enzyme has a strong ssDNA-binding site that engages in direct interactions with a significantly smaller number of nucleotides than the total site-size. The ssDNA-binding site is located in the center of the enzyme molecule, with the protein matrix protruding over a distance of approximately 6 nucleotides on both sides of the binding site. The analysis of the binding of two PriA molecules to long oligomers was performed using statistical thermodynamic models that take into account the overlap of potential binding sites, cooperative interactions, and the protein.ssDNA complexes with different stoichiometries. The intrinsic affinity depends little upon the length of the ssDNA. Moreover, the binding is accompanied by weak cooperative interactions.

Fluorescence studies of ATP-diphosphohydrolase from Solanum tuberosum var. Desirée

Chemical modification of potato apyrase suggests that tryptophan residues are close to the nucleotide binding site. Kd values (+/- Ca2+) for the complexes of apyrase with the non-hydrolysable phosphonate adenine nucleotide analogues, adenosine 5'-(beta,gamma-methylene) triphosphate and adenosine 5'-(alpha,beta-methylene) diphosphate, were obtained from quenching of the intrinsic enzyme fluorescence. Other fluorescent nucleotide analogues (2'(3')-O-(2,4,6-trinitrophenyl) adenosine 5'-triphosphate, 2'(3')-O-(2,4,6-trinitrophenyl) adenosine 5'-diphosphate. 1,N6-ethenoadenosine triphosphate and 1,N6-ethenoadenosine diphosphate) were hydrolysed by apyrase in the presence of Ca2+, indicating binding to the active site. The dissociation constants for the binding of these analogues were calculated from both the decrease of the protein (tryptophan) fluorescence and enhancement of the nucleotide fluorescence. Using the sensitised acceptor (nucleotide analogue) fluorescence method, energy transfer was observed between enzyme tryptophans and ethene-derivatives. These results support the view that tryptophan residues are present in the nucleotide-binding region of the protein, appropriately oriented to allow the energy transfer process to occur.

A conformation change in the carboxyl terminus of Alzheimer's Abeta (1-40) accompanies the transition from dimer to fibril as revealed by fluorescence quenching analysis

Alzheimer's disease is characterized by the presence of insoluble, fibrous deposits composed principally of amyloid beta (Abeta) peptide. A number of studies have provided information on the fibril structure and on the factors affecting fiber formation, but the details of the fibril structure are not known. We used fluorescence quenching to investigate the solvent accessibility and surface charge of the soluble Abeta(1-40) dimer and amyloid fibrils. Analogs of Abeta(1-40) containing a single tryptophan were synthesized by substituting residues at positions 4, 10, 34, and 40 with tryptophan. Quenching measurements in the dimeric state indicate that the amino-terminal analogs (AbetaF4W and AbetaY10W) are accessible to polar quenchers, and the more carboxyl-terminal analog AbetaV34W is less accessible. AbetaV40W, on the other hand, exhibits a low degree of quenching, indicating that this residue is highly shielded from the solvent in the dimeric state. Correcting for the effect of reduced translational and rotational diffusion, fibril formation was associated with a selective increase in solvent exposure of residues 34 and 40, suggesting that a conformation change may take place in the carboxyl-terminal region coincident with the dimer to fibril transition.

Does single-stranded DNA pass through the inner channel of the protein hexamer in the complex with the Escherichia coli DnaB Helicase? Fluorescence energy transfer studies

The structure of the complex of the Escherichia coli primary replicative helicase DnaB protein with single-stranded (ss) DNA and replication fork substrates has been examined using the fluorescence energy transfer method. In these experiments, we used the DnaB protein variant, R14C, which has arginine 14 replaced by cysteine in the small 12-kDa domain of the protein using site-directed mutagenesis. The cysteine residues have been modified with a fluorescent marker which serves as a donor or an acceptor to another fluorescence label placed in different locations on the DNA substrates. Using the multiple fluorescence donor-acceptor approach, we provide evidence that, in the complex with the enzyme, ssDNA passes through the inner channel of the DnaB hexamer. This is the first evidence of the existence of such a structure of a hexameric helicase-ssDNA complex in solution. In the stationary complex with the 5' arm of the replication fork, without ATP hydrolysis, the distance between the 5' end of the arm and the 12-kDa domains of the hexamer (R = 47 A) is the same as in the complex with the isolated ssDNA oligomer (R = 47 A) having the same length as the arm of the fork. These data indicate that both ssDNA and the 5' arm of the fork bind in the same manner to the DNA binding site. Moreover, in the complex with the helicase, the length of the ssDNA is similar to the length of the ssDNA strand in the double-stranded DNA conformation. In the stationary complex, the helicase does not invade the duplex part of the fork beyond the first 2-3 base pairs. This result corroborates the quantitative thermodynamic data which showed that the duplex part of the fork does not contribute to the free energy of binding of the enzyme to the fork. Implications of these results for the mechanism of a hexameric helicase binding to DNA are discussed.

Functional and structural heterogeneity of the DNA binding site of the Escherichia coli primary replicative helicase DnaB protein

The structure-function relationship within the DNA binding site of the Escherichia coli replicative helicase DnaB protein was studied using nuclease digestion, quantitative fluorescence titration, centrifugation, and fluorescence energy transfer techniques. Nuclease digestion of the enzyme-single-stranded DNA (ssDNA) complexes reveals large structural heterogeneity within the binding site. The total site is built of two subsites differing in structure and affinity, although both occlude approximately 10 nucleotides. ssDNA affinity for the strong subsite is approximately 3 orders of magnitude higher than that for the weak subsite. Fluorescence energy transfer experiments provide direct proof that the DnaB hexamer binds ssDNA in a single orientation, with respect to the polarity of the sugar-phosphate backbone. This is the first evidence of directional binding to ssDNA of a hexameric helicase in solution. The strong binding subsite is close to the small 12-kDa domains of the DnaB hexamer and occludes the 5'-end of the ssDNA. The strict orientation of the helicase on ssDNA indicates that, when the enzyme approaches the replication fork, it faces double-stranded DNA with its weak subsite. The data indicate that the different binding subsites are located sequentially, with the weak binding subsite constituting the entry site for double-stranded DNA of the replication fork.

Quantitative analysis of ligand-macromolecule interactions using differential dynamic quenching of the ligand fluorescence to monitor the binding

Quantitative analyses of the thermodynamics and kinetics of ligand-macromolecule interactions in biological systems rely predominately on monitoring changes in the spectroscopic properties of the ligand or macromolecule, particularly fluorescence changes, which accompany the formation of the studied complexes. However, in many instances the interactions do not affect the fluorescence properties of interacting species and do not provide a resolution high enough to perform quantitative and rigorous measurements of the thermodynamic and/or kinetic parameters. In this communication, we describe the theoretical and experimental aspects of a method of studying complex, multiple ligand-macromolecule interactions by the fluorescence titration technique, when the intrinsic fluorescence changes accompanying binding do not provide a resolution necessary to perform quantitative analyses. The method is based on the fact that a fluorescent ligand, or binding sites of the macromolecule, can have different accessibility to the collisional (dynamic) quencher, when involved in the complex, rather than in the free, unbound state. The presence of an external dynamic quencher in solution, i.e., the presence of an extra collisional quenching process, transforms the fluorescence of the ligand or macromolecule, intrinsically independent of the complex formation, into a property which is dramatically different in the free state than in the bound state of the fluorophore. The approach is applicable to any model of noncooperative or cooperative ligand binding to a macromolecule and allows for the optimization of the resolution of the binding or kinetic studies for a given ligand-macromolecule system. The application of the method is illustrated by applying it to the study of the binding of the fluorescent derivative of a nucleotide cofactor, epsilon ADP, to the six interacting sites of the E. coli primary replicative helicase DnaB protein hexamer.

Global conformational transitions in Escherichia coli primary replicative helicase DnaB protein induced by ATP, ADP, and single-stranded DNA binding. Multiple conformational states of the helicase hexamer

The direct evidence of dramatic conformational changes of the DnaB hexamer, induced by nucleotide binding, and the presence of multiple conformational states of the enzyme have been obtained by using analytical sedimentation equilibrium, sedimentation velocity studies, and the rigorous fluorescence titration technique. Equilibrium sedimentation measurements show that in the presence of the ATP nonhydrolyzable analog, AMP-PNP, the DnaB helicase fully preserves its hexameric structure. However, in the presence of the saturating concentration of AMP-PNP, the sedimentation coefficient of the hexamer is s20,w = 11.9 +/- 0.2 compared to the sedimentation coefficient s20,w = 10.5 +/- 0.2 of the free DnaB helicase hexamer. This large sedimentation coefficient change indicates dramatic global conformational transitions of the hexamer, encompassing all six subunits, upon binding the ATP analog. In the presence of ADP, the sedimentation coefficient is s20,w = 11.4 +/- 0.2, indicating that the conformation of the ADP form of the hexamer is different from the ATP form. The sedimentation coefficient of the ternary complex DnaB-(AMP-PNP)-depsilonA(pepsilonA)19, s20,w = 12.4, suggests that the DnaB helicase undergoes further conformational changes upon binding single-stranded DNA (ssDNA). The large global structural changes correlate with the functional activities of the enzyme. In the absence of the ATP analog, the hexamer exists in a "closed" conformation which has extremely low affinity toward ssDNA. Upon binding the ATP analog, the DnaB hexamer transforms into a "tense" state which binds ssDNA with an affinity of approximately 4 orders of magnitude higher than in the absence of the nucleotide. In the presence of ADP, the DnaB hexamer assumes a "relaxed" conformation. The functional difference between these two conformations is reflected in the much weaker allosteric effect of ADP on the ssDNA binding with the affinity constant approximately 3 orders of magnitude weaker than in the presence of the ATP analog (tense state).