Conformational states of the switch I region of Ha-ras-p21 in hinge residue mutants studied by fluorescence lifetime and fluorescence anisotropy measurements

doi:10.1110/ps.0236303

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Conformational states of the switch I region of Ha-ras-p21 in hinge residue mutants studied by fluorescence lifetime and fluorescence anisotropy measurements

Steven Kuppens, Mario Hellings, Jan Jordens¹, Stefan Verheyden and Yves Engelborghs

Laboratory of Biomolecular Dynamics, Katholieke Universiteit Leuven, Celestijnenlaan 200D, B-3001 Leuven, Belgium

Reprint requests to: Yves Engelborghs, Laboratory of Biomolecular Dynamics, Katholieke Universiteit Leuven, Celestijnenlaan 200D, B-3001 Leuven, Belgium; e-mail: yves.engelborghs{at}fys.kuleuven.ac.be; fax: 32-16-327974.

(RECEIVED October 14, 2002; FINAL REVISION January 12, 2003; ACCEPTED January 23, 2003)

Article and publication are at http://www.proteinscience.org/cgi/doi/10.1110/ps.0236303.

¹ Present address: Afdeling Biochemie, O. & N., KatholiekeUniversiteit Leuven, Herestraat 49, B-3000 Leuven, Belgium

Abstract

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

The hinge residues (Val29 and Ile36) of the switch I region(also known as the effector loop) of the Ha-ras-p21 proteinhave been mutated to glycines to accelerate the conformationalchanges typical for the effector loop. In this work, we havestudied the influence of the combined mutations on the steady-statestructure of the switch I region of the protein in both theinactive GDP-bound conformation as in the active GTP-bound conformation.Here, we use the fluorescence properties of the single tryptophanresidue in the Y32W mutant of Ha-ras-p21. This mutant has alreadybeen used extensively as a reference form of the protein. Reducingthe size of the side chains of the hinge residues not only acceleratesthe conformational changes but also affects the steady-statestructures of the effector loop as indicated by the changesin the fluorescence properties. A thorough analysis of the fluorescencechanges (quantum yield, lifetimes, etc.) proves that these changesare from a reshuffling between the rotamer populations of Trp.The population reshuffling is caused by the overall structuralrearrangement along the switch I region. The effects are clearlymore pronounced in the inactive GDP-bound conformation thanin the active GTP-bound conformation. The effect of both mutationsseems to be additive in the GDP-bound state, but cooperativein the GTP-bound state.

Keywords: G-proteins; ras protein; molecular switch; conformational change; fluorescence lifetimes

Abbreviations: GDP, 5'-guanosine diphosphate • GTP, 5'-guanosine triphosphate • GNBP, guanine nucleotide binding protein • NMR, nuclear magnetic resonance • EPR, electron paramagnetic resonance • GAP, GTPase activating protein • GEF, guanine exchange factor • GNRP, guanine nucleotide release protein • MD, molecular dynamics • TMD, targeted molecular dynamics • SDS-PAGE, sodium dodecyl sulphate polyacryl amide gel electrophoresis

Introduction

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Ha-ras-p21 is a small protein (189 residues) that belongs tothe extended group of guanine nucleotide-binding proteins (G-proteinsor GNBPs; Bourne et al. 1990, 1991). The membrane-bound Ha-ras-p21functions as a molecular switch that controls growing, proliferation,and differentiation processes of the cell. The ras-genes wereidentified as protooncogenes because of the high occurrenceof point mutations of these genes in human tumors (Barbacid 1987).The Ha-ras-p21 binds guanine nucleotides complexed withmagnesium ions. These magnesium ions contribute to the tightbinding of nucleotides. The physiological state of the protein(and thereby also the position of the molecular switch) dependson the nature of the bound nucleotide. In the active form, theprotein has GTP bound, and upon hydrolysis of GTP and the releaseof the ${gamma}$ -phosphate, the protein changes to the inactive state.After the hydrolysis, the GDP remains bound to the protein.Exchanging the GDP for GTP allows the protein to switch backto the active state (Wittinghofer and Pai 1991). The structuraldifferences between the GTP-bound and GDP-bound conformationsare mainly confined to two segments, the so-called "switch regions."These regions show an increased flexibility in X-ray structuresand in nuclear magnetic resonance (NMR) and electron paramagneticresonance (EPR) experiments (Farrar et al. 1997; Ito et al. 1997).Both switches are connected to the ${gamma}$ -phosphate of GTPwith hydrogen bonds. In this way, the conformational changecan best be described as a loaded-spring mechanism. After hydrolysisof the GTP and release of the ${gamma}$ -phosphate, the switch regionscan relax into the GDP-specific conformation. This mechanismis likely universal for the conformational change in the GNBPs(Vetter and Wittinghofer 2001).

Both hydrolysis and nucleotide exchange processes determinethe conformational state of the protein and are controlled byexternal proteins: the GTPase activating proteins (GAPs) inthe case of the hydrolysis and the guanine exchange factors(GEFs) and guanine nucleotide release proteins (GNRPs) in thecase of the nucleotide exchange (McCormick 1994). For detailedreviews on the structures of G-proteins and their interactionswith GAPs, GEFs, and effectors, see Sprang (1997) and Vetter and Wittinghofer (2001).

Our main interest focuses on the study of the dynamics of conformationaltransitions that occur in this protein. The biological relevanceof the system as well as the small size of Ha-ras-p21 make ita perfect model system to study the mechanisms of conformationaltransitions in GTP-activated proteins. The G-domain of the Ras-proteinwith 166 residues is considered as the minimal signaling unitwhere most other GNBPs are seen as variations on this canonicalstructure (Vetter and Wittinghofer 2001). In our previous research,we studied the conformational transition using computationalmethods, for example, molecular dynamics (MD) and targeted moleculardynamics (TMD) in order to find possible hinges and levers ofthe transition as well as to find a possible pathway for theactivation and deactivation of the molecule (Schlitter et al. 1994;Díaz et al. 1995). In this way, it became clearthat the conformational transition between both states of theprotein is not a single process but rather a succession of differentmicro transitions. It is possible to determine the residuesthat may constitute energy barriers for a certain micro transitionand then design mutants that may affect the transition stateof that particular micro transition in a stabilizing or destabilizingway. According to the calculated TMD pathway, the effector loop(switch I region, residues 30–38) plays a key role inthe transition by transmitting the recognition signal from theP-loop, which interacts with the phosphate chain of the nucleotide,to the switch II region. Two residues (V29 and I36) were identifiedas the main hinges in the movements of the effector loop (Díaz et al. 1997a).They show important dihedral transitions duringthe conformational changes. We expected, therefore, that theirsubstitution by glycines would lower the activation energy ofthe micro transitions and would speed up the overall conformationaltransition. In a previous paper (Kuppens et al. 1999), thesemutants were experimentally constructed and studied. Therefore,we used a fluorescent mutant of Ha-ras-p21 (Y32W) that containsa tryptophan as a fluorescent label in the effector loop. Berylliumtrifluoride is an analog of the ground state of the ${gamma}$ -phosphatein GTP, so it binds to the Ha-ras-p21 GDP complex and activatesit by forming an analog of the Ha-ras-p21 GTP complex. The fluorescenceproperties of the W32 in the GTP-bound form and in the (GDP-BeF₃^-)-boundform are identical (Díaz et al. 1997b). As predicted,the rate constant of the conformational change appeared to be~100 times higher in both mutants when compared with the wildtype. But we also got some indications of structural rearrangementsin the binding site caused by the introduced mutations. Theseindications are supported by the results of Spoerner et al. (2001),who investigated the conformation of the effector loopin the active state using ³¹P-NMR spectroscopy. The ³¹P-NMRexperiments on the GTP-bound p21 reported the existence of (atleast) two conformational states with a strongly temperature-dependentinterconversion (Geyer et al. 1996). The so-called state 2 correspondsto the structure found in the complex with the effectors andis the actual active conformation of Ha-ras-p21. State 1, however,may represent either a single conformation or a mixture of conformationalsubstates in fast exchange on the NMR time scale. In the spectrumof the highly flexible V29G/I36G variant, only state 1 getspopulated supporting the idea that state 1 is not a well-definedarrangement of atoms fixed in space. They conclude that thehigher flexibility of the loop disturbs the fast equilibriumof conformational substates of the effector loop in the activestate (Spoerner et al. 2001).

In this study, we take a deeper look into the structural andconformational consequences that are correlated with the mutantswe have described previously. We also constructed the mutantcontaining both mutations at the hinges of the effector loopto check if the hinges act in an independent or rather in acooperative way.

Results

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

The GDP-bound state and the GTP (or GDP-BeF₃^-)-bound state canbe distinguished using the difference in fluorescence of Trp32of the Y32W mutant of Ha-ras-p21. In the Y32W mutant, this differenceis ~60% (Díaz et al. 1997b). In both double mutants (V29G-Y32Wand Y32W-I36G), the drop in fluorescence intensity is reducedto 30% and lower (Kuppens et al. 1999). In the triple mutant(V29G-Y32W-I36G) of Ha-ras-p21 containing both mutated hingeresidues and the fluorescent Trp, we could not see a significantdifference in fluorescence intensity of the GDP-bound statein the presence and absence of BeF₃^-. The excitation and emissionspectra for the triple mutant are shown in Figure 1.

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Figure 1. (Top) Fluorescence excitation (emission wavelength 343 nm) and (bottom) fluorescence emission (excitation wavelength 280 nm) spectra of Ha-ras-p21 (V29G-Y32W-I36G). Spectra with GDP (circles) and GDP-BeF₃^- (triangles) bound to p21 (5µM) are displayed.

Fluorescence lifetime measurements were performed on all relevantmutants (V29G-Y32W, Y32W-I36G, V29G-Y32W-I36G, and Y32W as reference)in the GDP-bound and the GTP-bound state using phase fluorimetry.To prevent possible hydrolysis of the GTP in the GTP-bound conformation,we made use of the nonhydrolysable analog GTP ${gamma}$ S. In previousstudies, we used the fluorescence lifetime measurements to obtainthe tryptophan fluorescence characteristics of the single tryptophanin the Y32W mutant of the protein in the different conformationalstates (Díaz et al. 1997b). It appeared that the timedependence of the tryptophan fluorescence emission can be describedby a sum of three exponentials, that is, there are three distinctlifetimes, each of which is characterized by a correspondingamplitude. It also appeared that the fluorescence lifetimesof the tryptophan are approximately the same in the differentstates; the only differences arise from the amplitude fractionswhere we noticed the difference between the GDP state and theGTP state. The multiexponential fluorescence decay can be aresult of the presence of different quenching residues in theclose neighborhood of the Trp residue. The relevant quenchersin proteins are the disulfide bridge, the amino-acid side chainsof protonated histidine, cysteine and tyrosine, and the carbonylcarbon of the peptide bond (Chen et al. 1996; Chen and Barkley 1998;Sillen et al. 2000). In the case of Ha-ras-p21, thereare no disulfide bridges present at all, and in the close neighborhoodof the single Trp residue, none of the other mentioned quenchersis present either. Therefore, the different fluorescence lifetimescan be explained as originating from different conformationsof tryptophan with different distances between the atom CE3of tryptophan and the carbonyl atom of the peptide bond (Sillen et al. 2000).This means that the origin of the different lifetimescomes from the existence of different rotamer conformations(or microconformations) of the tryptophan and that the natureof these rotamer conformations is not changed toward the backboneof the loop after the conformational change. What happens isa change in the probability of populating a possible rotamerstate because of a change in the environment surrounding theloop (Sillen et al. 2000). Because of the high solvent exposureof the loop region containing the tryptophan residue and therelatively low restriction in the side-chain movement, the residuecan easily populate the multiple rotamer conformations. Becausethe tryptophan fluorescence properties are different in thedifferent conformations of the protein, we can deduce some structuralinformation about the effector loop that contains the tryptophanresidue. Differences in the fluorescence lifetimes and amplitudesthat occur when we compare the different mutants with each otherwill most probably be the effect of structural rearrangementsat the level of the effector loop that are caused by the correspondingmutations (i.e., V29G, I36G, or both).

The phase measurements of the fluorescence lifetimes of Trp32in the different mutants of p21 in the GDP-bound state are displayedin Figure 2. The analysis of these measurements with GlobalsUnlimited results in the corresponding fluorescence lifetimesdisplayed in Table 1. The phase measurements clearly indicatemajor differences for the different mutants. For all mutants,we see the three intrinsic fluorescence lifetimes and correspondingamplitude fractions as previously described in Díaz et al. (1997b).The differences in the time-resolved fluorescenceof the different mutants are apparent on the level of the amplitudefractions. Table 1 shows that the three lifetimes are approximatelyidentical for all mutants again indicating that the rotamerconformations of Trp are unaffected. On the other hand, we seea shift in the amplitude fractions, that is, the amplitude ofthe short lifetime (a₁) grows from 12% in the Y32W referencemutant to 40% in the triple mutant (V29G-Y32W-I36G); the amplitudeof the second lifetime (a₂) grows from 18% in the referencemutant to 44% in the triple mutant; and the amplitude of thelongest lifetime (a₃) drops from 70% in the reference mutantto 16% in the triple mutant. These amplitude shifts are quitesimilar (especially concerning a₂ and a₃) to the amplitude shiftsin the Y32W mutant when we compare the GDP-bound structure withthe GTP-bound structure. To study the same fluorescence propertiesin the GTP-bound structures of the different mutants of p21,we replaced the GDP by the nonhydrolysable GTP ${gamma}$ S. The phase measurementsof the fluorescence lifetimes of Trp32 in the different mutantsof p21 in the GTP ${gamma}$ S bound state are displayed in Figure 3, thecorresponding fluorescence lifetimes are shown in Table 2. Whenwe compare the fluorescence lifetimes and amplitude fractionsof the different mutants in their GTP ${gamma}$ S bound conformation, wesee that the differences are not as pronounced as in the GDP-boundconformation. The fluorescence properties of the different mutantsin the GTP bound conformation obviously do not show the extendeddifferences as seen for the GDP-bound conformation. Table 2shows us that the amplitude fraction a₃ of the longest lifetimeis not altered, whereas this fraction had the largest differencein the GDP conformation. Only a rather limited rearrangementbetween the amplitude fractions of both shorter lifetimes isnoticeable.

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Figure 2. Phase measurements of the fluorescence lifetimes of the different mutants of Ha-ras-p21 in the GDP bound state: Y32W (circles), V29G-Y32W (diamonds), Y32W-I36G (squares), and V29G-Y32W-I36G (triangles).

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Table 1. Tryptophan fluorescence lifetimes, relative amplitudes, and amplitude-averaged lifetimes of the different mutants of Ha-ras-p21 in the GDP-bound state

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Figure 3. Phase measurements of the fluorescence lifetimes of the different mutants of Ha-ras-p21 in the GTP bound state: Y32W (circles), V29G-Y32W (diamonds), Y32W-I36G (squares), and V29G-Y32W-I36G (triangles).

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Table 2. Tryptophan fluorescence lifetimes, relative amplitudes, and amplitude-averaged lifetimes of Ha-ras-p21 in the GTP ${gamma}$ S-bound state

Because the conformational changes and differences between thedifferent mutants are clearly accompanied by fluorescence changes,we can get a more detailed interpretation of the observed changesby analyzing the quantum yields and the average lifetimes.

Because by definition Q/ ${tau}$ = k_r, we assume that Q/ ${tau}$ = k_r and thatchanges in this factor, for example, upon a mutation, are reflectingchanges in the radiative rate constants or in static quenching,which indeed reduces Q without influencing k_r. A reduction of ${tau}$ is generally considered as a signal of dynamic quenching, butcan be the result of a shortening of individual lifetimes (withconstant amplitudes), which we identify as pure dynamic quenching,or to an increase in the amplitudes of short lifetimes, whichwe consider as population reshuffling. All these factors leadto changes in the quantum yield and can be combined into a setof factors as follows (Sillen and Engelborghs 1998; Sillen et al. 1999):

Where subscript 0 refers to the reference state, for example,the wild-type protein, and where f_kr represents the change inthe average radiative rate constant k_r, f_PR represents populationreshuffling, and f_DQ represents pure dynamic quenching. It shouldbe noted that static quenching also influences f_kr and heterogeneousstatic quenching (i.e., different for each life time component)also influences f_PR next to f_kr. It is clear these factors haveto be analyzed with caution because of the complicating effectof static quenching. This factorization gives us the possibilityto analyze in greater detail the quenching behavior and fluorescencedifferences between the different variants of the Ha-ras-p21protein.

Table 3 displays the fluorescence quantum yields of the differentmutants of Ha-ras-p21. In combination with the average fluorescencelifetimes the average radiative k_r and nonradiative k_nr rateconstants are calculated. In all cases, we see a drop in theaverage radiative rate constant upon the introduction of thehinge residue mutations. There is no apparent difference inthe average radiative rate constant when we compare the GTP-boundconformation with the GDP-bound conformation.

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Table 3. Average lifetimes, quantum yields, radiative and nonradiative rate constants of the Ha-ras-p21 variants

Table 4

gives a detailed overview of the quenching analysisof the discussed variants of Ha-ras-p21. Comparison betweenthe GDP-bound conformation and the GTP-bound conformation forthe Y32W reference mutant and the two single-hinge residue mutantsindicates that the difference in fluorescence properties ismainly caused by population reshuffling. In the triple mutant,with both hinges mutated, the proportion of the quantum yieldsequals one, which was to be expected because of the earlierobserved absence of any difference in fluorescence intensitybetween the two conformations (Fig. 1

). The effect of a mutatedhinge residue can be studied in a similar way by making a quenchinganalysis of these mutants using the Y32W variant as referencestate. Here, we notice both f_PR and f_kr are different from one,indicating multiple causes for the changed fluorescence propertiesupon introduction of the mutations. The errors on the ratiosf_DQ and f_PR are estimated to be ~10%, on the basis of the errorson the ${tau}$ ’s and the ${alpha}$ ’s, respectively. In these errorcalculations, the weight factors ( ${alpha}$ ’s in the case of f_DQand ${tau}$ ’s in the case of f_PR) are considered to be constants.

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Table 4. Relative changes in quantum yields and the quenching factors (f_kr, f_PR, and f_DQ) that contribute to possible differences in the fluorescence properties

Another method used to look at the mobility of the fluorophore-containingstructure is by using time-resolved fluorescence anisotropydecay measurements. In this situation, there is a multiexponentialanisotropy decay caused by the global rotation of the wholeprotein and by the local mobility of the Trp residue, causedboth by the movement of the Trp-containing loop structure andthe movement of the residue itself. Table 5

displays the fluorescenceanisotropy decay parameters of the different mutants in theGDP-bound structure. In the case of the wild-type protein data,we had to apply the associative type of fitting. Each particularlifetime is associated with a specific anisotropy decay. Theshortest lifetime ( ${tau}$ ₁), however, is too short and too small inpopulation to contribute to the measured anisotropy decay. Themiddle lifetime ( ${tau}$ ₂) is actually long enough to see the anisotropydecay but is also very low populated (18%). Together with thelow value for ${alpha}$ , this makes that we were not able to resolvea significant value for ${phi}$ ₁. The anisotropy parameters obtainedfor the longest lifetime ( ${tau}$ ₃), which is highly populated (70%),give the most significant results for the wild-type protein.All other mutants were fitted in the regular nonassociativeway with global anisotropy decay parameters and gave satisfactoryresults. The r₀ values are the initial anisotropy values, witha theoretical maximum of 0,4 when the absorption and emissiondipoles of the fluorescent group are colinear. In the case oftryptopan, the value is usually lower because of a mixture ofthe ¹L_a and ¹L_b transitions (Valeur and Weber 1977; Ruggiero et al. 1990).We attribute the long rotational correlation time ${phi}$ ₂ to the rotational motion of the whole protein, which is expectedto be around 25 ns. The value of ${phi}$ ₂ is much larger than the fluorescencelifetime and therefore the accuracy of this parameter is ratherlimited resulting in relatively high errors. The interestinginformation about the mobility of the loop structure is givenby the parameters ${alpha}$ and ${phi}$ ₁, with ${phi}$ ₁ the correlation time for theinternal motion and ${alpha}$ the amount of depolarization that occursas a result of internal motion of the fluorophore. This amountis related to the angle over which the fluorophore can move.We can see a clear evolution in these parameters upon increasingflexibility between the different hinge residue mutants in theGDP-bound state. The increase in ${alpha}$ from 0,11 in Y32W ( ${tau}$ ₃) to 0,40in the triple mutant shows us the increasing importance of theinternal mobility in the measured fluorescence depolarization.With this parameter, the angle over which the fluorophore canmove is calculated resulting in angles of around 16 degreesfor the Y32W mutant to 31 degrees for the double-hinge residuemutant (Table 5

). Both the single-hinge residue mutants areshowing values lying in between these. The correlation time ${phi}$ ₁ of internal mobility decreases significantly in the double-hingemutant supporting the much higher mobility and higher speedof movement of the fluorophore in this mutant.

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Table 5. Fluorescence anisotropy decay parameters of the GDP-bound state of the different Ha-ras-p21 hinge residue variants

	Discussion

TOP Abstract Introduction Results Discussion Materials and methods References

The small difference in overall fluorescence intensity of theGDP- and GTP-bound state of the triple mutant made kinetic experiments(using a stopped flow instrument) to study the conformationalchange from the GDP to the (GDP-BeF₃^-)-bound state impossible,but it gave us a further indication on the structural rearrangementsoccurring in the binding site as a result of the multiple pointmutations. The fact that the drop in the fluorescence signalfrom 60% in the Y32W-reference reduced to 30% and less in bothdouble mutants was the first indication of structural rearrangementsin the binding site. In these cases, the kinetic experimentswere still possible and therefore our research at that pointwas not focused toward the phenomenon we are studying in thispaper. All the measured and calculated fluorescence parametersof the triple mutant in the GDP-bound state are identical tothose of the Y32W-reference protein in the GTP-bound complex.The most straightforward interpretation of this would be toconclude that the triple mutant protein, although in the GDP-boundcomplex, is frozen in the GTP conformation. In this case, theaffinity for BeF₃^- would be at least as high as in the caseof the wild-type protein if not even higher. This is, however,very unlikely as the double mutants (V29G-Y32W and Y32W-I36G)already show a marked decrease of affinity for BeF₃^- (Kuppens et al. 1999).

In this study, we wanted to characterize the structural rearrangementsin the direct neighborhood of the Trp32 by a comparison of thedifferent time-resolved fluorescence properties of the so-called"switch I mutants" (Kuppens et al. 1999) in their distinct conformations(active and inactive). The measurements of the different mutantsin the inactive GDP-bound conformation clearly show a majorinfluence of the point mutation(s) on the fluorescence propertiesand therefore also on the structure and position of the switchI region. The differences appear largely in the amplitude fractionswhile the three distinct lifetimes stay practically constant.The amplitude of the longest lifetime (a3) drops from 70% inthe reference mutant (Y32W) to 16% in the triple mutant. Bothshorter lifetimes are compensating this with a raise of theiramplitude fractions from, respectively, 12% to 40% for the shortestlifetime ( ${tau}$ 1) and from 18% to 44% for the middle lifetime ( ${tau}$ 2).These large differences can only be explained by structuralrearrangements that place the fluorescent Trp32 in a differentenvironment in the different mutants.

In this discussion, however, it is of crucial importance tokeep in mind that we are talking about a highly flexible loopstructure (both in GDP- and GTP-bound states). Talking aboutthe position of this loop can give the impression that thisis a fixed and localized conformational state. As mentionedin the introduction, the high dynamic mobility (even in thewild-type state) was already extensively proven by X-ray, NMR,and EPR studies. In this way, the position of the loop becomesan averaged parameter of a broad range of closely related conformationsin a fast equilibrium. This implies the possibility that withthe introduction of one or more mutations, this equilibriumis altered, the average position can be altered, or the rangeof conformations can be broadened (e.g., as in a Gaussian distributionwhere the base is broadened and the curve is flattened) andthe time scale of the transition can be altered as well.

We have factorized the changes in quantum yield and averagelifetime as three factors: f_kr, f_DQ, and f_PR. We notice thatin the GDP-bound state, the effect of the hinge residue mutationson the conformational parameter f_PR (indicating the extent ofpopulation reshuffling in the tryptophan rotamers) is clearlyadditive (Fig. 4; Table 4). This implies that the already flexiblestructure is made even more flexible by replacing the hingeswith small Gly residues. In the single-hinge residue mutants,we only increase the flexibility at one end of the loop (respectively,the side of V29 or the side of I36). In the double-hinge mutant,the restriction of movement is deleted from both sides givingthe loop a very high degree of freedom probably resulting inan extremely broadened range of possible conformational substates.

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Figure 4. Visual representation of the f_PR factors (quantifying the extend of population reshuffling) between the different hinge residue mutants and the Y32W reference protein. The GDP-bound structures (left side) and the GTP-bound structures (right side) are placed on the same scale to point out the explicit difference between both cases. The dotted line shows the hypothetical value of f_PR when the two single hinge residue mutants show cumulative effects on the population reshuffling.

On the other hand, when we look at the fluorescence propertiesof Trp32 in the active GTP ${gamma}$ S-bound conformation, we do not seemajor differences between the different mutants. The effecton f_PR is rather limited, and almost identical for all mutants.The effect seems to be slightly higher for the V29G-hinge residuemutant. The additivity of the influence in the double-hingemutant is also lost (Fig. 4

). We can explain this phenomenonby taking a closer look at the structure of the loop. In theGTP-bound conformation, the loop is attached with hydrogen bridgesto the ${gamma}$ -phosphate of the GTP ligand. A main role is played bythe conserved residue Thr-35, which not only forms a highlystabilizing hydrogen bridge with the ${gamma}$ -phosphate of GTP but alsocontributes via its side-chain hydroxyl in the coordinationof the important Mg²⁺-ion and via the methyl group that packsagainst the effector loop and is responsible for a reductionin the flexibility of the loop. The fixation at the positionof residue 35 not only explains the much smaller effect of thehinge residue mutations in the GTP-bound conformation, but alsoexplains the higher effect for the V29G mutation, as the loopgets divided in two parts with the Trp residue positioned onthe side of residue 29. The locking of the loop through thebridge between Thr35 and the phosphate also explains the lossof additivity (or presence of cooperativity) in the double-hingemutant.

Nevertheless, the loop still displays a high flexibility (butlikely not as extended as for the GDP-bound state) in its wild-typestate. The introduction of the hinge residue mutations doesnot affect the fluorescence parameters to the extent they didin the GDP-bound state. Nevertheless, their introduction increasesthe flexibility with a certain amount resulting in a shiftedequilibrium of the conformational substates as also supportedby the results of Spoerner et al. (2001).

This hypothesis is further supported by the results of the quenchinganalysis displayed in Table 4. The difference between the GTP-boundconformation and the GDP-bound conformation is displayed solelyin the population reshuffling (f_PR), which is correlated toa conformational difference between the "average" position ofthe loop in both states. The difference disappears with increasingflexibility. More information concerning the influence of themutations can be gathered when we compare the quenching factorsof the mutants with the wild type. Both in the GDP- and GTP-boundstates, the differences in fluorescence properties are displayedin a combination of differences in f_kr and f_PR. The differencein radiative rate constant (k_r) is of the same order of magnitudefor all mutants in both states. More interesting is the populationreshuffling phenomenon in the hinge residue mutants becausethis population reshuffling in the case of p21 is always correlatedto conformational changes. We see in the GTP-bound state a ratherlimited population reshuffling happening that has the same orderof magnitude for all mutants. In the GDP-bound state, the populationreshuffling is of greater magnitude in all cases and it increaseswith higher flexibility of the effector loop all of which supportthe higher-stated hypothesis and confirm the crucial role ofresidue Thr35 in the structure and functionality of the Ha-ras-p21protein.

The anisotropy measurements are in qualitative agreement withthe expected increasing flexibility upon introduction of moreGly residues. The increased contribution of the correlationtime for internal mobility and accordingly, the calculated averageangle over which the fluorophore rotates, clearly point in thisdirection. The conclusion is that fluorescence spectroscopycan reveal different kinds of dynamical behavior of proteins.Rotamer populations reflect heterogeneity or dynamics on a timescale much slower than nanoseconds, while the fluorescence anisotropydecay reflects local dynamical flexibility of the fluorophoreand the segment containing the Trp residue in the nanosecondtimescale.

Materials and methods

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Analytical-grade beryllium sulfate and potassium fluoride fromMerck & Co. were used to prepare the stock solution of berylliumfluoride; all other chemicals employed were analytical gradeor better.

The beryllium fluoride stock solution was prepared in bufferA (64 mM Tris, 50 mM HCl, 1 mM NaN₃, 1 mM dithioerytrol [DTE]),containing 1 mM MgCl₂, 0.75 M KF, and 0.25 M BeSO₄. The pH waslater adjusted to 7.2. The effective concentration of berylliumtrifluoride was calculated using the effective complexing constantsof the beryllium fluoride system at a given final concentrationof the Be²⁺ and F^- ions (Mesmer and Baes 1969), the berylliumfluoride concentration of the stock turned out to be 176 mM.

The mutants (V29G-Y32W, Y32W-I36G, and V29G-Y32W-I36G) wereconstructed by long-range PCR (Cheng et al. 1994) of the ptac-rasplasmid (Tucker et al. 1986) containing the Y32W mutation, whichwas kindly provided by Prof. Dr. A. Wittinghofer. Escherichiacoli cells of the WK6 line ( ${Delta}$ (lac-proAB) galE straA nal^r [F'lacI^q lacZ ${Delta}$ M15 pro AB⁺]; Zell and Fritz 1987) were transformedwith the obtained plasmids. The mutant proteins were purifiedas described previously (Díaz et al. 1997b), their puritywas checked by SDS-PAGE (Laëmmli 1970) and their activitywas tested by measuring their ability to bind GDP.

Steady-state fluorescence measurements were performed on a Fluorolog1691 spectrofluorimeter (Spex Industries). The excitation wavelengthwas 280 nm, the emission wavelength 343 nm both with slit aperturesof 2 mm, giving a dispersion of 7.2 and 3.6 nm/mm, respectively,for the excitation and emission monochromators.

Fluorescence quantum yields were determined relative to tryptophanin water according to the method of Parker and Rees (1960) usinga quantum yield for tryptophan in water of 0.14 (Chen 1967).

Fluorescence lifetimes were measured using multifrequency-phasefluorimetry between 1.6 Mhz and 1 Ghz (Vos et al. 1997; Sillen et al. 2000).An excitation wavelength of 295 nm was used tomeasure exclusively the tryptophan fluorescence, while the emissionwavelength was set at 330 nm using an Oriel filter. N-acetyl-L-tryptophanamidein water was used as reference. Analysis of the data was donewith global analysis using the software of Globals Unlimited(University of Illinois).

The time-resolved fluorescence anisotropy decay was measuredusing the same multifrequency-phase fluorimeter. The anisotropydecay parameters are obtained by analyzing the experimentaldata using the following formulas:

with

Here is r(t), the time-dependent anisotropy value and r₀, theinitial anisotropy, equal to 0.4 if the emission dipole is colinearwith the absorption dipole. ${alpha}$ is the amount of depolarizationthat occurs from internal motion of the fluorophore and is directlyrelated to the range of angles (ß) over which thefluorophore can move. ${phi}$ ₁ and ${phi}$ ₂ are respectively the correlationtimes of internal motion and the rotation of the whole protein.

Acknowledgments

S. Kuppens is a recipient of an IWT fellowship. We thank Dr.Alain Sillen for the assistance with the anisotropy analysisand useful discussions. This research was supported by grantG.0092.01 of the Fund for Scientific Research (Flanders).

The publication costs of this article were defrayed in partby payment of page charges. This article must therefore be herebymarked "advertisement" in accordance with 18 USC section 1734solely to indicate this fact.

References

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

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