Protein self-association in crowded protein solutions: A time-resolved fluorescence polarization study

doi:10.1110/ps.04809404

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Protein self-association in crowded protein solutions: A time-resolved fluorescence polarization study

Silvia Zorrilla¹, Germán Rivas², A. Ulises Acuña¹ and M. Pilar Lillo¹

¹ Instituto de Química Física "Rocasolano" and ² Centro Investigaciones Biológicas, Consejo Superior Investigaciones Cientificas (CSIC), Madrid, Spain

Reprint requests to: M. Pilar Lillo, Instituto de Química Física "Rocasolano," CSIC, Serrano 119, 28006 Madrid, Spain; e-mail: pilar.lillo{at}iqfr.csic.es; fax: +34-91-5642431.

(RECEIVED April 13, 2004; FINAL REVISION July 9, 2004; ACCEPTED September 5, 2004)

Abstract

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Abstract
Introduction
Results
Discussion
Materials and methods
References

The self-association equilibrium of a tracer protein, apomyoglobin(apoMb), in highly concentrated crowded solutions of ribonucleaseA (RNase A) and human serum albumin (HSA), has been studiedas a model system of protein interactions that occur in crowdedmacromolecular environments. The rotational diffusion of thetracer protein labeled with two different fluorescent dyes,8-anilinonaphthalene-1-sulfonate and fluorescein isothiocyanate,was successfully recorded as a function of the two crowder concentrationsin the 50–200 mg/mL range, using picosecond-resolved fluorescenceanisotropy methods. It was found that apoMb molecules self-associateat high RNase A concentration to yield a flexible dimer. Theapparent dimerization constant, which increases with RNase Aconcentration, could also be estimated from the fractional contributionof monomeric and dimeric species to the total fluorescence anisotropyof the samples. In contrast, an equivalent mass concentrationof HSA does not result in tracer dimerization. This differenteffect of RNase A and HSA is much larger than that predictedfrom simple models based only on the free volume available toapoMb, indicating that additional, nonspecific interactionsbetween tracer and crowder should come into play. The time-resolvedfluorescence polarization methods described here are expectedto be of general applicability to the detection and quantificationof crowding effects in a variety of macromolecules of biologicalrelevance.

Keywords: time-resolved fluorescence anisotropy; macromolecular crowding; self-association; segmental flexibility; apomyoglobin; ribonuclease A; human serum albumin

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

A large variety of physical and chemical processes in livingorganisms take place in highly concentrated solutions (50–400mg/mL) of different macromolecules, which occupy a large fractionof the solution volume (Minton 2001). As a result of that, thereis a significative increase of nonspecific interactions, suchas steric repulsion or electrostatic interactions, which havebeen proven to have large effects on the equilibrium and kineticparameters of biomolecular reactions (Ellis 2001). Previousexperimental and theoretical work demonstrated substantial effectsof crowding on a broad range of biochemical and physiologicalprocesses (Zimmerman and Minton 1993; Minton 2001; Rivas et al. 2004),like macromolecular association (Minton 2000) andprotein folding (Sasahara et al. 2003; Tokuriki et al. 2004).Thus, as would be expected, macromolecular crowding enhancesthe formation of those reaction products that exclude less volumeto other species in the solution such as compact structuresor polymers. The quantification of species populations and thedetermination of apparent equilibrium constants in crowded mediawill be crucial for the correct understanding of biologicalprocesses in physiological environments.

A crowded environment can be mimicked, as a first approximation,by adding to a given solution a high concentration of the crowder,in the form of unrelated synthetic or natural macromolecules(Ellis 2001). However, even in these simplified model systems,monitoring changes in the macromolecule of interest (the tracer)to isolate crowding effects is a difficult experimental challenge.Physical methods based on fluorescence spectroscopy appear veryconvenient for this purpose, due to the possibility of labelingwith extrinsic fluorescent dyes only the tracer protein, whichin this way can be easily distinguished from the crowding macromolecules.In fact, this approach has been applied before to the studyof horse apomyoglobin (apoMb) dimerization in crowded solutions,by means of steady-state fluorescence anisotropy techniques(Wilf and Minton 1981).

Steady-state fluorescence anisotropy values of a labeled tracerprotein depend on the rotational correlation time ( ${phi}$ ) of themacromolecule and on the dye fluorescence lifetime, as expressedby Perrin’s equation (Lakowicz 1999). When the tracerprotein forms oligomers the hydrodynamic volume of the rotatingunit increases, and this results in an increase of ${phi}$ and, consequently,in the fluorescence anisotropy value. However, the oligomerizationprocess may also affect the label fluorescence lifetime and,in this case, the correct interpretation of the recorded fluorescenceanisotropy changes is far from simple. On the other hand, time-resolvedanisotropy methods often allow the direct determination of thetracer rotational correlation time, independently of the changesin the fluorescence lifetime, facilitating the correct identificationof the molecular species present in the solution. In the presentwork, we have further extended the previous steady-state anisotropystudy of apoMb in highly concentrated protein solutions by meansof time-resolved fluorescence anisotropy techniques with picosecondresolution. Two proteins were selected as crowders: ribonucleaseA (RNase A; 13,700 Da), as in the work of Wilf and Minton (1981),and human serum albumin (HSA; 66,500 Da), as one of the majorplasma proteins. In the case of fluorescence studies in concentratedRNase A solutions, the tracer apoMb was labeled with 8-anilinonaphthalene-1-sulfonate(ANS). This dye was selected because of its convenient longfluorescence lifetime (~15 nsec) and the lack of interferinglocal ANS motions when bound to apoMb (Zorrilla et al. 2004a).However, the noncovalent ANS binding to apoMb prevents its usein the presence of HSA, which also contains ANS binding sites(Slavik 1982; Matulis and Lovrien 1998). Therefore, the experimentsin crowded HSA solutions were carried out using a fluoresceindye covalently bound to apoMb.

The fluorescence polarization methods developed in this workserved to characterize apoMb self-association in concentratedprotein solutions and should be of general application to thestudy of other protein interactions. Moreover, these methodsmay also facilitate the extension of current high throughputanalytical techniques based on fluorescence spectroscopy fromdiluted to highly concentrated, crowded solutions.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Characterization of labeled apoMb
ApoMb labeled with fluorescein (apoMb-Fl) and apoMb labeledwith ANS (apoMb-ANS) were first characterized independentlyin diluted solution, to determine the effect of fluorescentlabeling on apoMb hydrodynamics and association. The steady-stateanisotropy of apoMb-Fl, in a diluted buffer solution containing2 µM of the labeled protein and 100 µM of unlabeledapoMb, was r = 0.120 ± 0.005 ( ${lambda}$ _exc = 460 nm, ${lambda}$ _em =520 nm),and the decay of the fluorescence intensity was fitted to atriexponential function (Table 1), with an average lifetime( ${tau}$ _m) of 3.4 ± 0.1 nsec. This complex decay is indicativeof heterogeneity in the dye microenvironment, probably due tothe lack of specificity in the labeling reaction. The decayof the fluorescence anisotropy in the same conditions was fittedto a biexponential function with two correlation times (Table2). The faster correlation time of 0.2 nsec can be assignedto local, independent depolarizing motions of the fluoresceindye, while the slower one (10 ± 1 nsec) agreed with previousdata for the global rotation of monomeric apoMb and Mb in dilutedsolutions (Wang et al. 1997; Tcherkasskaya et al. 2000). Theexperimental time-zero anisotropy, r(0) = 0.25 ± 0.01,was considerably lower than the fundamental anisotropy of fluorescein(~0.4; Chen and Bowman 1965). This decrease is due to ultrafastpicosecond components in the anisotropy decay that could notbe resolved. The fluorescence intensity decay of apoMb-ANS insimilar diluted solutions is best described by a two-exponentialfunction, with ${tau}$ _m =14.7 ± 0.1 nsec (Zorrilla et al. 2004a).In these conditions, the fluorescence anisotropy of apoMb-ANSis monoexponential, with a single correlation time of 9.0 ±0.2 nsec, which is again that expected for the global rotationof monomeric apoMb (Zorrilla et al. 2004a). Additional analyticalultracentrifugation experiments were run with the labeled samplesof apoMb (100 µM total protein concentration, as in thecrowding experiments). These data confirmed that both apoMb-Fland apoMb-ANS are present in monomeric form in the above dilutedsolution conditions, with a molecular mass of 17,500 ±2000 Da (data not shown).

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Table 1. Fluorescence intensity decay parameters^a of apoMb-Fl as a function of increasing concentration of HSA

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Table 2. Time-resolved fluorescence anisotropy parameters of labeled apoMb as a function of increasing concentration of RNase A and HSA

A simple way to determine possible changes in apoMb structuredue to covalent dye labeling is by recording the Försterresonance energy transfer (FRET) between ANS and fluoresceinin the labeled protein. The binding of ANS to apoMb-Fl is takenas a test of protein integrity (Bismuto et al. 1996). If thedye is effectively bound to the protein the ANS-fluoresceinseparation should be less than the diameter of apoMb (~3.5 nm)(Papadopoulos et al. 2000). Because the Förster criticaldistance, R₀, for the ANS-fluorescein pair is 5 nm (Sassaroli et al. 1984),the ANS $->$ fluorescein energy transfer efficiencyshould be higher than 90%, and virtually all the ANS fluorescencewould be quenched. The FRET assay was carried out by addingan excess (40 µM) of ANS to a 5 µM apoMb-Fl solution.In Figure 1

the emission spectra of the mixed solution is presented,together with those of two separated 5 µM apoMb-ANS and5 µM apoMb-Fl solutions for comparison. It is shown thatthe fluorescence band at ~465 nm, corresponding to bound ANS,has been quenched, while that at ~520 nm (apoMb-Fl) increasedsignificantly, indicating the efficient ANS binding to apoMb-Fl.Moreover, a similar assay can be used to estimate the affinityof ANS for the labeled protein. With this purpose, a 25 µMsolution of unlabeled apoMb was added to a solution containing25 µM apoMb-Fl and 25 µM ANS. The ANS emission intensityof the resulting mixture was ${approx}$ 50% of a 25 µM apoMb-ANScontrol sample. This simple experiment indicates that both apoMband apoMb-Fl are competent for ANS binding, with a dye dissociationconstant to apoMb-Fl in the same range as that determined forunlabeled apoMb (3.4•10^–6 M) (Stryer 1965).

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Figure 1. ANS binding to apoMb-Fl: Fluorescence emission spectra of 5 µM apoMb with 40 µM ANS (• •), 5 µM apoMb-Fl (——), and 5 µM apoMb-Fl with 40 µM ANS (- - -), in 20 mM phosphate, 150 mM NaCl, 0.1 mM EDTA (pH 7.4), 20°C, ${lambda}$ _exc =393 nm.

ApoMb self-association in RNase A concentrated solutions
Fluorescence anisotropy measurements were carried out to determinethe possibility of apoMb association in crowded RNase A solutions.The steady-state fluorescence anisotropy of apoMb-ANS in thepresence of RNase A (50–250 mg/mL) increased with RNaseA concentration (Fig. 2

). The polarization values were coincident,within the experimental error, with those published by Wilf and Minton (1981)at the same excitation and emission wavelength( ${lambda}$ _exc = 375 nm, ${lambda}$ _em = 465 nm) (data not shown).

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Figure 2. Steady-state fluorescence anisotropy (r) of labeled apoMb as a function of crowder concentration. (A) ApoMb-ANS in RNase A solutions; [apoMb-ANS] = 80 µM; ${lambda}$ _exc = 393 nm and ${lambda}$ _em = 465 nm. (B) ApoMb-Fl in HSA solutions; [apoMb-Fl] = 2 µM; ${lambda}$ _exc = 460 nm and ${lambda}$ _em = 520 nm. [apoMb]_T = 100 µM. T = 20°C.

The fluorescence intensity decay of apoMb-ANS in the presenceof RNase A (50–250 mg/mL) was biexponential, with an intensityaveraged lifetime ( ${tau}$ _m) of 14.7 ± 0.2 nsec (Zorrilla et al. 2004a).Because this value remains practically unalteredupon addition of increasing concentrations of RNase A, the interpretationof the corresponding anisotropy changes was considerably simplified.When apoMb-ANS was placed in concentrated RNase A solutions(50–250 mg/mL), the anisotropy decay was biexponentialand two well-separated rotational correlation times (Table 2

)were determined at each RNase A concentration, which increasedin parallel with the crowder concentration. The slowest correlationtime ( ${phi}$ ₂), which was not present in diluted apoMb solutions,increased from 24 ± 2 nsec to 54 ± 12 nsec for50–250 mg/mL RNase A solutions. The value of ${phi}$ ₂ extrapolatedto zero RNase A concentration was 22 ± 2 nsec, compatiblewith published values of the rotational time of apohemoglobin(apoHb), a dimeric protein with subunits homologous to monomericapoMb (Sassaroli et al. 1986). On the other hand, the fastestcorrelation time ( ${phi}$ ₁) increased from 9.0 ± 0.2 nsec to12.4 ± 2 nsec for 0–250 mg/mL RNase A solutions.This value, determined for zero RNase A concentration, is assignedto the global depolarizing rotational motion of the apoMb monomer(Zorrilla et al. 2004a). The experimental time-zero anisotropy,r(0) = 0.35 ± 0.01, was coincident with the ANS fundamentalanisotropy (Anderson and Weber 1969) and was independent ofRNase A concentration. This result, together with the absenceof fast depolarization processes, indicates that the ANS chromophoreis rigidly constrained within the hydrophobic apoMb heme pocket.

A parallel experiment was performed with apoMb-Fl in a 200 mg/mLRNase A solution, to test the possible influence of dye labelingon the hydrodynamic parameters of apoMb in RNase A solutions.In these conditions, the steady-state anisotropy of apoMb-Flwas r = 0.150 ± 0.005 ( ${lambda}$ _exc = 460 nm, ${lambda}$ _em = 520 nm) andthe decay of the fluorescence intensity was fitted to a tripleexponential function, with lifetime values of 0.26 ±0.05, 1.3 ± 0.3, and 3.7 ± 0.1 nsec; average lifetime ${tau}$ _m = 3.2 ± 0.1 nsec. The anisotropy decay was best fittedto a function that included a residual anisotropy contribution, ${beta}$ , in addition to two rotational correlation times (Table 2).

Additional insight on apoMb association was obtained from steady-stateanisotropy measurements of apoMb-ANS in samples where the RNaseA concentration was fixed (100, 150, 200, and 250 mg/mL), whileapoMb concentration was varied from 10 µM to 800 µM(Fig. 3). The background residual emission and the noncovalentANS labeling prevented anisotropy measurements below 10 µM.Interestingly, the fluorescence anisotropy remained practicallyunaltered upon addition of apoMb to the solution in the studiedconcentration range. Furthermore, these values were not affectedby the ANS/apoMb labeling ratio (0.2–0.8).

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Figure 3. Steady-state anisotropy (r) of apoMb-ANS as a function of apoMb concentration, in the presence of 250 mg/mL RNase A ( ${circ}$ ), 200 mg/mL RNase A ( ${blacktriangledown}$ ), 150 mg/mL RNase A ( ${triangleup}$ ), and 100 mg/mL RNase A ( ${blacksquare}$ ). ${lambda}$ _exc = 393 nm; ${lambda}$ _em = 465 nm. Dashed/dotted lines correspond to theoretical curves computed from equation 11

, for the lowest apparent equilibrium constant values compatible with experimental data.

ApoMb in HSA concentrated solutions
A parallel study of the association of apoMb was carried outin highly concentrated HSA solutions. The steady-state fluorescenceanisotropy of apoMb-Fl in presence of HAS (5–200 mg/mL)increased with HSA concentration (Fig. 2

), and the fluorescenceintensity decay in these conditions was fitted to a triexponentialfunction (Table 1

). A small increase in the fractional contributionof the two shorter lifetimes was observed at high HSA concentration,without apparent changes in the lifetime values (Table 1

The time-resolved fluorescence anisotropy of apoMb-Fl in thepresence of a high concentration of HSA was best described bytwo correlation times (Table 2). The fastest correlation time( ${phi}$ ₁) was practically independent of HAS concentration and, asindicated above, it is likely due to fast local flapping motionsof the fluorescein dye bound to apoMb. The slowest correlationtime ( ${phi}$ ₂) increased from 10 ± 1 nsec to 14 ± 2nsec for 0–200 mg/mL HSA solutions, and its value determinedfor zero HSA concentration corresponds to the global rotationof monomeric apoMb. The r(0) value was independent on HSA concentration.Additional numerical analyses were run by including a residualanisotropy term in the fitting function. However, only in thecase of the anisotropy decay in 200 mg/mL HSA solution the experimentaldata were compatible with this term, which may be assigned toa 5%–10% of dimeric apoMb (see Discussion).

Discussion

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Abstract
Introduction
Results
Discussion
Materials and methods
References

ApoMb self-associates in highly concentrated RNase A solutions
The relationship between rotational correlation time and hydrodynamicvolume (V) of a spherical particle can be expressed by the Stokes-Einstein-Debyeequation as:

(1)

where ${eta}$ is the solution viscosity, k is the Boltzmann constant,and T is the temperature. This expression has been shown tobe of general applicability to globular proteins in dilutedsolutions (Ferrer et al. 2001; Garcia-Mayoral et al. 2004).Thus, in the case of apoMb solution at [RNase A] = 0, the rotationalcorrelation time ( ${phi}$ ₁ = 9 ± 0.2 nsec) (Table 2) would correspondto the monomeric form of the protein, according to the volumeestimated from equation 1 (Zorrilla et al. 2004a). On the otherhand, when apoMb-ANS is present in solutions with increasingconcentrations of RNase A, a second correlation time ( ${phi}$ ₂) wasdetermined, that extrapolated to zero RNase A concentrationtakes a value (22 ± 2 nsec) compatible with the globalmotion of dimeric apoMb. In fact, this value largely exceedsthat expected for the apoMb monomer in diluted solution (9–10nsec). According to that, one possible way of interpreting thetime-resolved anisotropy data of apoMb-ANS in RNase A crowdedsolutions would be by means of a rigid particle model, in whichthe correlation times ${phi}$ ₁ and ${phi}$ ₂ are associated to the global rotationof apoMb monomer and dimer, respectively, both considered asrigid particles in the nanosecond range. In that case, the fractionalcontributions ( ${beta}$ _i) from the anisotropy decay analysis (Table2) could be directly associated to monomeric and dimeric apoMbmolar fractions (x_i). Thus, for example, in a 250 mg/mL RNaseA solution in which ${beta}$ ₁ = 0.4 and ${beta}$ ₂ = 0.6, this would correspondto 40% of apoMb monomer and 60% of dimer, with rotational correlationtimes of about ~12 nsec and ~54 nsec, respectively. However,this model fails to explain the steady-state experiments reportedin Figure 3, in which the viscosity of the crowded solutionis kept constant and the monomer/dimer ratio is varied. Thesteady-state anisotropy values corresponding to apoMb monomerand rigid dimer, in the 250 mg/mL RNase A solution would ber_m = 0.165 and r_d = 0.275, respectively, as estimated from equation12, and the spectroscopic parameters measured here. Then, theexperimental steady-state fluorescence anisotropy (r), whichis the weighted sum of the individual contribution from eachspecies (r = x_mr_m + x_dr_d), would be very sensitive to changesin the molar fraction of apoMb monomer and dimer (see Materialsand Methods). This expectation is not realized when the r valueof apoMb is recorded at the fixed RNase A concentration of 250mg/mL, neither at any other concentration values shown in Figure3, despite the fact that the monomer/dimer ratio is expectedto change appreciably. Furthermore, monomer and dimer fractionalabundance estimations based on the rigid particle model didnot agree with previous results (Wilf and Minton 1981), whichindicate that apoMb in a 250 mg/mL RNase A solution is presentessentially as a dimeric species. The lack of changes in r inFigure 3 could be understood if the apoMb dimer had a flexiblestructure. In fact, this possibility is strongly supported bythe detection of flexible motions in the homologous dimericprotein apoHb (Sassaroli et al. 1986). In that case, the segmentalmotions of apoMb dimer would have the effect of decreasing thedifference between the monomer (r_m) and dimer (r_d) anisotropyvalues. Because of that, the change in the summed anisotropy(r) as a function of the monomer/dimer ratio (given by the apoMbconcentration) would be negligible in the range studied here(Fig. 3). Therefore, we interpret the results presented herein terms of a flexible particle model, in which the apoMb dimeris represented by two rigid subunits joined together with aflexible link. The depolarizing segmental motions of this dimertake place most likely in a time range close to that of theglobal rotation of apoMb monomer, because only two rotationaltimes are experimentally observed (Table 2). This similaritywas indeed reported in the case of the flexible apoHb dimer(Sassaroli et al. 1986). Accordingly, the correlation time ${phi}$ ₁is assigned to the combination of the segmental motion of apoMbdimer and the global motion of the monomer, while ${phi}$ ₂ pertainsto the dimer global rotation. A flexible apoMb dimer is alsocompatible with the increase in tracer anisotropy as a functionof crowder concentration shown in Figure 2. In this case, thepresence of increasing amounts of the crowder protein (RNaseA or HSA) results in corresponding increases in the rotationalviscosity affecting both monomeric and dimeric species (Zorrilla et al. 2004a),which is reflected in measurable changes in theanisotropy.

The anisotropy decay parameters of apoMb-Fl in a 200 mg/mL RNaseA solution (Table 2) are fully consistent with the flexibleparticle model of apoMb dimerization proposed above. The ${phi}$ ₂ valueagrees with the fast correlation time determined for apoMb-ANSat the same RNase A concentration, which corresponds to thecombined global motion of monomeric apoMb and segmental motionof dimeric apoMb. On the other hand, the correlation time of0.2 nsec is assigned to independent motions of the fluoresceindye, as noted above. The short lifetime of the fluorescein chromophore(~3 nsec) and these fast depolarizing motions in apoMb-Fl ( ${phi}$ ₁~0.2 nsec) precluded the determination of the dimer correlationtime, which appears instead as a residual term ( ${beta}$ ) in the anisotropydecay. This experiment also indicates that self-associationof apoMb to form dimers is an intrinsic characteristic of theprotein, independent of the bound ANS dye.

The data presented above also excluded specific interactionsbetween tracer apoMb and crowder RNase A. These interactions,if present, would result in the heteroassociation of tracerand crowder. In that case, the absence of changes in anisotropyvalues shown in Figure 3 would indicate that all apoMb moleculeswere bound to RNase A forming heterodimers, for all RNase Aand apoMb solutions studied here. Then, the two correlationtimes of apoMb determined in RNase A solutions (Table 2) wouldcorrespond to a heterodimer composed by two rigid subunits linkedby a very flexible joint, in which ${beta}$ ₁ and ${beta}$ ₂ (Table 2) would beassociated to the amplitudes of the flexible subunits and theoverall heterodimer motion, respectively. Because ${beta}$ ₁ decreasesfrom 0.85 to 0.40 in the 50–250 mg/mL RNase A concentrationrange, one needs to assume that the flexibility of the heterodimerwould be strongly reduced at high RNase A concentrations. Previousresults (Wilf and Minton 1981) show that the hydrodynamic volumeof apoMb approaches that of dimeric apoHb as the RNase A concentrationincreases. Both are practically coincident in a 250 mg/mL RNaseA solution, but markedly different at lower RNase A concentrations.Therefore, to explain the above results in terms of heteroassociation,a very flexible apoMb-RNase A complex would be necessary, witha variety of conformations different for each crowder concentration,which seems very unlikely. In conclusion, the simplest interpretationof all the fluorescence data presented above is that apoMb self-associatesin highly concentrated RNase A solutions to yield a flexibledimer species. The monomer ${leftrightarrow}$ dimer equilibrium is almost completelyshifted to the dimer side at RNase A concentrations of 250 mg/mL.

Fractional abundance of monomeric and dimeric apoMb in concentrated RNase A solutions
The apoMb-ANS monomer/dimer molar ratio in concentrated RNaseA solutions can be estimated from time-resolved anisotropy databy assuming that the degree of flexibility of the apoMb dimeris independent on the RNase A concentration (see Materials andMethods). As it is shown in Figure 4, the molar fraction ofdimeric apoMb increased almost linearly with RNase A concentration.

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Figure 4. The apoMb dimer molar fraction as a function of RNase A concentration, computed from the anisotropy parameters of Table 2

as described in the main text.

The apparent equilibrium dimerization constant (K') could notbe extracted from steady-state anisotropy experiments due tothe limited apoMb concentration range that is accessible inthese conditions, as noted above. Nevertheless, model calculationsusing equation 11

(see Materials and Methods), permit to estimatelower limits of K' compatible with the steady-state anisotropyvalues and the fractional abundance of monomer and dimer apoMbspecies, as determined from the time-resolved parameters. Inthis way, the following values were obtained: K' $≥$ 2 x 10⁴ M^–1,K' $≥$ 2 x 10⁵ M^–1, and K' $≥$ 10⁶ M^–1, for RNase A concentrationof 100 mg/mL, 150 mg/mL, and 200 to 250 mg/mL, respectively.The lower limit of the apparent dimerization constant showsa clear tendency to increase with the concentration of RNaseA, which is consistent with the increasing apoMb dimer concentrationin these crowded solutions detected by time-resolved measurements.

The method illustrated here is of general applicability to anyhomo- or heteroassociation reaction in a crowded environment,provided that the steady-state fluorescence anisotropy valuesof the monomeric and oligomeric species differ significantly.Because each experiment is run at a constant crowder concentration,the rotational friction is kept constant and the anisotropychanges would depend only on the hydrodynamic volume of eachmolecular species and on the dye fluorescence lifetime.

Differential effect of HSA and RNase A as crowder proteins
The data presented above show that apoMb self-associates inconcentrated RNase A solutions; while in concentrated HSA solutionsthe tracer protein is in monomeric form, at least in the rangestudied here. This change in the apparent dimerization equilibriumconstant can be analyzed first in terms of the different volumeexcluded to apoMb in HSA and RNase A solutions for the samemass concentration. In this regard, it is important to notethat HSA itself is in monomeric state in the whole concentrationrange studied here (data not shown), while RNase A solutionsare much more heterogeneous. Recent analytical ultracentrifugationexperiments have shown that in the above concentration rangeRNase A molecules may be present as a mixture of monomers andtrimers, monomers and tetramers, or monomers, dimers, and tetramers(Zorrilla et al. 2004b). Although two solutions of RNase A andHSA with the same mass concentration should have approximatelythe same total volume occupied by the macromolecule, the distributionof this occupied volume is markedly different, giving rise toa very different free volume available to apoMb, much lowerin the case of an RNase A solution than in HSA. This is dueto the higher number of macromolecules in RNase A solutions(Fig. 5). A crude estimate of the solution volume, from whichapoMb is excluded in RNase A and HSA solutions, shows that thevolume available to apoMb in 200 mg/mL HSA is comparable tothat of an 80–100 mg/mL RNase A solution. For this lastconcentration of RNase A the apoMb dimer molar fraction detectedhere is ~30%, while this fraction is less than 10% in 200 mg/mLHSA. In conclusion, the differential effect of RNase A and HSAis parallel to the different free volume available to apoMbin these two crowded solutions.

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Figure 5. Idealized scaled representation of excluded and free volume in crowded solutions. (A) 200 mg/mL RNase A solution containing monomers and tetramers of the crowder. (B) 200 mg/mL RNase A solution containing monomers and trimers, and (C) 200 mg/mL HSA solution. All species are represented as spherical particles of equivalent volume, assuming an hydration of 0.3 g of water/g protein. The black circle represents an apoMb monomer molecule.

A semiquantitative estimate of the extent of excluded volumeinfluence on the monomer/dimer association equilibrium of atracer protein can be obtained from several existing theoreticalmodels (Minton 1998). Thus, for example, the activity coefficientof a spherical tracer (apoMb in this case) due to a sphericalcrowder can be computed from the scaled particle theory of Boublik(Boublik 1986). Although in some of the experiments describedabove the real situation can be more complex, due to heterogeneityin crowder size distribution and a nonspherical dimer conformation,this computation may provide interesting worst-case expectationchanges of the apparent association equilibrium constants. Infact, computations based on the above model (Minton 1998) predictthat the K' value should increase by a factor of ~2.2 for achange in RNase A crowding concentration from 100 to 200 mg/mL(data not shown), to be compared with the experimental changeof about two orders of magnitude reported here. In the caseof HSA the theoretically predicted change is ~1.5. One may concludethat this model correctly predicts, in a qualitative way, theobserved difference between RNase A and HSA crowding effects,although fails short to account for each individual crowdingeffect. This large discrepancy is unlikely due to model limitationsbut, rather on the contrary, it is probably an indication ofadditional nonspecific crowder–tracer interactions inthe solutions studied here, as, for example, those originatedfrom electrostatic charges, which are different for the twocrowder proteins.

Conclusions
The changes in steady-state and time-resolved fluorescence anisotropyof apoMb-ANS and apoMb-Fl, recorded in the presence of largeconcentrations of RNase A, indicate that the tracer proteinin this crowding environment self-associates to yield flexibledimers. The spectroscopic techniques described here allowedthe characterization of the hydrodynamic properties of the monomericand dimeric species, as well as an estimate of the lower limitfor the apparent dimerization equilibrium constant as a functionof crowder concentration. On the other hand, it is also shownthat self-association of apoMb does not take place in the presenceof an equivalent mass concentration of HSA. The different effectof the two crowder proteins, RNase A and HSA, can only partiallybe interpreted by the large difference in free volume availableto the tracer protein, which is much smaller in the first case.Additional, nonspecific crowder-dependent effects should alsobe operating.

Materials and methods

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Chemicals
Proteins
Crystallized and lyophilized horse skeletal muscle myoglobin(Mb), crystallized and lyophilized HSA and five times crystallizedpancreatic bovine RNase A were purchased from Sigma-AldrichChemie Gmbh. All the proteins were used without further purification,but extensively dialyzed against working buffer previously toany experiment.

Fluorescent labels: 8-anilinonaphthalene-1-sulfonic acid ammoniumsalt was purchased from Fluka Chemie AG, and fluorescein-5-isothiocyanate(FITC) was obtained from Molecular Probes, Inc.

All the experiments were carried out in 20 mM phosphate, 150mM NaCl, 0.1 mM EDTA buffer (pH 7.4), at 20 ± 0.1°C.

Preparation and labeling of apomyoglobin
ApoMb was prepared from Mb by a modification of the acid/acetonemethod (Rossi-Fanelli et al. 1958; Wilf and Minton 1981). ApoMbyield was 60%–70%. The efficiency of heme group removal,determined from the absorbance ratio at 405 and 280 nm (Wilf and Minton 1981),was 98%. Protein concentration was determinedby absorbance measurements performed on a Cary 3E spectrophotometer,using molar absorption coefficients of 15,700 M^–1 cm^–1for apoMb at 280 nm (Wilf and Minton 1981); 9800 M^–1 cm^–1for RNase A at 277.5 nm (Sela and Anfinsen 1957; Torrent et al. 1999);and 34,600 M^–1 cm^–1 for HSA at 280 nm(Mach et al. 1992; Peters Jr. 1996).

ApoMb was labeled with ANS, in the form of a stable 1:1 noncovalentcomplex (Stryer 1965). The concentration of added ANS was determinedfrom its absorbance at 350 nm, using a molar absorption coefficientof 5000 M^–1 cm^–1 (Stryer 1965). Labeling ratiosin the 0.2–0.8 range were estimated from the value ofthe binding constant (3.4 x 10^–6 M) (Stryer 1965). Thefluorescence emission of free ANS in buffer solution was negligiblecompared with that of the protein-bound form (Stryer 1965).

Nonspecific covalent amino terminal and lysine labeling of apoMbwith FITC was performed by adding the fluorophore to an apoMbsolution in a 5:1 molar ratio, in 0.2 M phosphate buffer atpH 8.0. The labeling reaction was carried out for 30 min atroom temperature and the unreacted dye was removed with a HiTrapcolumn (Pharmacia Biotech). The dye/protein ratio after labelingwas 1.2, estimated from absorbance measurements at 490 and 280nm, respectively. The molar absorption coefficient of boundfluorescein at 490 nm used here was 72,800 M^–1 cm^–1(Diehl and Horchak-Morrils 1987).

Steady-state and time-resolved anisotropy measurements
Fluorescence spectra and anisotropy measurements were performedon a photon-counting SLM 8000D spectrofluorimeter fitted withGlan-Taylor polarizers in the excitation and emission channels,at 20 ± 0.1°C. The steady-state fluorescence anisotropyis defined as:

(2)

where I_II and I are the intensities observed in the paralleland perpendicular directions to the plane of polarization ofthe excitation beam, respectively. G is a scaling factor thataccounts for differences in the detection efficiency for thetwo polarized intensities.

Picosecond-resolved fluorescence intensity and anisotropy measurementswere carried out using two time-correlated single photon countinglaser systems, one with a PicoQuant 393 nm diode laser beamas the excitation source (as described in Organero et al. 2002),and a second one with a Spectra Physics Ti:sa mode-locked laser,associated to a second harmonic generator tuned at 460 nm (asdescribed in Lillo et al. 2002). The first one was used forapoMb-ANS samples and the second one in the apoMb-Fl experiments,with a time resolution of 12.2 and 13.1 psec/channel, respectively.

The fluorescence anisotropy decay r(t) was determined by simultaneousanalysis of the parallel I_II (t) and perpendicular I(t) emissionintensity components:

(3)

(4)

(5)

where I(t), ${tau}$ _i, and a_i are the total fluorescence decay, thefluorescence lifetimes, and the preexponential factors, respectively( ${sum}$ a_i = 1). The intensity averaged fluorescence lifetime was calculatedas .

The fitting function was usually a sum of exponentials of theform (Lakowicz 1999; Valeur 2002):

(6)

where r(0) is the time-zero anisotropy, ${phi}$ _i the rotational correlationtimes, and ${beta}$ _i the fractional amplitudes. For anisotropy decayswith a residual anisotropy term (r(0)• ${beta}$ ), the fitting functionwas:

(7)

Data analysis was performed using nonlinear least-squares globalmethods from the Globals Unlimited general-purpose program.The quality of the fit was determined from global ${chi}$ ² values andvisual inspection of the weighted residuals distribution.

Steady-state and time-resolved anisotropy measurements of apoMb-ANSin highly concentrated RNase A solutions were performed keepingthe total apoMb concentration constant (100 µM; 1.7 mg/mL)while changing the RNase A concentration (50–250 mg/mL).In addition, some steady-state anisotropy measurements wereperformed for a constant RNase A concentration of 100, 150,200, and 250 mg/mL and variable apoMb concentration (10–800µM). In this case, the excitation and emission wavelengthswere 393 nm and 465 nm for all the steady-state and time-resolvedanisotropy determinations.

For highly concentrated HSA solutions, steady-state anisotropymeasurements were carried out with samples containing 2 µMapoMb-Fl and additional unlabeled apoMb until a total apoMbconcentration of 100 µM, with excitation and emissionwavelengths at 460 nm and 520 nm, respectively. ApoMb-Fl ina 200 mg/mL RNase A solution was also studied in the same conditions.

The background fluorescence from unlabeled concentrated proteinsolutions was recorded and substracted for all the spectroscopicdeterminations. The fluorescence measurements were taken atleast 1 h after solution preparation, to assure equilibriumconditions.

Determination of apoMb monomer and dimer molar fractions
The fluorescence anisotropy decay of apoMb-ANS in concentratedRNase A solutions was fitted to a double exponential functionwith rotational correlation times ${phi}$ ₁ and ${phi}$ ₂ (equation 6). Foran apoMb solution containing labeled monomer and dimer species,the anisotropy decay is a weighted function of the individualmonomer and dimer anisotropy decays, r_m(t) and r_d (t):

(8)

where ${beta}$ _m is the fractional intensity of monomeric apoMb. In theflexible particle model, ${phi}$ ₁ was assigned to a combination ofthe global motion of monomeric apoMb and the segmental localmotion of dimeric apoMb, while ${phi}$ ₂ was assigned to the overallmotion of dimeric apoMb (see above). Then equation 6 can berecast as follows:

(9)

where and are the fractional amplitudes corresponding to the global and localmotions of dimeric apoMb, respectively (). Assuming that the contribution of flexibility to the dimer depolarizationwas constant and equal to that found in a 250 mg/mL RNase Asolution, where virtually all apoMb is in dimeric form (Wilf and Minton 1981),then and. Finally, in the absence of spectroscopic changes in the fluorescentlabel upon dimer formation, the molar fraction of dimeric apoMbcoincides with the fractional intensity of the dimer (x_d = 1- ${beta}$ _m), and it can be estimated as:

(10)

Determination of the apparent equilibrium dimerization constant
For a solution containing only monomeric and dimeric fluorescentspecies of apoMb-ANS, detected at a given pair of excitationand emission wavelengths, the value of the steady-state anisotropyis given by: r = f_dr_d + f_mr_m. In this expression r_d and r_m arethe dimer and monomer fluorescence anisotropies and f_d and f_mthe corresponding fractional fluorescence intensities, which,in the absence of spectral changes in ANS upon dimer formationcorrespond to the respective molar fractions. On the other hand,the apparent equilibrium dimerization constant can be writtenas: K' = [d]/[m]², where [d] and [m] are the molar concentrationof dimeric and monomeric apoMb at equilibrium, respectively.Combining this equation with that from above for the anisotropyof a monomer/dimer mixture, an expression that relates the steady-stateanisotropy with the apparent dimerization equilibrium constantcan be derived (Chauvin et al. 1994):

(11)

where r is the steady-state anisotropy of apoMb measured fora total molar concentration [apoMb]_T. Theoretical steady-stateanisotropy curves were calculated from equation 11 for differentvalues of the apparent equilibrium constant for each RNase Aconcentration. Because r_d and r_m values cannot be obtained directlyin these solutions, these values were estimated from the time-resolvedfluorescence parameters measured here for dimeric and monomericapoMb at each RNase A concentration and the expression (Lakowicz 1999):

(12)

Footnotes

Article published online ahead of print. Article and publicationdate are at http://www.proteinscience.org/cgi/doi/10.1110/ps.04809404.

Acknowledgments

We thank Dr. A. Douhal for instrumentation facilities in theANS-apoMb experiments. We also thank Dr. A.P. Minton for insightfuldiscussion and advice, Dr. C. Alfonso for the performance ofanalytical ultracentrifugation experiments, and an unknown reviewerfor very helpful criticisms. This work was supported by grantsBQU/2000–1500, BIO99-0859-C03, BQU/2003-4430, and SAF/2003-04266from the Spanish Dirección General de EnseñanzaSuperior e Investigación (DGESI), and grant 07B/0042/1999from Comunidad de Madrid. S.Z. was a predoctoral fellow of theComunidad de Madrid (CAM).

References

TOP
Abstract
Introduction
Results
Discussion
Materials and methods
References

Anderson, S.R. and Weber, G. 1969. Fluorescence polarization of the complexes of 1-anilino-8-naphthalenesulfonate with bovine serum albumin. Evidence for preferential orientation of the ligand. Biochemistry 8: 371–377.[CrossRef][Medline]

Beechem, J.M., Gratton, E., Ameloot, M., Knutson, J.R., and Brand, L. 1991. The global analysis of fluorescence intensity and anisotropy decay data: Second-generation theory and programs. In Topics in fluorescence spectroscopy, Vol. 2 (ed. J.R. Lakowicz), pp. 241–305. Plenum Press, New York.

Bismuto, E., Sirangelo, I., Irace, G., and Gratton, E. 1996. Pressure-induced perturbation of apomyoglobin structure: Fluorescence studies on native and acidic compact forms. Biochemistry 35: 1173–1178.[CrossRef][Medline]

Boublik, T. 1986. Equations of state of hard body-fluids. Mol. Phys. 59: 371–380.[CrossRef]

Chauvin, F., Brand, L., and Roseman, S. 1994. Sugar transport by the bacterial phosphotransferase system. Characterization of the Escherichia coli enzyme I monomer/dimer equilibrium by fluorescence anisotropy. J. Biol. Chem. 269: 20263–20269.[Abstract/Free Full Text]

Chen, R.F. and Bowman, R.L. 1965. Fluorescence polarization: Measurement with ultraviolet-polarizing filters in a spectrophotometer. Science 147: 729–732.[Abstract/Free Full Text]

Diehl, H. and Horchak-Morris, N. 1987. Studies on fluorescein: The absorbance of fluorescein in the ultraviolet as a function of pH. Talanta 34: 739–741.[CrossRef]

Ellis, R.J. 2001. Macromolecular crowding: An important but neglected aspect of the intracellular environment. Curr. Opin. Struct. Biol. 11: 114–119.[CrossRef][Medline]

Ferrer, M.L., Duchowicz, R., Carrasco, B., García de la Torre, J., and Acuña, A.U. 2001. The conformation of serum albumin in solution: A combined phosphorescence depolarization-hydrodynamic modelling study. Biophys. J. 80: 2422–2430.[Abstract/Free Full Text]

García-Mayoral, M.F., García-Ortega, L., Lillo, M.P., Santero, J., Martínez del Pozo, A., Gavilanes, J.G., Rico, M., and Bruix, M. 2004. NMR structure of the non-cytotoxic ${alpha}$ -sarcin mutant ${Delta}$ (7–22): The importance of the native conformation of peripheral loops for activity. Protein Sci. 13: 1000–1011.[Abstract/Free Full Text]

Lakowicz, J.R. 1999. Principles of fluorescence spectroscopy, 2nd ed. (ed. J.R. Lakowicz). Kluwer Academic-Plenum Publishers, New York.

Lillo, M.P., Cañadas, O., Dale, R.E., and Acuña, A.U. 2002. Location and properties of the taxol binding center in microtubules: A picosecond laser study with fluorescent taxoids. Biochemistry 41: 12436–12449.[CrossRef][Medline]

Mach, H., Middaugh, C.R., and Lewis, R.V. 1992. Statistical determination of the average values of the extinction coefficients of tryptophan and tyrosine in native proteins. Anal. Biochem. 200: 74–80.[CrossRef][Medline]

Matulis, D. and Lovrien, R. 1998. 1-Anilino-8-naphthalene sulfonate anion-protein binding depends primarily on ion pair formation. Biophys. J. 74: 422–429.[Abstract/Free Full Text]

Minton, A.P. 1998. Molecular crowding: Analysis of effects of high concentrations of inert cosolutes on biochemical equilibria and rates in terms of volume exclusion. Methods Enzymol. 295: 127–149.[Medline]

———. 2000. Implications of macromolecular crowding for protein assembly. Curr. Opin. Struct. Biol. 10: 34–39.[CrossRef][Medline]

———. 2001. The influence of macromolecular crowding and macromolecular confinement on biochemical reactions in physiological media. J. Biol. Chem. 276: 10577–10580.[Free Full Text]

Organero, J.A., Tormo, L., and Douhal, A. 2002. Caging ultrafast proton transfer and twisting motion of 1-hidroxi-2-acetonaphthona. Chem. Phys. Lett. 363: 409–414.[CrossRef]

Papadopoulos, S., Jurgens, K.D., and Gros, G. 2000. Protein diffusion in living skeletal muscle fibers: Dependence on protein size, fiber type, and contraction. Biophys. J. 79: 2084–2094.[Abstract/Free Full Text]

Peters Jr., T. 1996. All about albumin. Biochemistry, genetics and medical applications. Academic Press, San Diego, CA.

Rivas, G., Ferrone, F., and Herzfeld, J. 2004. Life in a crowded world. EMBO Rep. 5: 23–27.[CrossRef][Medline]

Rossi-Fanelli, A., Antonini, E., and Caputo, A. 1958. Structure of hemoglobin. I. Physicochemical properties of human globin. Biochim. Biophys. Acta 30: 608–615.

Sasahara, K., McPhie, P., and Minton, A.P. 2003. Effect of dextran on protein stability and conformation attributed to macromolecular crowding. J. Mol. Biol. 326: 1227–1237.[CrossRef][Medline]

Sassaroli, M., Bucci, E., Liesegang, J., Fronticelli, C., and Steiner, R.F. 1984. Specialized functional domains in hemoglobin: Dimensions in solution of the apohemoglobin dimer labeled with fluorescein iodoacetamide. Biochemistry 23: 2487–2491.[CrossRef][Medline]

Sassaroli, M., Kowalczyk, J., and Bucci, E. 1986. Probe dependence of correlation times in heme-free extrinsically labeled human hemoglobin. Arch. Biochem. Biophys. 251: 624–628.[CrossRef][Medline]

Sela, M. and Anfinsen, C.B. 1957. Spectrophotometric and polarimetric experiments with ribonuclease. Biochim. Biophys. Acta 24: 229–235.[Medline]

Slavik, J. 1982. Anilinonaphthalene sulfonate as a probe of membrane composition and function. Biochim. Biophys. Acta 694: 1–25.[Medline]

Stryer, L. 1965. The interaction of a naphthalene dye with apomyoglobin and apohemoglobin. A fluorescent probe of non-polar binding sites. J. Mol. Biol. 13: 482–495.[Medline]

Tcherkasskaya, O., Ptitsyn, O.B., and Knutson, J.R. 2000. Nanosecond dynamics of tryptophans in different conformational states of apomyoglobin proteins. Biochemistry 39: 1879–1889.[CrossRef][Medline]

Tokuriki, N., Kinjo, M., Negi, S., Hocino, M., Goto, Y., Urabe, I., and Yomo, T. 2004. Protein folding by the effects of macromolecular crowding. Protein Sci. 13: 125–133.[Abstract/Free Full Text]

Torrent, J., Connelly, J.P., Coll, M.G., Ribo, M., Lange, R., and Vilanova, M. 1999. Pressure versus heat-induced unfolding of ribonuclease A: The case of hydrophobic interactions within a chain-folding initiation site. Biochemistry 38: 15952–15961.[CrossRef][Medline]

Valeur, B. 2002. Molecular fluorescence principles and applications. Wiley-VCH, Weinheim, Germany.

Wang, D., Kreutzer, U., Chung, Y., and Jue, T. 1997. Myoglobin and hemoglobin rotational diffusion in the cell. Biophys. J. 73: 2764–2770.[Abstract/Free Full Text]

Wilf, J. and Minton, A.P. 1981. Evidence for protein self-association induced by excluded volume. Myoglobin in the presence of globular proteins. Biochim. Biophys. Acta 670: 316–322.[Medline]

Zimmerman, S.B. and Minton, A.P. 1993. Macromolecular crowding: Biochemical, biophysical, and physiological consequences. Annu. Rev. Biophys. Biomol. Struct. 22: 27–65.[Medline]

Zorrilla, S., Rivas, G., and Lillo, M.P. 2004a. Fluorescence anisotropy as a probe to study tracer proteins in crowded solutions. J. Mol. Recognit. 17: 408–416.[CrossRef][Medline]

Zorrilla, S., Jiménez, M., Lillo, M.P., Rivas, G., and Minton, A.P. 2004b. Sedimentation equilibrium in a solution containing an arbitrary number of solute species at arbitrary concentrations: Theory and application to concentrated solutions of ribonuclease. Biophys. Chem. 108: 89–100.[CrossRef][Medline]

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