The SC3 Hydrophobin Self-Assembles into a Membrane with Distinct Mass Transfer Properties

doi:10.1529/biophysj.104.057794

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The SC3 Hydrophobin Self-Assembles into a Membrane with Distinct Mass Transfer Properties

X. Wang^*, Fuxin Shi, H. A. B. Wösten, H. Hektor^*, B. Poolman and G. T. Robillard^*

^* Biomade Technology Foundation, Groningen, The Netherlands; Department of Biochemistry, University of Groningen, Groningen, The Netherlands; Department of Membrane Cell Biology, Medical Faculty, University of Groningen, Groningen, The Netherlands; and Department of Microbiology, Institute of Biomembranes, University of Utrecht, Utrecht, The Netherlands

Correspondence: Address reprint requests to Prof. Dr. G. T. Robillard, BiOMaDe Technology, Nijenborgh 4, 9747 AG Groningen, The Netherlands. Tel.: 31-50-3634321; Fax: 31-50-3634429; E-mail: robillard{at}biomade.nl.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Hydrophobins are a class of small proteins that fulfill a widespectrum of functions in fungal growth and development. Theydo so by self-assembling into an amphipathic membrane at hydrophilic-hydrophobicinterfaces. The SC3 hydrophobin of Schizophyllum commune isthe best-studied hydrophobin. It assembles at the air-waterinterface into a membrane consisting of functional amyloid fibrilsthat are called rodlets. Here we examine the dynamics of SC3assembly at an oil-water and air-water interface and the permeabilitycharacteristics of the assembled layer. Hydrophobin assembledat an oil-water interface is a dynamic system capable of emulsifyingoil. It accepts soluble-state SC3 oligomers from water in aunidirectional process and sloughs off SC3 vesicles back intothe water phase enclosing a portion of the oil phase in theirhydrophobic interior. The assembled layer is impermeable tosolutes >200 Da from either the water phase or the oil phase;however, due to the emulsification process, oil and the hydrophobicmarker molecules in the oil phase can be transferred into thewater phase, thus giving the impression that the assembled layeris permeable to the marker molecules. By contrast, the layerassembled at an air-water interface is permeable to water vaporfrom either the hydrophobic or hydrophilic side.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Hydrophobins are a class of small proteins that play an importantrole in fungal growth and development (Wösten, 2001). Forinstance, they allow fungi to escape an aqueous environment,confer hydrophobicity to fungal surfaces in contact with air,and mediate attachment of fungi to hydrophobic surfaces. Hydrophobinshave diverse amino acid sequences but share eight conservedcysteine residues (Wessels, 1997). Class I and class II hydrophobinsare distinguished on the basis of differences in hydropathypatterns and biophysical properties (Wessels, 1994). SC3 ofSchizophyllum commune is the best characterized class I hydrophobin.It self-assembles at interfaces between water and air, waterand oil, and water and a hydrophobic solid (Wösten et al.,1993, 1994a, 1995) Mature SC3 consists of 112 amino acids (deVocht et al., 1998). Its eight cysteine residues form four disulfidebridges (de Vries et al., 1993) that prevent spontaneous self-assemblyin solution and thus account for the controlled assembly athydrophilic-hydrophobic interfaces (de Vocht et al., 2000).SC3 contains 17–22 mannose residues that are attachedto threonine residues in the N-terminal part of the protein(de Vocht et al., 1998). These sugar residues are exposed atthe hydrophilic side after self-assembly and thus determinethe surface properties of this side (Wösten et al., 1994b;de Vocht et al., 1998; Scholtmeijer et al., 2002).

SC3 undergoes several conformational changes during self-assembly.Hydrophobin exists in water as oligomers that are rich in ß-sheet(de Vocht et al., 1998; Wang et al., 2002). Oligomerizationof SC3 takes place above a critical concentration of $~$ 4 µg/ml.(Wang et al., 2002, 2004a). Upon assembly at the air-water interface,SC3 proceeds through an intermediate form with increased ${alpha}$ -helicalstructure ( ${alpha}$ -helical state) to a film which has a ß-sheetsignature but no clear ultrastructure (ß-sheet I state)and, finally, after prolonged incubation, to the ß-sheetII state consisting of amyloid-like fibrils 10 nm in diameterthat are called rodlets (Wösten et al., 1993; Wöstenand de Vocht, 2000; de Vocht et al., 1998, 2002). The rodletsformed by SC3 are composed of two tracks of 2–3 protofilamentsthat are 2.5 nm wide (Wösten and de Vocht, 2000). Likeother amyloid fibrils (LeVine, 1993), they increase the fluorescenceof thioflavin T and bind Congo red (Wösten and de Vocht,2000; Mackay et al., 2001; Butko et al., 2001). Assembly ofSC3 on a Teflon surface is similar to that at the air-waterinterface except that it does not spontaneously adopt its stableend form at this interface. Instead it stops at the intermediate ${alpha}$ -helical state and only proceeds to the ß-sheet stateafter treating the SC3 coated Teflon surface with detergentat elevated temperatures (de Vocht et al., 1998, 2002). A predictedamphipathic helix between the third and fourth cysteine hasbeen identified as responsible for the binding to a Teflon surfaceand inducing significant structural change to the ${alpha}$ -helical-statestructure (Wang et al., 2004b).

Here we show that functional amyloid fibrils spontaneously formnot only at an air-water interface but also at an oil-waterinterface. The SC3 membrane consisting of amyloid fibrils ispermeable to water vapor but the diffusion of molecules >200Da is blocked. However, the molecules >200 Da can pass throughthe membrane via soluble-state SC3-assisted emulsification whichis driven by one-way insertion of SC3 into the membrane andthe resulting increase of surface area.

MATERIALS AND METHODS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Purification and labeling of hydrophobins
A monokaryotic strain of S. commune with a deleted SC15 gene(Lugones et al., 2004) was used for production of the SC3 hydrophobin.The fungus was grown in production medium (Scholtmeijer et al.,2002) in 1 L shaken cultures (225 rpm) for 5–7 days at24°C. SC3 was purified from the culture medium as described(Wösten et al., 1993; Wessels, 1997). SC3 was labeled withdansyl or dabcyl according to Wang et al. (2002).

Self-assembly of SC3 at the air-water and oil-water interface
Freeze-dried labeled or unlabeled SC3 was treated with trifluoroaceticacid to dissociate assemblages into soluble-state SC3 (de Vrieset al., 1993; Wösten et al., 1993). After removing thesolvent by a stream of air, the protein was taken up in 50 mMsodium phosphate, pH 7.0 (1 mg/ml). In the case of FRET experiments,stock solutions of dabcyl and dansyl labeled SC3 were mixed1:1 and incubated for 30 min before use, or stock solution ofdansyl-SC3 was used for coating first, followed by the additionof a dabcyl-SC3 stock solution to a ratio of 1:1.

Assembly of SC3 at the air-water interface was done as follows.A soluble-state SC3 stock solution (1 mg/ml) was diluted 10-foldin a cuvette containing 50 mM sodium phosphate, pH 7.0, andthe solution was allowed to stand at room temperature for astated time before measurements were carried out. In the caseof assembly at an oil-water interface, paraffin oil was layeredon top of the buffer solution immediately after soluble-stateSC3 was added to the buffer. In the case of assembly at an oil-waterinterface in an emulsion, emulsions of organic solvents (butanol,hexane, and hexadecane) and oils (olive oil, paraffin oil) in50 mM sodium phosphate, pH 7.0 (2.5% v/v) were prepared. Thesewere obtained by bath sonication for 10 min just before addingSC3 to a final concentration of 100 µg/ml.

Incorporation of SC3 into an SC3 membrane already assembled at an oil-water interface
SC3 was added to an oil-water emulsion to a final concentrationof 100 µg/ml. After overnight incubation, the oil dropletswere either washed or not washed. All procedures were carriedout at room temperature. Washing was done in the following way.An aliquot of 2 ml was centrifuged at 1000 rpm in an Eppendorftable centrifuge for 2 min. The buffer was carefully removedwith a glass pipette, and the oil was resuspended in 2 ml ofbuffer. This was repeated 3 times with 30-min incubation periodsbetween the washes. A dansyl-SC3 solution was then added toall the samples including a control sample with SC3 alone (nooil droplets). At given times, a 1-ml aliquot was filtered througha 0.2-µm low-protein-binding membrane (Millex-LG, Millipore,Billerica, MA), and the dansyl fluorescence in the filtratewas measured to determine the loss of dansyl-SC3 from the solution,i.e., the incorporation of dansyl-SC3 into the membrane.

The converse experiment was carried out with dansyl-SC3 beingadded to the oil emulsion first, followed by the addition ofunlabeled-SC3 after the washes. The gain of dansyl fluorescencein the filtered solution was measured at the end to determinethe release of dansyl-SC3 from the membrane.

Thickness of an SC3 membrane formed at an air-water interface
A 100 µl volume of SC3 solution (100 µg/ml) in 50mM phosphate, pH 7.0, was dried down on a 1 x 1-cm mica surface,and the thickness of the membrane formed was determined to be $~$ 47 nm by AFM. The refractive index of assembled SC3 in the membranewas determined with a Nanofilm EP3 ellipsometer (LayTec, Berlin,Germany), and the resulting value, 1.535, was used to determinethe thickness of the membrane formed at an air-water interfaceusing the same equipment. For this measurement, a plastic cuvettewas filled with freshly prepared soluble-state SC3 in 50 mMsodium phosphate, pH 7.0, at a concentration of 100 µg/mlor 10 µg/ml. The position and the height of the cuvettewere adjusted until the laser from the ellipsometer was maximallyreflected by the water surface. The measurement was started $~$ 10 min after the preparation of SC3 solution. The sample wasleft at the same position without disturbance and the data werecollected at given times. The data were then analyzed usingthe software, AnalysR.

Thioflavin T fluorescence of SC3 at a hydrophobic-hydrophilic interface
A thioflavin T (ThT) stock solution (300 µM) was diluted100-fold at fixed time intervals in mixtures of oil and waterto which hydrophobin was added. ThT fluorescence was measuredusing a SPF-500C spectrofluorometer (SLM Aminco, Foster City,CA). The excitation wavelength was 450 ± 4 nm and emissionwas measured at 500 ± 4 nm. Data for each sample werecorrected for the signal before the addition of ThT.

Permeability of the SC3 membrane formed at an air-water interface
For the measurement of water permeability from the hydrophilicside to the hydrophobic side of the membrane, a cuvette wasfilled with 2 ml buffer (50 mM phosphate, pH 7.0) or 2 ml offreshly prepared soluble-state SC3 (10 or 100 µg/ml) inthe same buffer. The samples were incubated at 37°C andwere weighed at various time points. The water evaporated fromthe sample was then calculated by subtracting the actual weightfrom the original weight.

For the measurement of permeability from the hydrophobic sideto the hydrophilic side, the same SC3 and control (no SC3) samplesas mentioned above were placed in an open dessicater. Afterovernight incubation, the bottom of the dessicater was filledwith deuterium oxide (D₂O) and the dessicater was closed immediately.One SC3 and one control sample were taken out at each time pointfrom the dessicater and the content of D₂O in each sample wasdetermined by NMR using a Varian Unity INOVA 600 NMR spectrometer.

Permeability of the SC3 membrane formed at a paraffin oil/buffer interface
Pyrene (molecular mass 202.26 Da), neutral Texas Red dextran(molecular mass 3,000 Da), and neutral rhodamine B dextran (molecularmass 10,000 Da) were used to study the permeability of the SC3membrane. Pyrene was purchased from Fluka (St. Louis, MO), theother compounds from Molecular Probes (Eugene, OR). Pyrene wasdissolved in paraffin oil or buffer (50 mM sodium phosphate,pH 7.0) to a saturated concentration. All of the dextrans weredissolved in paraffin oil to saturated concentrations or dissolvedin buffer to a final concentration of $~$ 100 µg/ml. Samplepreparation and measurements were done in a 1 x 1-cm (4-ml)quartz cuvette with a stirring bar at the bottom. The excitationand emission wavelength of pyrene were 347 and 395 nm, respectively.Those of Texas Red-labeled dextran and rhodamine B-labeled dextranwere 582 and 610 nm and 570 and 603 nm, respectively. The changeof fluorescence intensity in the buffer phase was followed for2.5 h with a SPF-500C spectrofluorometer (SLM Aminco). For this,the cuvette was placed in the spectrofluorometer in such a waythat the light only passed through the buffer phase. The slitwidth for excitation and emission was 4 nm. Experiments werecarried out at room temperature, except for those with dextran10,000, which were done at 50°C to accelerate transfer betweenthe phases.

Transfer from buffer to paraffin oil
A cuvette was filled with 2 ml of a solution of soluble-stateSC3 supplemented with one of the fluorescent markers. For pyrene,a saturated concentration was used, and for the dextrans, thefinal concentration was $~$ 100 µg/ml. Paraffin oil (1 ml)saturated with the same fluorescent marker was then carefullylayered on top of the SC3 solution. The hydrophobin was allowedto assemble at the oil-water interface at room temperature overnight.The cuvette was then placed in the spectrofluorometer in sucha way that light only passed through the aqueous phase. Thetransfer experiment was started by replacing 0.5 ml of marker-saturatedparaffin oil top layer with 1.5 ml of the oil lacking the marker.Measurements were immediately started under conditions of slowstirring. The control experiment was done in the same way butin the absence of SC3.

Transfer from paraffin oil to buffer
A cuvette was filled with 2 ml of a solution of soluble-stateSC3 on top of which 1 ml of paraffin oil was layered. The cuvettewas left at room temperature overnight to allow SC3 to fullyassemble at the oil-water interface. The cuvette was then placedin the spectrofluorometer. The transfer experiment was startedby carefully adding 1 ml of paraffin oil saturated with a fluorescentmarker on top of the original paraffin oil layer. The stirring-barwas then immediately set to slow rotation. The control experimentwas done in the same way but in the absence of SC3.

Fluorescence and confocal microscopy
For fluorescence microscopy of SC3-coated oil droplets, a 20-µlsample was put on a glass slide and covered with a coverslip.The sample was examined using an Olympus Provis AX70 microscope.Pictures were taken with a 3.3 MegaPixel-camera Color View IIand analyzed with AnalySIS docu software by Soft Imaging System(Münster, Germany).

For confocal laser scanning microscopy experiments, pyrene-saturatedparaffin oil and 50 mM sodium phosphate, pH 7.0 (2% v/v) weresonicated for 2 min on ice. Triton X-100 (10% v/v) or an SC3solution (1 mg/ml) was added to the emulsion to a final concentrationof 0.01% and 100 µg/ml, respectively, immediately aftersonication. The emulsions were incubated overnight at room temperaturein the dark and subsequently washed or not washed. Washing wasdone in the same way as mentioned above. Samples of 20 µlwere mounted on glass slides and analyzed by confocal microscopy(TCS Leica SP2 confocal laser scanning microscope, Welzlar,Germany). Two to four images were taken for each sample, andthe fluorescence intensity of 10–20 droplets (middle planeof the vesicles) of each image was quantified by averaging thesignals using Leica Confocal Software, version 2.5 (Leica Microsystems,Heidelberg, Germany).

RESULTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

Spontaneous SC3 membrane formation at the paraffin oil/buffer interface
Emulsions of butanol, hexane, hexadecane, olive oil, or paraffinoil were mixed with soluble-state SC3 to a final concentrationof 100 µg/ml. The paraffin oil emulsion showed the higheststability as deduced from the turbidity of the aqueous phaseand, consequently, was used for the remainder of the study.Dansyl-SC3 (fluorescence resonance energy transfer (FRET) donor)also stabilized the paraffin oil emulsion. When a sample wastaken 30 min after adding the labeled SC3 to the paraffin oilemulsion, membranes coating the paraffin oil droplets showeda green fluorescence that was somewhat enhanced after overnightincubation (Fig. 1, A and B). When a mixture of dansyl-SC3 anddabcyl-SC3 (FRET acceptor) were used together to stabilize theparaffin oil emulsion, the fluorescence of dansyl-SC3 was quenchedat the oil-water interface (Fig. 1, C and D), indicating thatthe membrane is composed of spatially proximate SC3 molecules.A similar quenching was observed if oil droplets were firstcoated overnight with dansyl-SC3, then washed to remove excesslabeled SC3 and exposed to dabcyl-SC3. Quenching to 50% of theoriginal fluorescence occurred within 10 min (Fig. 2 A). Washingof the quenched sample or addition of an excess amount of unlabeledSC3 did not lead to recovery of dansyl fluorescence at all (datanot shown), indicating that once incorporated, SC3 remains stronglyassociated in the membrane. In another experiment (Fig. 2 B),the droplets were coated overnight with native SC3 and the resultingemulsions were washed (dots) or not washed (squares). Dansyl-SC3was then added to the samples and its incorporation into thecoating around the oil droplet was followed as a loss of dansyl-SC3from the supernatant after removing the oil droplets by filtration(see Materials and Methods). The decrease in fluorescence (Fig.2 B) suggests that SC3 continues to incorporate into the assembledmembrane over a period of hours. Conversely, when dansyl-SC3was used to coat the droplets first, followed by the additionof SC3, no dansyl-SC3 could be competed out of the membraneinto the solution, indicating that the incorporation of SC3into the assembled membrane is a one-way process (data not shown).If oil droplets were not present (triangles) the fluorescencewas constant, confirming that the fluorescence decrease wasdue to incorporation of labeled protein into the oil dropletmembrane rather than removal of aggregated and precipitatedprotein by filtration.

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FIGURE 1 Fluorescence of SC3-coated paraffin oil droplets in buffer. Dansyl-SC3-coated oil droplets shown by light (A) and fluorescence microscopy (B) and dansyl-SC3 (donor)/dabcyl-SC3 (acceptor)-coated oil droplets shown by light (C) and fluorescence microscopy (D). Bar indicates 10 µm.

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FIGURE 2 Incorporation of SC3 into the membrane assembled at an oil-water interface. (A) Overnight-incubated dansyl-SC3-coated oil droplets were washed (solid line) and then supplemented with dabcyl-SC3 to the same concentration as for the dansyl-SC3 that was originally present. Dansyl fluorescence was recorded after 10 min (dotted line). (B) Overnight-incubated unlabeled-SC3-coated oil droplets were washed (circles) and not washed (squares). Unlabeled-soluble-state SC3 alone served as a control (triangles). At T = 0, dansyl-SC3 was added to the same concentration as the original unlabeled SC3. Aliquots of 1 ml were taken at each time point from each sample, filtered through a 0.2-µm membrane, and the dansyl fluorescence in the filtrate was measured.

The amyloid-specific fluorescent dye ThT has been shown to interactwith self-assembled SC3 in the ß-sheet II state (Wöstenand de Vocht, 2000

; Butko et al., 2001

). Fig. 3 shows that soluble-stateSC3 in buffer hardly interacts with ThT. Vortexing, however,results in conversion to the ß-sheet assembled stateand results in increased ThT fluorescence, as has already beenreported by Wösten and de Vocht (2000)

. In the case ofSC3 and a paraffin oil emulsion, the ThT fluorescence increasedtwofold 30 min after adding soluble-state SC3 and from 10–15-foldafter overnight incubation. This is $~$ 40% of the maximum ThT fluorescenceobtained by vortexing the sample. When ThT was added to theovernight-incubated sample that had been washed with bufferto remove free SC3, the fluorescence reached the same levelas the open columns but, after vortexing, increased only slightly(data not shown). Therefore, the additional increase in ThTfluorescence in the paraffin oil emulsions in Fig. 3 upon vortexingcan be attributed to SC3 association on air bubbles just asin the case of the buffer/SC3 sample. These data show that SC3spontaneously self-assembles at the oil-water interface intothe stacked ß-sheet state.

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FIGURE 3 ThT fluorescence study of interfacial assembly of SC3. Amyloid-like ß-sheet-state formation of SC3 at the air-water and oil-water interfaces as determined by the increase in ThT fluorescence. Open and shaded columns, respectively, represent samples before and after vortexing for 5 min. Error bars indicate the standard deviation of the results of three independent experiments.

Permeability of the SC3 membrane at the paraffin oil-buffer interface
Transfer from the hydrophilic to hydrophobic side
To measure the permeability of the SC3 membrane from the hydrophilicside, hydrophobin was allowed to self-assemble at a paraffinoil-water interface in a cuvette as stated in Materials andMethods. A downwardly curved interface was formed immediatelyafter adding the paraffin oil on top of the SC3 solution, whereaswithout SC3 it formed a flat surface. The tight adhesion ofthe edge of the SC3 membrane to the cuvette wall might havecontributed to such an unusual phenomenon. The transfer of pyrene(202 mol wt) from water to oil was monitored by following thefluorescence decrease in the buffer phase (see Materials andMethods for details). But first, to exclude that SC3 changesthe fluorescence properties of pyrene in the buffer phase, thefluorescence emission spectrum was determined in the absenceand presence of the hydrophobin. Pyrene excited at 345 nm showedan emission spectrum composed of two bands, a monomer band withpeaks near 390 nm and an excimer band with a broad peak near460 nm. The excimer/monomer ratio, which can be calculated fromthe fluorescence intensities at 460 and 390 nm, has been usedby others to report the environmental hydrophobicity once pyreneaccesses the interior of micelles, membranes, or proteins (Senand Chakrabarti, 1990

; Bhattacharyya et al., 2002

). If pyrenebound to a hydrophobic environment in SC3 assemblies or formedSC3-coated micelles, a significant change in fluorescence intensitiesat 390 and 460 nm would have been expected. As shown in Fig.4 A, the pyrene excimer/monomer ratio increased only slightlyin time in the presence of SC3, indicating that a large amountof pyrene monomers (at least 90%) still remained in solutioneven after overnight incubation. Therefore, changes in pyrenefluorescence intensity, when they occur in the experiments describedhere, must be due to transfer across the hydrophobin membraneand not to binding of the marker to the protein.

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FIGURE 4 Pyrene transfers through the SC3 membrane formed at the buffer-paraffin oil interface. (A) Pyrene fluorescence is only slightly changed in the presence of SC3. Soluble-state SC3 was mixed with a saturated pyrene solution in 50 mM sodium phosphate, pH 7.0. The final concentration of SC3 was 100 µg/ml. The fluorescence spectrum of pyrene was taken after a 30-min (dashed line) and a 16-h (solid line) incubation. The same pyrene solution in the absence of SC3 served as a control (dotted line). (B) Pyrene transfer from buffer to paraffin oil after overnight assembly of SC3 at the oil-water interface starting from a concentration of the hydrophobin in the buffer phase of 3 µg/ml (dash-dotted line), 10 µg/ml (dashed line), and 100 µg/ml (solid line). A solution without SC3 served as a control (dotted line). (C) Pyrene transfer from paraffin oil to buffer in the absence (dotted line) or presence (solid line) of an SC3 membrane formed during overnight incubation from a solution containing 100 µg/ml of protein.

Pyrene rapidly transferred from buffer to paraffin oil in theabsence of SC3 or after overnight assembly of SC3 from a 3-µg/mlsolution at the oil-water interface (Fig. 4 B). However, therate of transfer was reduced when SC3 had assembled overnightfrom a 10-µg/ml SC3 solution, and it was blocked completelyby overnight assembly from a 100-µg/ml SC3 solution (Fig.4 B). By contrast, the transfer of pyrene was reduced by only20% when SC3 was replaced by bovine serum albumin or lysozyme(100 µg/ml) (data not shown). Similar results were obtainedwith dextran 3000 and dextran 10,000. Dextran 3000 equilibratedeasily between buffer and paraffin oil in the absence of anSC3 membrane. Dextran 10,000 diffused more slowly, and therefore,a higher temperature (50°C) was used to accelerate transferof this marker. After overnight assembly of SC3 (100 µg/ml),transfer of dextran 3,000 and 10,000 from buffer to oil wascompletely blocked (Fig. 5, A and C). From these data we canconclude that an SC3 membrane completely blocks the movementof molecules >200 Da from the hydrophilic to the hydrophobicphase.

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FIGURE 5 Transfer of dextran 3000 (A and B) and dextran 10,000 (C and D) in the absence (dotted lines) or presence (solid lines) of an SC3 membrane formed overnight at the paraffin oil/buffer interface from a protein solution of 100 µg/ml. Transfer was measured from buffer to paraffin oil (A and C) and from paraffin oil to buffer (B and D).

Transfer from the hydrophobic to the hydrophilic side
In contrast to transfer from buffer to the oil, pyrene apparentlystill transferred at room temperature from paraffin oil to bufferafter overnight assembly of 100 µg/ml SC3 (Fig. 4 C),although the transfer rate was reduced compared to that observedacross an interface without hydrophobin. Like pyrene, dextran3000 and dextran 10,000 passed through the SC3 membrane (Fig.5, B and D). Cytochrome c, a globular protein with a molecularweight of $~$ 12,000 Da, behaved similarly to dextran 10,000 (datanot shown).

Unexpectedly, when the experiment shown in Fig. 4 C was repeatedusing a low concentration of pyrene in oil (e.g., one-tenthof the saturated concentration), the concentration of pyrenethat accumulated in the aqueous phase reached a higher levelthan that in the control sample in the absence of SC3. An evenfurther accumulation of pyrene in the buffer phase was observedif, after the system reached equilibrium, extra pyrene/oil wasadded to the sample (Fig. 6). This result suggests that anotherprocess apart from diffusion must be involved in transferringpyrene across the membrane. A closer examination of the physicalstate of the fluorescent markers in the aqueous phase providedthe answer.

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FIGURE 6 Lowering the pyrene concentration used in oil resulted in more partition of pyrene in the aqueous phase in a buffer/SC3/oil system ( ${blacksquare}$ ) than in a buffer/oil control system ( ${diamond}$ ). Pyrene concentration in oil was $~$ 10 times as low as that in a saturated solution, and only 100 µl of such pyrene/oil solution was added on the top of the oil phase. After the pyrene transfer reached equilibrium, 50 µl of extra pyrene/oil was added at the time indicated by the arrow.

When soluble-state SC3 was present in the aqueous phase, thefluorescent markers, pyrene and the dextrans that had transferredfrom the paraffin oil phase, were found in small oil droplets.No such oil droplets were observed in the sample without hydrophobinor in samples containing 0.01% (v/v) Triton X-100 instead ofSC3 (Fig. 7). Moreover, these oil droplets were absent whenthe transfer experiment was done in the absence of stirring.This correlated with the absence of pyrene in the aqueous phase.Apparently, under stirring conditions, SC3 in the aqueous phaseemulsifies oil droplets from the paraffin oil phase. Pyrenetransfer from oil to water was also monitored in an emulsionof paraffin oil and buffer stabilized either by Triton X-100(control) or SC3. The change of pyrene fluorescence in the oildroplets was monitored in time by confocal laser scanning microscopy.In both cases, pyrene fluorescence slightly decreased in thefirst 2 days and then remained constant for the next 7 days(Fig. 8). However, as Fig. 9 shows, Triton X-100 coated dropletsrapidly destabilized when excess surfactant was washed away.Both the number and the size of the droplets decreased in timeand the pyrene fluorescence in the remaining oil droplets decreasedsignificantly, suggesting that pyrene transferred out of theoil droplets in this case. In contrast, when excess of SC3 waswashed away from the buffer phase, the oil droplets remainedstable and no pyrene fluorescence was lost. Clearly, SC3 canstabilize the oil droplets by a mechanism different from thedetergent molecules. Further supplementing the solution containingwashed SC3-coated oil droplets with freshly prepared soluble-stateSC3 (to 100 µg/ml) seemed to restore the pyrene transferto some extent. If the washed SC3-coated oil droplets were supplementedwith Triton X-100 (to 0.01% v/v), an even larger amount of pyrenewas released from oil after long incubation, whereas the sizeand the number of the droplets did not change significantly(Fig. 9).

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FIGURE 7 Large oil droplets were observed in the aqueous phase in the cuvette containing buffer/pyrene/SC3 (100 µg/ml)/paraffin oil (A and B). After the membrane was formed overnight at the interface, the solution was slowly stirred for 2.5 h and an aliquot of the aqueous solution was taken for microscopic measurement. No droplets were observed in a control sample using 0.01% (v/v) Triton X-100 instead of SC3 (C and D). Samples were visualized by light microscopy (A and C) and fluorescence microscopy (B and D). Scale bar, 10 µm.

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FIGURE 8 Time-dependent change of pyrene fluorescence in oil droplets stabilized with 0.01% (v/v) Triton X-100 and 100 µg/ml SC3, as detected by confocal laser scanning microscopy. The emulsions were left at room temperature for 1 day (black columns), 2 days (gray columns), and 9 days (white columns). Aliquots of the samples were taken and subjected to the microscopic detection. Error bars indicate the standard deviation of the fluorescence values for various oil droplets in each sample.

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FIGURE 9 Time-dependent change of pyrene fluorescence in oil droplets as detected by confocal laser scanning microscopy. Oil droplets stabilized with 0.01% (v/v) Triton X-100 or 100 µg/ml SC3 were washed with buffer (TX-w and SC3-w, respectively), followed by supplementation with freshly prepared soluble-state SC3 to 100 µg/ml (SC3-w-SC3) and Triton X-100 to 0.01% (v/v) (SC3-w-TX). Samples were incubated at room temperature for 2.5 h (black columns), 6 h (gray columns), and 18 h (white columns). The asterisk indicates that the fluorescence in the sample TX-100w after 18 h incubation was not determined because the oil droplets were too small to be measured. Error bars indicate the standard deviation of the fluorescence values for various oil droplets in each sample.

Permeability of SC3 membrane to water at an air-water interface
Ellipsometry measurements showed that SC3 forms a monolayermembrane at an air-water interface after several hours of incubation.When protein concentration was high (100 µg/ml), the membranethickness after 10 min was determined to be 2.3 nm, and it slowlyincreased to the maximum of $~$ 3 nm after 5 h incubation. Thisthickness agrees well with the expected diameter of an SC3 monomer,assuming that the molecule is spherical in shape. When a lowerprotein concentration (10 µg/ml) was used, the membranethickness reached $~$ 1.7 nm in 5 h, and it only grew to 2.1 nmafter overnight incubation. This suggests that the membraneformed at low protein concentration is less compact; eithera larger space exists between molecules or the orientation ofthe protein in the membrane is different.

The water permeability of the membrane formed at the air-waterinterface by overnight incubation of a 100-µg/ml SC3 solutionwas monitored in both directions. Water transfer over the membranefrom the hydrophilic to hydrophobic side was determined by simplyfollowing the evaporation of water from a cuvette containingSC3 which had been allowed to form a membrane at the air-waterinterface. Water transfer from the hydrophobic side was monitoredas the exchange of deuterium from D₂O outside a cuvette to H₂Ocovered by an SC3 membrane in a cuvette. (see Materials andMethods for details). The time used to monitor the process wasmuch longer than that needed for an SC3 membrane to mature (5h). For both determinations, over a period of more than 80 h,the sample containing SC3 at 100 µg/ml or 10 µg/mldid not show significant differences from the control samplein the absence of SC3 (Tables 1 and 2), indicating that theSC3 membrane is permeable for water molecules from both thehydrophilic and the hydrophobic side.

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TABLE 1 Water permeability of the hydrophilic side of an SC3 membrane formed at an air-water interface, as detected by the evaporation of water

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TABLE 2 Water permeability of the hydrophobic side of SC3 membrane formed at an air-water interface as detected by the exchange of deuterium oxide

	DISCUSSION

TOP ABSTRACT INTRODUCTION MATERIALS AND METHODS RESULTS DISCUSSION ACKNOWLEDGEMENTS REFERENCES

This study shows that SC3 spontaneously assembles into the ß-sheetII state at the oil-water interface. When a mixture of dansyl-SC3(donor) and dabcyl-SC3 (acceptor) was used to coat the oil droplets,the fluorescence of dansyl-labeled SC3 was efficiently quenched,confirming that donor and acceptor were in close proximity,as is typical for ß-sheet-state hydrophobin (Wanget al., 2002

). If one starts with a membrane composed only ofdansyl-SC3, subsequent addition of dabcyl-SC3 quickly quenchesthe fluorescence of dansyl-SC3, which has assembled at the oil-waterinterface, indicating that SC3 can incorporate into an alreadyformed membrane. The incorporation is best characterized asa one-way process because no evidence can be found for soluble-stateSC3 reappearing in solution once it has been in the membrane.The insertion process has a fast and a slow kinetic regime.The fast regime only appears if the oil droplets are washedand centrifuged several times before adding fresh soluble-stateSC3, suggesting that the handling procedure itself is creatingeasily accessible insertion sites (Fig. 10 A). The slow regimeis observed under all circumstances. It reflects the processin which, for further insertion to occur, room must be createdby budding off of SC3-coated oil droplets (Fig. 10, B and C).The slow regime is also reported by ThT fluorescence, whichincreased significantly in time when SC3 was added to a paraffinoil emulsion. Apparently, as long as there is soluble-stateSC3 in solution, the incorporation process will continue, andthe ß-sheet II structure formation in the assembledmembrane and vesicles will continue. The increased fluorescenceof ThT is in good agreement with a previous study (Wöstenet al., 1994a

) showing rodlets of SC3 at the oil-water interfaceafter freeze-fracture. However, at that time it could not beexcluded that these rodlets were first formed at the air-waterinterface (due to sonication) and then associated with the oildroplets.

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FIGURE 10 A schematic model of SC3 membrane formed at an oil-water interface. SC3 undergoes a dynamic process of incorporation and association (assembly) into the membrane. As a result, certain parts of the membrane are pressed and protrude, forming vesicles that contain oil or oil solutes. Hydrophobic molecules >200 Da in the oil phase can therefore pass through the membrane and enter the aqueous phase via SC3-assisted emulsification. The whole process will stop when soluble-state SC3 is not present in the aqueous phase. Water molecules, however, can freely permeate the membrane from both sides.

The increased transfer of pyrene from the paraffin oil to thebuffer phase beyond the equilibrium value is confirmation ofa dynamic SC3-coated oil droplet formation process. Microscopyrevealed that the fluorescent molecules were contained in oildroplets that were stabilized by a hydrophobin membrane. Apparently,SC3 in the aqueous phase in combination with slow stirring neededto accelerate the transfer of fluorescent molecules emulsifiesoil from the layer on top of the SC3 membrane. This is consistentwith a continuous incorporation of SC3 into the membrane, whichincreases the surface area and, therefore, causes parts of themembrane to protrude into the aqueous phase and further formSC3-coated oil droplets. Confocal microscopy strongly supportsthis conclusion. When soluble-state SC3 was washed away fromthe aqueous phase, pyrene transfer from the oil to the aqueoussolution was eliminated. The system remained stable for manydays, until freshly prepared soluble-state SC3 was added. Thepresence of detergent in the aqueous phase in this case evenfacilitated the transfer of pyrene, while the membrane remainedintact.

The data presented here indicate that SC3 in the ß-sheetII state forms a membrane permeable to water vapor but excludingmolecules with a molecular weight >200 Da. Formation of thismembrane is protein concentration-dependent. It is completelyformed at 100 µg/ml, but only partially formed at 10 µg/mland not at all at 3 µg/ml. At the lowest concentration,diffusion of marker molecules is not hampered at all, indicatingthe absence of a membrane. This may be due to the fact thatassembly of SC3 depends on a critical concentration of 3.7 µg/ml(de Vocht, 2001). A concentration of SC3 in the aqueous phaseof 10 µg/ml should be sufficient for self-assembly. However,at this concentration rodlets could not be observed at the air-waterinterface by electron microscopy even though a discrete SC3membrane was formed (de Vocht et al., 2002). This suggests thatat such a low concentration SC3 is arrested in the ß-sheetI state. The secondary structure of this state cannot be discriminatedfrom that of the ß-sheet II state but the ultrastructureis clearly different, i.e., a featureless film versus a rodlet-decoratedfilm (de Vocht et al., 2002). This difference in organizationapparently affects the permeability of the protein film. Dextran3000 seemed to transfer faster from paraffin to buffer thandextran 10,000 in the presence of SC3 membrane (Fig. 5, B andD), but this should not occur if the dextran transfer is independentof membrane permeability, i.e., because of the size exclusionlimit. The experiment was repeated several times, and it wasfound that this trend is not reproducible. In some cases, thetwo dextrans transferred at a similar rate (data not shown).A likely reason for this discrepancy is that the stirring speedused was somehow different from measurement to measurement,leading to a difference in the formation of SC3-coated oil droplets.

The model of SC3 behavior at an oil-water interface is presentedin Fig. 10. SC3 forms a membrane that is permeable to waterbut excludes molecules >200 Da. During formation there isfirst movement of soluble-state SC3 to the oil-water interface,then self-association resulting in the ß-sheet IIstate. The driving force for continued insertion once the membraneis formed is the mechanical stirring that results in buddingoff of SC3-covered vesicles. The oil, as well as the solutesin the oil, will therefore be emulsified by SC3. In the absenceof free SC3, the assembled membrane is totally inert withoutany mass transfer or emulsification ability.

Biological implications
A semipermeable hydrophobin membrane has biological implications.Such membranes covering fungal structures in contact with air(e.g., aerial hyphae, spores, air channels within fruiting bodies)would allow evaporation of water and not protect against desiccation.This is in agreement with preliminary results showing that therate of dessication of colonies did not increase after deletingthe SC3 gene (H. A. B. Wösten, unpublished results). Onthe other hand, a semipermeable membrane would allow rehydrationfrom a humid atmosphere after a dry period, thus enabling theemergent structure to start up metabolism. Semipermeable hydrophobinmembranes would also not impede exchange of metabolic gases.Exchange of such gases is essential for growth of aerial hyphae,fruiting bodies, and lichens. In fact, hydrophobin-coated airchannels traverse fruiting bodies and lichens to improve gasexchange (see Wösten, 2001).

A semipermeable hydrophobin membrane would prevent diffusionof small molecules in or out of the cell wall. Such a membranecould be instrumental for infectious propagules (e.g., spores)of pathogenic fungi to evade plant and animal defenses. Forinstance, it would prevent diffusion of elicitors from the cellwall (Wösten and Wessels, 1997). Moreover, the hydrophobinmembrane could shield ligands that are recognized by the immunesystem of animals. However, swelling of a spore resulting fromuptake of water disrupts the hydrophobin membrane. This impliesthat the hydrophobin membrane would only protect the spore duringinitial stages of contact. Interestingly, the rodlet layer onconidiospores of Aspergillus fumigatus has indeed been shownto function in early, and not in later, stages of infection,probably by protecting the spores against macrophages and neutrophils(Shibuya et al., 1999; Paris et al., 2003). Disruption of thehydrophobin layer, as occurs upon swelling of spores, couldalso be beneficial; it would allow uptake of low-molecular-weightnutrients.

A hydrophobin membrane with such unique mass transfer propertiesmight also be intriguing for nanotechnology, for instance, ascoatings for drug delivery carriers. The hydrophobin coatingwould not only miniaturize the oil droplets or the particlesof water-insoluble compounds and thus make them soluble in solution,but would also provide a physically stable proteinaceous layerthat would allow washing, separation from other components,and probably lyophilization of these particles. In addition,a hydrophobin might improve the bioavailability of drugs (Scholtmeijeret al., 2002).

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

We thank Professor Jos Wessels for discussions about the biologicalconsequences of a semipermeable membrane. We also thank K. Dijkstraand R. M. Scheek for their help with the deuterium diffusionNMR measurement.

Submitted on December 14, 2004; accepted for publication February 22, 2005.

REFERENCES

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS
DISCUSSION
ACKNOWLEDGEMENTS
REFERENCES

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