Functional Incorporation of Integrins into Solid Supported Membranes on Ultrathin Films of Cellulose: Impact on Adhesion

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Functional Incorporation of Integrins into Solid Supported Membranes on Ultrathin Films of Cellulose: Impact on Adhesion

Stefanie Goennenwein^*, Motomu Tanaka^*, Bin Hu, Luis Moroder and Erich Sackmann^*

^* Technische Universität München, Garching, Germany; Lerner Research Institute, The Cleveland Clinic Foundation, Cleveland, Ohio 44195; USA; and Max Planck Institut für Biochemie, Martinsried, Germany

Correspondence: Address reprint requests to Stefanie Goennenwein, Technische Universität München, James-Franck-Str. 1, D-85748 Garching, Germany. Tel.: 49-8928912470; Fax: 49-8928912469; E-mail: smarx{at}ph.tum.de.

ABSTRACT

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Biomimetic models of cell surfaces were designed to study thephysical basis of cell adhesion. Vesicles bearing reconstitutedblood platelet integrin receptors ${alpha}$ _IIbß₃ were spreadon ultrathin films of cellulose, forming continuous supportedmembranes. One fraction of the integrin receptors, which werefacing their extracellular domain toward the aqueous phase,were mobile, exhibiting a diffusion constant of 0.6 µm²s^-1. The functionality of receptors on bare glass and on cellulosecushions was compared by measuring adhesion strength to giantvesicles. The vesicles contained lipid-coupled cyclic hexapeptidesthat are specifically recognized by integrin ${alpha}$ _IIbß₃.To mimic the steric repulsion forces of the cell glycocalix,lipids with polyethylene glycol headgroups were incorporatedinto the vesicles. The free adhesion energy per unit area ${Delta}$ g_adwas determined by micro-interferometric analysis of the vesicle'scontour near the membrane surface in terms of the equilibriumof the elastic forces. By accounting for the reduction of theadhesion strength by the repellers and from measuring the densityof receptors one could estimate the specific receptor ligandbinding energy. We estimate the receptor-ligand binding energyto be 10 k_BT under bioanalogue conditions.

INTRODUCTION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Solid supported lipid membranes with functional proteins havebeen intensively and widely investigated in the last decadesas a general model of cell membranes (Sackmann, 1996). Theyhave been used especially for the study of cell adhesion (Chanet al., 1991, Dustin, 1997, Bruinsma et al., 2000) or proteininteractions (Brian and McConnell, 1984) as well as for thedesign of biosensors on electrical devices (Hillebrandt et al.,1999). One advantage of planar membranes is the possibilityto study structural and dynamical properties by numerous surfacesensitive techniques (Watts et al., 1986, Salafsky et al., 1996,Wong et al., 1999). A commonly used method to reconstitute proteinsinto supported bilayers is to incorporate them into lipid vesiclesand spread these proteoliposomes onto solid surfaces (Kalb etal., 1992). Membrane-spanning proteins such as ion channelsor bacteriorhodopsins (Puu et al., 2000) can be reconstitutedinto supported membranes which are in contact with solid surfaceswithout a considerable reduction of their function. However,for cell-adhesion studies the situation is more complicated,since the functional headgroups of the receptors are very largeand can stick out of the membrane up to several 10 nm (Sackmannand Bruinsma, 2002). Since the distance between membranes andsolid substrates is typically smaller than 1 nm, the large headgroupstouch the solid substrates, which often results in the denaturationof the proteins. One strategy to overcome this problem is toseparate the bilayer from the solid support either by incorporationof lipopolymers into the membrane (Heyse et al., 1995) or bycoating the surface with soft, ultrathin biocompatible polymer"cushions" (Wegner, 1993). As demonstrated previously, purelipid bilayers can be spread homogeneously on cellulose cushions(Sigl et al., 1997). Recently, even the homogeneous and orientation-selectiveimmobilization of human erythrocyte membranes on these cellulosefilms was accomplished (Tanaka et al., 2001).

Integrin ${alpha}$ _IIbß₃ receptors are cell-adhesion molecules,which are expressed on human blood platelets and play a criticalrole in thrombosis and hemostasis (Hynes, 1992). The integrin(depicted schematically in Fig. 1 b, molecular mass $~$ 240 kDa)has a small intracellular domain and a large extracellular domain(8 x 12 nm² lateral dimensions), which bears a specific bindingsite for fibrinogen, fibronectin, von Willebrand's factor andvitronectin. Integrin ${alpha}$ _IIbß₃ binds specifically toArg-Gly-Asp (RGD) sequences of these ligands. The receptorswere reconstituted into lipid vesicles. These proteoliposomeswere spread onto solid surfaces covered by multilayers of rodlikecellulose molecules (thickness ). The supported membranes exhibited a homogeneous coating over large areas (18x 18 mm²), enabling partially long-range lateral diffusion ofreconstituted receptors pointing their extracellular domainsinto the aqueous phase. In contrast, the receptors are essentiallyimmobile if the proteoliposomes were spread directly onto bareglass slides and a complete fusion of the membrane was impeded.

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FIGURE 1 (a) Cryo-electron micrograph of reconstituted integrin ${alpha}$ _IIbß₃ receptors in DMPC/DMPG vesicles. The black protrusions in the vesicles membranes correspond to integrins. (b) Schematic illustration of the lipid vesicle containing integrin receptors, where the large extracellular parts are exposed on both sides of the membrane. The picture is drawn to scale.

The functionality of the integrin receptors was tested quantitativelyby measuring the free adhesion energy ${Delta}$ g_ad (also called spreadingpressure) to giant vesicles. These vesicles bear lipid-coupledcyclic hexapeptides which contain the RGD sequence. Using themicro-interferometric technique (Albertsdörfer et al.,1997

), the free adhesion energy can be determined from the vesicle'scontour close to the substrate. For vesicles adhering to bilayerssupported on cellulose films, the measured spreading pressure ${Delta}$ g_ad agreed well with the value calculated from the density andthe estimated binding constant of the receptors in the supportedmembrane.

Repeller molecules (lipids with polyethylene glycol headgroups)were incorporated into the giant vesicles to mimic the repulsiveforces exerted by the glycocalix of the cell plasma membranes.These repeller molecules have been postulated to decrease thefree adhesion energy ${Delta}$ g_ad due to the osmotic pressure difference ${Delta}$ ${pi}$ _R between the adhering and the nonadhering parts of the membrane(Bruinsma et al., 2000). Indeed, an increase in the repellerconcentration led to a decrease in the adhesion energy. By extrapolatingthe measured spreading pressure ${Delta}$ g_ad to zero repeller concentrationwe could estimate the specific adhesion energy W_ad. Surprisingly,the formation of tight adhesion domains was not accompaniedby a pronounced lateral repeller segregation. We found onlya small decrease of 3% for the repeller concentration in thetight adhesion domain. This result can be explained by the largerintegrin headgroup ( $~$ 12 nm) in comparison to the Flory radiusof the repeller headgroup. The extrapolated specific adhesionenergy W_ad and the measured receptor density enabled us to determinesingle receptor-ligand interaction energies under biocompatibleconditions.

The major motivation for the present work was to measure forcesbetween receptors and ligands in a biological environment. Tothis end a model system was established which allows for forcemeasurements between receptor ligand pairs coupled to soft surfaces.Although the presented model system does not represent the truephysiological situation where the RGD-bearing ligands are anintegral part of the tissue surface (e.g. vitronectin) or formsoluble linkers between cell membranes and tissues as the vonWillebrand factor, it mimics well the physical situations ofmembrane adhesion. As demonstrated earlier such model systemsare helpful to gain physical insights into the control of theadhesion processes, since the contributions of the various forcescan be controlled (Albertsdörfer et al., 1997). In thesupported bilayers the receptors pointing toward the substratedo not interfere with the adhesion process. However, they generatea structure very similar to cell plasma membranes, where thelipid/protein bilayer is spatially separated from the surfaceof the actin cortex. The membranes of giant vesicles are ina fluid state, which allows a rapid diffusion of the lipid coupledRGD ligands and corresponds to that of soluble van Willebrandfactors.

MATERIALS AND METHODS

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ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Cellulose
Glass coverslides were purchased from Merck (Germany) and usedas substrates. They were rinsed by sonication in acetone andmethanol, and immersed into 1:1:5 (v/v) solution of H₂O₂/NH₄OH/H₂Oat 60°C for 30 min. After rinsing extensively with ultrapurewater (Millipore, France), the slides were dried at 70°Cand stored in a vacuum chamber for at least 12 h. The substrateswere immersed into a 5 vol % solution of octadecyltrimethoxysilane(ODTMS, ABCR, Karlsruhe, Germany) in dry toluene, adding 0.5vol % butylamine as a catalyst (Mooney et al., 1996). The sampleswere sonicated for 60 min at a controlled temperature of 13°C,and soaked for another 30 min. To remove physisorbed ODTMS fromthe surface, the samples were then carefully rinsed and sonicatedfor 2 min in toluene.

Trimethylsilyl cellulose (TMSC) was synthesized as previouslyreported (Schaub et al., 1993). The degree of substitution (DS)was estimated by elemental analysis to DS $~$ 2.0. Thin films oftrimethylsilyl cellulose (TMSC) were deposited by Langmuir-Blodgetttechnique, where the lateral pressure was kept constant at 30mN/m and a the subphase temperature was 17°C (Hillebrandtet al., 1999). The transferred films (10 layers, thickness $~$ 10nm) were dried in a vacuum chamber and exposed to a saturatedvapor of concentrated HCl for 15–30 s in order to regenerateoriginal cellulose by cleavage of silyl sidegroups (film thicknessafter regeneration $~$ 5 nm).

Integrin ${alpha}$ _IIbß₃
Integrin ${alpha}$ _IIbß₃ was extracted by Triton-X 100 (Sigma-Aldrich,Germany) from outdated human blood platelets of the local bloodbank (Fitzgerald et al., 1985). Function of the purified receptorswas checked by enzyme-linked immunosorbent assay (ELISA) tests.For reconstitution into small vesicles Triton-X 100 was removedby Bio-Beads SM2 (Bio-Rad, Germany), as described previously(Müller et al., 1993, Hu et al., 2000). As matrix lipidswe used a 1:1 mixture (by molar fraction) of DMPC and DMPG ((1,2-dimyristoyl-sn-glycero-3-phosphocholineand -phosphatidylglycerol), purchased from Avanti Polar LipidsInc. (Alabaster, AL, USA). The integrin-containing vesicleswere dialyzed to 150 mM NaCl, 20 mM TRIS, 1 mM NaN₃, 1 mM CaCl₂,1 mM MgCl₂ at pH 7.3, called buffer A in the following.

For fluorescence experiments, integrins were labeled with 5-(and-6)-carboxy-tetra-methylrhodaminesuccinimidyl ester (5(6)-TAMRA-SE) purchased from MolecularProbes, Inc. (Eugene, OR, USA), as reported earlier (Hu et al.,2000). The labeling efficiency was measured to be 1:1 with spectroscopy.These labeled proteins were mixed with unlabeled ones, yieldinga final molar fraction of labeled proteins of 0.1.

In order to label the lipid moiety of the vesicle membrane 1-oleoyl-2-[12-[(7-nitro-2-1,3-benzoxadiazol-4-yl)amino]dodecanoyl]-sn-glycero-3- phosphocholine (called NBD-PC in thefollowing) purchased from Molecular Probes was added to purelipids at a concentration of 1–2 mol %.

Synthesis of RGD ligand
The synthesis of cyclic RGD-peptide (c[Arg-Gly-Asp-D-Phe-Lys(NBD)-Gly-])was reported by Gurrath et al., (1992) and the coupling of theRGD sequence to DMPE (1,2-dimyristoyl-sn-glycero-3-phosphoethanolamine)was reported elsewhere (Hu et al., 2000).

The fluorescently labeled RGD peptide was synthesized as follows:6-(N-(7-Nitrobenz-2-oxa-1,3-diazol-4-yl)aminohexanoic acid (NBD)(18 mg; 62 µmol) was coupled to the cyclic peptide c[Arg(Pbf)-Gly-Asp(OtBu)-D-Phe-Lys-Gly-](30 mg; 31 µmol) in 5 ml of freshly destilled DMF by HATU(24 mg; 62 µmol), HOAt (9 mg; 62 µmol) and DIPEA(17 µl; 120 µmol). After 4 h, the solvent was removedand the residue was taken up in ethyl acetate. The insolubleproduct was centrifuged and the solid was treated with 95% aqueousTFA containing 1.5% triethylsilane for 2 h. The crude productwas purified batchwise by reversed phase HPLC on XTerra C18(Waters, MA, USA) with a linear gradient of 5%–60% AcCNin 0.01% TFA in 45 min; yield: 7 mg (22%); HPLC: t_r = 6.2 min(Luna 150 x 4.6 5µ C18, phenomenex); ESI-MS: m/z = 969.4[M+H⁺] M_r = 968.5 calculated for C₄₆H₆₈N₁₀O₁₁S.

Supported planar bilayers
Supported planar bilayers were formed by direct fusion of integrin-loadedvesicles (Müller et al., 1993) onto bare glass slides andonto slides coated with cellulose films, respectively. The substrateformed the bottom of the measuring chamber, which was assembledby pressing a Teflon frame onto the substrate with the helpof a metal frame. This measuring chamber was filled with 200µl of the vesicle suspension and covered by a glass slide.After 2.5 h of incubation, the osmolarity of the solution wasincreased by 25 mOsm with respect to the intravesicular medium.After another hour of incubation, the sample was rinsed intensivelywith buffer A to remove physisorbed vesicles. For adhesion experiments,nonspecific binding was blocked by incubation with a 3 wt %solution of BSA in buffer A for 1 h. Finally, the sample wasrinsed with buffer A to remove nonadsorbed material.

Giant vesicles
Giant vesicles were composed of an equimolar mixture of DMPCand cholesterol, 1 mol % of DMPE with polyethylene glycol headgroups(PEG lipid, molecular mass(PEG) = 2000) and 1 mol % of DMPEwith a cyclic RGD peptide headgroup (RGD lipid, synthesizedas described before), in respect to the DMPC amount were added.All components were purchased from Avanti. Giant vesicles wereprepared by the electro-swelling technique (Dimitrov and Angelova,1988, Albertsdörfer et al., 1997). For this purpose, lipidswere dissolved in chloroform and deposited onto indium-tin-oxideelectrodes. The swelling chamber was filled with 170 mM sucrosesolution and the content was exposed to an AC electric fieldof 10 Hz and 1 A for 2 h. 200 µl of the obtained giantvesicle suspension was injected into the measuring chamber whichcontained buffer B (100 mM NaCl, 10 mM HEPES, 1 mM NaN₃, 1 mMCaCl₂ at pH 7.3 and 205 mOsm). The vesicles settled on the bottomof the measuring chamber due to the higher density of the intravesicularsucrose solution with respect to the outer buffer B ( ${Delta}$ ${rho}$ = 49.5kg/m³). Due to an osmotic pressure difference of 30–40mOsm between the inner and outer medium of the vesicle, thevesicles were deflated. Thereby, excess area is generated, enablingvesicles to adhere to flat surfaces.

Fluorescence microscopy
The homogeneity and the lateral distribution of the labeledlipids and proteins were checked with an inverted microscopeAxiovert 200 (Zeiss, Germany) equipped with a neofluar objective(antiflex, 63x, oil immersion, NA = 1.3). The dyes were excitedwith a high pressure mercury lamp combined with fluorescencefilters that transmit at 540–550 nm for TAMRA and at 450–490nm for NBD. Fluorescence emission was detected above 590 nm(TAMRA) or 515 nm (NBD), respectively, with a cooled 12 bitcamera (Orca-ER, Hamamatsu, Japan). The data collection wascarried out through a real-time imaging software developed atour laboratory.

Reflection interference contrast microscopy
Adhesion of giant vesicles was studied by a micro-interferometrictechnique, called reflection interference contrast microscopy(RICM) (Albertsdörfer et al., 1997). RICM images are formedby interference of light reflected from the interface glassbuffer and the surface of the adhering vesicle, respectively.The contour of the adhering vesicle in the vicinity of the substratecould be reconstructed by an inverse cosine transformation.

Fluorescence recovery after photobleaching
The lateral mobility in the bilayer was measured by fluorescencerecovery after photobleaching (FRAP) (Axelrod et al., 1976).The fluorescent labels were bleached within a circular spotof 9.3 µm diameter by a focused laser pulse of an Ar⁺-Laser(Innova 70, Coherent, Santa Clara, CA, USA). Recovery of thefluorescence signal was monitored by a photomultiplier (RCA31034-04). The lateral diffusion constant D was obtained byanalyzing the fluorescence recovery according to the theoreticalmodel of Soumpasis (1983), which holds for a rectangular intensityprofile of the bleaching light.

RESULTS AND DISCUSSION

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

Determination of integrin and lipid concentrations in vesicles
The reconstitution of integrins into lipid vesicles was confirmedby electron micrographs of cryo-fixed samples. In the exampleof Fig. 1 a, the reconstituted ${alpha}$ _IIbß₃ receptors arevisible as small protrusions extending from both sides of thevesicle membrane. Closer inspection of many samples showed thatthese protrusions have a quite regular length of $~$ 20 nm, whichis in good agreement with other studies (Erb et al., 1997).The receptors are rather evenly distributed over the vesiclesurface. The protein concentration in the vesicles was determinedby UV spectroscopy measurements, following the procedure reportedby Bradford (1976). The lipid concentration was measured byphosphate analysis according to Fiske and SubbaRow (1925). Wefound an integrin concentration of 56 nM and a lipid concentrationof 400 µM, corresponding to an integrin to lipid molarratio of 1:7000. This protein content is rather high, althoughit is a factor of five smaller than the highest concentrationreported, 1:1500 (Müller et al., 1993). The measured lipidto protein molar ratio corresponds to an average protein distanceof 60 nm in the membrane.

Formation of planar membranes with integrins
Fig. 2 shows the fluorescence micrograph of a supported membranewith labeled integrins on a bare glass substrate. The fluorescencedistribution (and thus the protein distribution) is heterogeneousand numerous dark patches are visible, showing that the coverageis incomplete. These heterogeneous patches and defects couldnot be healed out, even after prolonged incubation. This findingis in contrast to the homogeneous membrane reported by (Erbet al., 1997), although the preparation procedures are verysimilar. However, as shown in Fig. 3 and as more clearly demonstratedby lateral diffusion measurements (cf. following section) aperfectly homogeneous and fluid membrane is formed by spreadingof vesicles on a cellulose "cushion."

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FIGURE 2 (a) Fluorescence micrograph of a membrane containing labeled integrins on a bare glass substrate. (b) Side view of the solid supported membrane.

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FIGURE 3 (a) Fluorescence micrograph of an integrin-doped membrane on a cellulose film. (b) Schematic drawing of the polymer cushioned membrane viewed from the side.

Determination of lateral diffusion constants
FRAP experiments were carried out to determine the lateral diffusionconstant D and the mobile fraction of integrin receptors andlipids in the two types of supported membranes. To eliminateeffects of drift of the optical paths, the quality of the focus(in lateral and horizontal plane) was checked after each measurement.For the membrane on bare glass slides, no fluorescence recoverycould be observed during the observation time (cf. gray circlesin Fig. 4 a). The same qualitative result is obtained for amembrane on a quartz substrate (data not shown). In the caseof membranes supported on polymer cushions, however, we obtaina recovery of the fluorescence signal of R = 25 ± 5%(black squares in Fig. 4 a). Analysis of the recovery curveyielded a diffusion constant of D = 0.6 ± 0.2 µm²s^-1. To understand the origin of the low recovery, we performedtwo subsequent bleaching experiments at the same position ofthe sample. The recovery curve of the second bleaching experimentis shown in Fig. 4 b. A comparison of the black curves in Fig.4 a and 4 b shows that the fraction of fluorescence recoveryincreased drastically in the second bleaching experiment. Sinceall immobile proteins are irreversibly bleached during the firstlaser pulse, only mobile fluorescent proteins can diffuse intothe bleached spot and contribute to the fluorescence signalin the second experiment. Thus only mobile integrins are observedand we therefore obtain a higher recovery rate of 86 ±5%, whereas the diffusion constant D is the same as before.These findings strongly suggest that mobile and immobile integrinspecies coexist in the membrane. It is reasonable to assumethat all receptors with the large headgroups facing toward thesubstrate are immobile. According to previous electron microscopystudies the two orientations of the receptors are evenly distributedin the original vesicle preparation. One would thus expect that50% of the receptors should be fully mobile and fully functional.The immobilization of proteins with the large extracellulardomain pointing to the aqueous phase could be due 1), to localclustering of receptors within the supported membrane 2), tononspecific attraction between the proteins and the cellulosefilms, or 3), to nonspecific binding to defects in the cellulosefilm.

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FIGURE 4 (a) Fluorescence recovery after photobleaching (FRAP) curves of supported membranes containing labeled integrin. The gray circles correspond to the fluorescence signals from a membrane deposited directly on a bare glass substrate, whereas the black squares indicate the recovery curve of a membrane supported on a cellulose film (as depicted in the insets). For the membrane on the polymer cushion the percentage of fluorescence recovery is 25%. (b) The recovery curve obtained after another bleaching pulse applied to the same sample position. The recovery attains 86%.

The existence of defects in the supported membranes is suggestedby measurements of the lipid diffusion. For these experimentsthe fluorescent lipid NBD-PC was added to the integrin-containingmembrane. We obtained a diffusion constant D = 3.3 ±0.2 µm² s^-1 and a recovery fraction of 77 ± 1%for the membrane on cellulose cushions. Bleaching again thesame spot yielded a higher mobile fraction of 96.9 ±0.1% while the diffusion constant D remained the same. Thisresult shows that the supported membrane on the polymer cushionexhibits still a remarkable density of defects, which couldcomprise an area fraction of $~$ 20%. Receptors in this area fractionare expected to be immobile.

The measured lipid diffusion constants are a factor of threelarger than those reported for pure lipid bilayers on polymersupports or bare glass substrates (Sigl et al., 1997). Thiscan be interpreted in terms of the reduced frictional couplingbetween the membrane and the surface, which is inversely proportionalto the thickness of the water layer in between (Evans and Sackmann,1988). The rather rigid protein headgroups are expected to actas spacers between the polymer cushion and the lipid bilayer,hence friction between lipids and the polymer film is expectedto be smaller. The value of D = 3.3 ± 0.2 µm² s^-1is about half of the lipid diffusivity in a free bilayer membraneof pure DMPC (Almeida et al., 1992).

Interestingly, the diffusion constant of the lipids in the supportedmembranes on bare glass slides is a factor of 10 smaller thanin polymer supported membranes. This could be explained by assumingthat the integrins adsorbing with their large extracellulardomain on the surface can hinder the diffusion of lipids drastically(Chan et al., 1991, Kucik et al., 1999). Another explanationis that the diameter of the bleaching pulse (9.3 µm) islarger than the size of most of the continuous lipid patches,which would result in a reduced long-range diffusion coefficient.

Functionality test of integrin
The functionality of the reconstituted receptors in supportedmembranes was evaluated by quantitative analysis of the specificbinding to a cyclic hexapeptide containing the RGD sequence,which is specifically recognized by the ${alpha}$ _IIbß₃ receptor.Two series of binding tests were adopted: firstly, the bindingof fluorescently labeled RGD peptides to supported membraneswas tested. The fluorescence intensity in the presence of integrin(cf. Fig. 5) was a factor of two higher than in the absenceof receptors in the membrane. Another clear difference betweenthe two samples appeared when the dyes were continuously illuminated.For the membrane with integrin, we observed a continuous bleachingof fluorescent dyes, as manifested by an exponential decay ofthe signal intensity. In contrast, for pure membranes the fluorescencefrom the labeled RGD peptides remained constant, suggestingthat in this case the fluorescence signal comes from RGD peptidesin the bulk solution.

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FIGURE 5 (a) Fluorescence micrograph of the labeled RGD peptides bound to integrin-doped membrane supported on a cellulose cushion. (b) Schematic presentation of the side view of the membrane, where synthetic ligands bind only to the integrins pointing their extracellular headgroup into the aqueous phase.

The second and more powerful test of the functionality is basedon the study of adhesion of giant vesicles bearing RGD lipidsby using RICM. A typical RICM image of a giant vesicle withRGD lipids adhering to an integrin-containing bilayer on a cellulosefilm is shown in Fig. 6 a. Strong adhesion is indicated by theformation of a dark disc, where the distance between membraneand substrate is smaller than 30 nm (Bruinsma et al., 2000

).The picture shown was obtained by averaging over 20 subsequentimages ( $~$ 1 s). The interferogram exhibits well-defined Newtonrings, indicating that the vesicle is not moving or does notshow strong thermally excited bending fluctuations. This isa consequence of the strong adhesion which leads to the suppressionof the membrane flickering by the adhesion induced membranetension (Albertsdörfer et al., 1997

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FIGURE 6 (a) Reflection interference contrast microscopy (RICM) image of a giant vesicle containing 1% RGD lipid and 2% PEG lipid adhering to a membrane with integrin ${alpha}$ _IIbß₃. The membrane is supported by a cellulose cushion. The dark areas indicate strongly adhered patches. Newton fringes around the contact area show lines of equal height of the membrane above the surface. (b) Intensity profile along the straight line indicated in the interferogram. (c) The local height profile shown is reconstructed from the intensity profile. The contact angle ${alpha}$ and the characteristic capillary length ${lambda}$ are defined in the height profile. The zero point of the x axis (x = 0) is determined by the onset of the upward deflection of the membrane from the substrate.

In contrast, RGD lipid and PEG lipid containing giant vesiclesin contact with pure supported DMPC membranes do not adhere.No dark adhesion plaques are observed. The same is found forpure giant DMPC vesicles in contact with an integrin-containingsupported membrane. Thus, strong adhesion of vesicles does nottake place in the absence of either the receptors integrin ${alpha}$ _IIbß₃or the conjugated ligands (RGD lipids).

Adhesion strength on bare glass and on cellulose films
It is interesting to compare the adhesion strength of vesiclesadhering on the membrane deposited onto bare glass and ontocellulose films, since this will yield insights into the effectsof the mobility and functionality of receptors on the adhesion.In Fig. 6 a, an adhering vesicle on an integrin-containing membranesupported by a cellulose cushion is shown. Fig. 7 a shows avesicle in contact with a bilayer supported directly on bareglass. The adhesion in the latter case is weaker, because onlya small part of the contact area adheres strongly as indicatedby dark patches (cf. arrows in Fig. 7). Most of the adhesiondisc consist of large bright areas, which correspond to weakadhesion. The blurred appearance of the vesicle in Fig. 7 bindicates that the contact area fluctuates strongly.

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FIGURE 7 (a) RICM interferogram of a giant vesicle with 1% RGD lipid and 2% PEG lipid adhering to an integrin-doped membrane on a bare glass substrate (integration time 59 ms). The arrows indicate the strongly adhering (dark) area, whereas the main area of the adhesion disc adheres only weakly (light areas) and exhibits strong flickering. (b) RICM image of the same giant vesicle taken with a prolonged integration time of 5 s. Due to the motion of the contact area, the vesicle exhibits a bleary appearance.

The free energy of adhesion ${Delta}$ g_ad per unit area (also called spreadingpressure) of the vesicle to the substrate can be determinedby two different methods:

One way is to analyze the contour ofthe vesicle in terms ofmechanical equilibrium at the contactline of the adhering vesiclewith the substrate. This is describedby the classical wettingequation of Young-Dupré (Evans,1974, Bell et al., 1984,Bruinsma et al., 2000):
(1)
where ${alpha}$ isthe contact angle defined in Fig. 6, cand ${gamma}$ the lateral membranetension (corresponding to the surfacetension of a liquid).This equation holds for fluid membranes,when the tension ofthe vesicle membrane is homogeneous.
Thesecond method is based on the analysis of the vesicle globalshape as a function of the vesicle membrane area to the vesiclevolume (called the degree of deflation) following Seifert andLipowsky (1990). By respecting the equilibrium of the bendingmoments of the membrane near the surface this approach predicts:
(2)
where ${kappa}$ is the bending stiffness and R_C is thecontact curvature. The geometric parameter R_C is the curvatureat the transition from the adhering to the nonadhering regionsof the vesicle.

Unfortunately, the contact curvature is difficult to measure.Therefore, a more accurate method to determine ${Delta}$ g_ad is basedon a model suggested by Bruinsma (1995). The following equationfor the height profile of the membrane in the vicinity of thecontact line is obtained:

(3)
where xis defined in Fig. 6 c, ${alpha}$ is the macroscopic contact angle betweenthe membrane and the substrate, and is the capillary length. ${lambda}$ is a measure for the length over which thedeformation of the membrane at the contact line is determinedby the local bending deformation. Thus, for x > ${lambda}$ the vesicleshape is tension dominated. It is easily verified that ${lambda}$ is relatedto the contact curvature according to ${lambda}$ = ${alpha}$ R_C, as the second derivativeof Eq. 3 at x = 0 is the inverse contact curvature R_C. The geometricparameters ${alpha}$ and ${lambda}$ can be determined from the RICM image for eachlocation along the rim of the adhesion disc (Albertsdörferet al., 1997).

The capillary length ${lambda}$ is determined by the distance betweenx = 0 and the intersection of the straight line fitted to thecontour of the vesicle for and the x axis.The zero point of the axis (x = 0) is determined by the onsetof the deflection of the membrane (cf. Fig. 6 c). The bendingstiffness ${kappa}$ is assumed to be 100 k_BT for the DMPC vesicle containing50 mol % cholesterol. According to the Young equation (Eq. 1),the local adhesion energy ${Delta}$ g_ad could in principle be determinedat every position of the rim. However, since the values of ${lambda}$ can not be easily determined for regions of tight adhesion,more accurate results are obtained by measuring the tension ${gamma}$ at sites of weak adhesion, which exhibit many Newton rings.Then, owing the isotropic tension, this value of ${gamma}$ is used todetermine the adhesion energies ${Delta}$ g_ad at tight adhesion domainsaccording to Eq. 1. In Fig. 8 we show an example of the distributionof the contact angles ${alpha}$ and free adhesion energy densities ${Delta}$ g_adfor a vesicle containing 2% PEG lipid adhering to a cellulosesupported bilayer. At site numbers 0 and 9, the capillary lengthas well as the contact angle can be measured with high accuracy,whereas in the domains of tight adhesion (site numbers 3 and6) only the contact angle can be measured reliably. The freeadhesion energies per unit area measured for a given set ofconcentrations (c_R, c_Li) at various sites of the adhesion disc,agree remarkably well (cf. Fig. 8). This shows that the vesicleis in thermodynamic equilibrium which is an important conditionto obtain reproducible results. The free adhesion energy ${Delta}$ g_adobtained for different concentrations of repeller moleculesand 1% RGD lipid onto different substrates are presented inthe histogram in Fig. 9.

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FIGURE 8 Measurement of membrane tension ${gamma}$ , contact angle ${alpha}$ (circles) and free adhesion energy densities ${Delta}$ g_ad (squares) at sites of strong (black regions) and weak (light regions) adhesion near the rim of the adhesion disc.

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FIGURE 9 Histograms of measured values of free energies of adhesion of vesicles containing 2 and 3 mol % of repeller lipids (PEG lipids) on cellulose (black and dotted lines, respectively) and of vesicles containing 2 mol % PEG lipids on bare glass substrates (gray lines). Note that the largest value correspond to regions of tight adhesion, whereas the lowest values correspond to the spreading pressures of the regions of weak adhesion.

Estimation of the specific adhesion energy W_ad
In the following, we attempt to compare the measured valuesof ${Delta}$ g_ad for strong adhesion sites with the specific adhesionenergy W_ad (cf. Eq. 4, below), estimated as follows. By assumingfirstly that the integrin concentration within the strong adhesionplaque is about equal to the initial concentration and secondlythat 50% of the integrins exhibit the functional headgroup towardthe aqueous phase, the integrin receptor density is n_I ${approx}$ 7 x10¹³ m^-2. The binding energy of the receptor-ligand pair hasnot been measured yet, but it can be estimated from the dissociationconstant of the hexapeptide-integrin pair, k_D(I-RGD) ${approx}$ 1.1 x10^-6 M (Hu et al., 2000

). This k_D value is a factor of 10⁹ smallerthan the corresponding value reported for the biotin-streptavidinbond (k_D(B-S) $~$ 10^-15 M), which has a binding energy of w_ad(B-S) $~$ 35 k_BT (Bayer, 1990

). This approach yields w_ad(I-RGD) $~$ 10 k_BTfor the integrin-RGD binding energy. Note that this is a lowerlimit of the binding energy since the density of receptors n_Iwould be a factor of two smaller if the immobilized fractionof receptors is not functional.

The specific adhesion energy in our experiments is then expectedto be in the order of W_ad ${approx}$ n_I x w_ad(I-RGD) ${approx}$ 3 x 10^-6 J m^-2.According to Fig. 9, this value is only 3 and 10 times largerthan the largest spreading pressure ${Delta}$ g_ad found for vesicles containing2% and 3% PEG lipids, respectively. It is 30 times larger thanthe largest value of ${Delta}$ g_ad found for vesicles containing 2% PEGlipid on pure glass substrates (cf. Fig. 9).

The relatively small discrepancies between the values of W_adand ${Delta}$ g_ad for the cellulose covered substrates can be understoodas follows (Sackmann and Bruinsma, 2002). The free adhesionenergy has been shown to depend not only sensitively on thereceptor and ligand densities and their binding energy, butalso on the repeller concentration c_R since the two-dimensionalosmotic pressure difference between the adhesion plaque andthe nonadherent membrane regions reduces the free energy ofadhesion drastically (Bell et al., 1984, Bruinsma et al., 2000).By ignoring effects of the membrane elasticity, the free energyof adhesion can be expressed as

(4)
where ${Delta}$ ${pi}$ _R and ${Delta}$ ${pi}$ _Li is the osmotic pressure difference of the repellersand ligands, respectively. W_ad is the specific adhesion energyper unit area of the receptor-ligand pairs. The osmotic pressuredifference ${Delta}$ ${pi}$ _R arises since the repeller molecules are partiallyexpelled from the tight adhesion domains due to the steric repulsiongenerated by the large PEG headgroups having a Flory radius (deGennes, 1980). Because the headgroupsof the RGD ligands are very small, they are expected to be ratherevenly distributed between strongly adhering regions and thefree membrane and their effect is thus ignored in the following.The osmotic pressure difference of the repellers can be estimatedfrom van't Hoff's law:

(5)
where ${Delta}$ c_R isthe difference in the repeller concentration between the adherentand free membrane regions.

If the local repeller concentration in the adhesion domain isassumed to be zero and the area per lipid is 100 Å², theosmotic pressure (for 2 mol % PEG lipid) would be ${Delta}$ ${pi}$ _R ${approx}$ 8 x 10^-5J m^-2 (according to Eq. 5). This value is much higher than themeasured spreading pressure ( ${Delta}$ g_ad = 1 x 10^-6 J m^-2, cf. Fig. 9).In order to account for the difference between the spreadingpressure ${Delta}$ g_ad and the estimated specific interaction energy W_ad,we calculate the energetic difference to 2 x 10^-6 J m^-2 forthe case of 2% PEG by application of Eq. 4. The concentrationdifference ${Delta}$ c_R necessary to generate this difference is determinedto ${Delta}$ c_R $~$ 0.03c_R, which is very small. The existence of a ratherhigh density of PEG lipids in the tight adhesion plaques suggestedhere, can be explained in terms of the larger integrin headgroups ( $~$ 12 nm) than the Flory radius of the PEG lipid (R_Flory ${approx}$ 3 nm).

According to Eq. 4, the specific adhesion energy W_ad is obtainedfrom the measurement of ${Delta}$ g_ad by extrapolation ${Delta}$ g_ad versus thePEG lipid concentration c_R to c_R = 0. This approach yields afree adhesion energy ${Delta}$ g_{ad(cR = 0)} = 2 x 10^-6 J m^-2 at c_R = 0.This extrapolated value of ${Delta}$ g_ad agrees well with the predictedspecific adhesion energy in the tight adhesion plaques W_ad =3 x 10^-6 J m^-2. We can conclude further that the mobile integrinreceptors do not accumulate remarkably in the tight adhesiondomains. A possible explanation of this finding is that theaccumulation of the receptors is impeded by the presence ofrepeller molecules.

The much smaller value of the free adhesion energy ${Delta}$ g_ad on anintegrin-doped membrane supported by a bare glass surface (cf.Fig. 9), can be attributed to the partial denaturation of thereceptors, since effects of the osmotic pressure differenceshould be similar to that in the vesicle on polymer-supportedmembranes.

CONCLUSIONS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

To design models of cell surfaces, we established solid supportedmembranes with incorporated, large transmembrane proteins, suchas integrin receptors. The membranes were separated from thesolid substrates by ultrathin, soft cellulose multilayers. Thesepolymer cushions were shown to be particularly well suited asbiocompatible soft surface to prepare macroscopically homogeneoussupported membranes. A fraction of 25% of the integrin receptorson the cellulose cushion exhibits long range lateral mobility(diffusion constant D = 0.6 µm² s^-1), attributed to theproteins pointing their large headgroups into the aqueous phase.Integrins incorporated in membranes supported on bare glasssubstrates are essentially immobilized. Additionally, a drasticreduction in the adhesion strength of the receptors on thesesurfaces was observed, in comparison to the adhesion strengthon soft polymer surfaces. The free adhesion energy (spreadingpressure) ${Delta}$ g_ad could be measured quantitatively in terms of theelastic boundary conditions. It corresponds to the differenceof the specific energy W_ad and the lateral osmotic pressureexerted by the repeller molecules ${Delta}$ ${pi}$ _R. Previously, it was reportedthat the adhesion process is accompanied by repeller segregationand adhesion plaque formation. The results here however show,that the repeller concentration in the adhesion plaque is onlyabout 3% smaller than that in the free membrane. Because theFlory radius of the used repeller (3 nm) is smaller than thereceptor headgroup (12 nm), the repeller depletion, enforcedby the interplay of short range attraction of receptor-ligandpairs and the long-range generic repulsion, is weak for thepresent system.

Measurements of ${Delta}$ g_ad as a function of the repeller concentrationallowed us to estimate the specific adhesion energy W_ad of thevesicle to the substrate. By neglecting receptor condensation,we obtain for the specific receptor-ligand binding energy alower limit An independent measurement of the local receptor density in the adhesion plaque would benecessary for a more reliable determination of an absolute valueof w_ad. However, the present technique provides a simple andpowerful tool to measure relative values of the receptor-ligandbinding energies of different receptor-ligand pairs under thebioanalogue condition that both interacting surfaces are fluid.The strong reduction of the binding energy observed for membranessupported by bare glass shows the importance of depositing membraneson soft polymer films for quantitative adhesion studies.

ACKNOWLEDGEMENTS

TOP
ABSTRACT
INTRODUCTION
MATERIALS AND METHODS
RESULTS AND DISCUSSION
CONCLUSIONS
ACKNOWLEDGEMENTS
REFERENCES

We thank M. Rusp for the preparation of the integrin vesicles,Dr. S. Kaufmann for the help with the phosphate analysis andprotein concentration measurements, and Dr. M. Bärmannfor helpful advice in biochemistry. F. Foerster from the MPIfür Biochemie in Martinsried took the electron microscopyimage. K. Behrendt is acknowledged for the fluorescent labeledRGD peptide and J. Schilling for developing the real time imagingsoftware. O. Purrucker is acknowledged for a critical readingof the manuscript. One of the authors (M.T.) is grateful toProf. G. Wegner for helpful suggestions in cellulose chemistry.

This work was supported by the Deutsche Forschungs Gesellschaft(SFB 563) and the Fonds der Chemischen Industrie. M.T. is thankfulto DFG for Habilitation fellowship (Emmy Noether-Program).

Submitted on October 25, 2002; accepted for publication February 10, 2003.

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ACKNOWLEDGEMENTS
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