Endothelial adhesion receptors are recruited to adherent leukocytes by inclusion in preformed tetraspanin nanoplatforms

doi:10.1083/jcb.200805076

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doi:10.1083/jcb.200805076
The Journal of Cell Biology, Vol. 183, No. 3, 527-542
The Rockefeller University Press, 0021-9525 $30.00
© Barreiro et al.

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Endothelial adhesion receptors are recruited to adherent leukocytes by inclusion in preformed tetraspanin nanoplatforms

Olga Barreiro¹^,2, Moreno Zamai⁴^,5, María Yáñez-Mó¹^,2, Emilio Tejera¹^,2, Pedro López-Romero³, Peter N. Monk⁶, Enrico Gratton⁷, Valeria R. Caiolfa²^,4^,5, and Francisco Sánchez-Madrid¹^,2

¹ Servicio de Inmunología, Hospital de la Princesa, Universidad Autónoma de Madrid, 28006 Madrid, Spain
² Departamento de Biología Vascular e Inflamación and ³ Unidad de Genómica, Centro Nacional de Investigaciones Cardiovasculares, 28029 Madrid, Spain
⁴ Department of Molecular Biology and Functional Genomics and ⁵ Italian Institute of Technology Network Research, Unit of Molecular Neuroscience, San Raffaele Scientific Institute, 20132 Milan, Italy
⁶ Academic Neurology Unit, School of Medicine and Biomedical Science, University of Sheffield, Sheffield S10 2RX, England, UK
⁷ Laboratory for Fluorescence Dynamics, Biomedical Engineering Department, University of California, Irvine, Irvine, CA 92697

Correspondence to Francisco Sánchez-Madrid: fsanchez.hlpr{at}salud.madrid.org

VCAM-1 and ICAM-1, receptors for leukocyte integrins, are recruitedto cell–cell contact sites on the apical membrane of activatedendothelial cells. In this study, we show that this recruitmentis independent of ligand engagement, actin cytoskeleton anchorage,and heterodimer formation. Instead, VCAM-1 and ICAM-1 are recruitedby inclusion within specialized preformed tetraspanin-enrichedmicrodomains, which act as endothelial adhesive platforms (EAPs).Using advanced analytical fluorescence techniques, we have characterizedthe diffusion properties at the single-molecule level, nanoscaleorganization, and specific intradomain molecular interactionsof EAPs in living primary endothelial cells. This study providescompelling evidence for the existence of EAPs as physical entitiesat the plasma membrane, distinct from lipid rafts. Scanningelectron microscopy of immunogold-labeled samples treated witha specific tetraspanin-blocking peptide identify nanoclusteringof VCAM-1 and ICAM-1 within EAPs as a novel mechanism for supramolecularorganization that regulates the leukocyte integrin–bindingcapacity of both endothelial receptors during extravasation.

Abbreviations used in this paper: ACF, autocorrelation function;EAP, endothelial adhesive platform; FCS, fluorescence correlationspectroscopy; FLIM, fluorescence lifetime imaging microscopy;FN, fibronectin; FRET, Förster resonance energy transfer;FRETeff, FRET efficiency; GPI, glycosylphosphatidylinositol;HUVEC, human umbilical vein endothelial cell; knn, k nearestneighbor; LEL, large extracellular loop; mEGFP, monomeric EGFP;TEM, tetraspanin-enriched microdomain; VE-cadherin, vascularendothelial cadherin.

© 2008 Barreiro et al. This article is distributed underthe terms of an Attribution–Noncommercial–ShareAlike–No Mirror Sites license for the first six monthsafter the publication date (see http://www.jcb.org/misc/terms.shtml).After six months it is available under a Creative Commons License(Attribution–Noncommercial–Share Alike 3.0 Unportedlicense, as described at http://creativecommons.org/licenses/by-nc-sa/3.0/).

Introduction

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Abstract
Introduction
Results
Discussion
Materials and methods
References

How cells physically organize and compartmentalize receptorsand signaling molecules into specialized, efficient, regulatednetworks is of critical importance to our understanding of thecomplexity and dynamics of biological processes. In this regard,cholesterol and sphingolipid-enriched rafts have been proposedas platforms for the sorting of specific membrane components,such as glycosylphosphatidylinositol (GPI)-anchored proteins,and as sites for the assembly of cytoplasmic signaling complexes(Simons and Toomre, 2000; Anderson and Jacobson, 2002). Recentbiochemical, proteomic, and structural studies bolster the ideathat tetraspanin-enriched microdomains (TEMs) at the plasmamembrane play a key role in organizing molecular complexes withprotein compositions different from those of typical lipid rafts(Hemler, 2005; Le Naour et al., 2006; Min et al., 2006). Theexistence and physical properties of lipid rafts have been extensivelystudied by innovative analytical methods (Kenworthy et al., 2004;Sharma et al., 2004; Larson et al., 2005; Suzuki et al., 2007).However, the presence and molecular dynamics of TEMs on theplasma membrane of living cells have not been explored.

Tetraspanins are ubiquitous, low molecular weight proteins thatspan the plasma membrane four times and are able to organizethemselves by homo- and heterooligomerization (Hemler, 2005).Moreover, these molecules can simultaneously associate laterallyat the plasma membrane with numerous integral membrane receptors,modulating their functions and organizing discrete, dynamicplasma membrane compartments. These partners include integrinsand other adhesion molecules (Yanez-Mo et al., 1998; Berditchevski, 2001;Barreiro et al., 2005), CD19–CD21 (Cherukuri et al., 2004;Levy and Shoham, 2005), major histocompatibility complex–peptidecomplexes (Kropshofer et al., 2002), Fc receptors (Moseley, 2005),G protein–coupled receptors (Little et al., 2004), andmetalloproteinases (Yan et al., 2002). Tetraspanins also associateintracellularly with several cytoplasmic signaling mediatorssuch as type II PI4K or PKC isoforms (Yauch and Hemler, 2000;Zhang et al., 2001). Apart from acting as adapters for membraneorganization, tetraspanins also regulate the trafficking andbiosynthetic processing of associated receptors (Berditchevski and Odintsova, 2007).Although TEMs seem to be different from biochemically definedlipid rafts (Simons and Toomre, 2000), they are not devoid oflipid interactions because tetraspanins are highly palmitoylatedproteins that bind cholesterol and gangliosides (Charrin et al., 2003;Yang et al., 2004).

The composition and other specific characteristics of TEMs mayvary with cell type. Gene deletion, knockdown, overexpression,and mutation experiments have revealed key functional rolesfor tetraspanins in many fundamental physiological processes,among which are egg–sperm fusion (Le Naour et al., 2000;Miyado et al., 2000), antigen presentation (Kropshofer et al., 2002;Levy and Shoham, 2005; Unternaehrer et al., 2007), viral cellentry and budding and virus-promoted syncytia formation (Pileri et al., 1998;Gordon-Alonso et al., 2006; Nydegger et al., 2006), kidney failureand tissue angiogenesis (Sachs et al., 2006; Takeda et al., 2007),and cell adhesion, migration, and invasion (Yanez-Mo et al., 1998,2008; Chattopadhyay et al., 2003; Hemler, 2003; Barreiro et al., 2005).Because there are few known tetraspanin ligands, it is verylikely that these molecules exert their regulatory effects indirectlythrough their lateral binding to assorted partners. However,the molecular mechanisms underlying the regulatory activityof tetraspanins remain elusive.

Leukocyte extravasation from the bloodstream to sites of infectionand inflammation involves a dynamic interaction with the endotheliumthat is mediated by an array of leukocyte and endothelial cellsurface receptors. This process consists of sequential stepsof tethering, rolling, firm adhesion, locomotion, and diapedesis,with specialized receptor/ligand pairs involved in each (Ley et al., 2007).Previous studies have shown that, to prevent leukocyte detachmentunder hemodynamic flow, endothelial cells form actin-based structuresthat cluster VCAM-1, ICAM-1 (Barreiro et al., 2002; Carman and Springer, 2003;van Buul et al., 2007), tetraspanins, and actin-binding proteinsat the contact area with leukocytes (Barreiro et al., 2002,2005).

In this study, we demonstrate that before leukocyte binding,the apical plasma membrane of living endothelial cells possessesspecialized microdomains containing tetraspanins and adhesionreceptors (VCAM-1 and ICAM-1), which we have termed endothelialadhesive platforms (EAPs). This particular kind of TEM promotesmolecular aggregation at the nanoscopic scale (nanoclustering)of adhesion receptors to enhance their adhesive properties duringleukocyte adhesion to endothelium. By using advanced analyticalfluorescence microscopy techniques, we have determined the molecularcharacteristics, dynamics, and biophysical properties of EAPs.Finally, using scanning electron microscopy in combination withtetraspanin-blocking peptides, we show that tetraspanin microdomainsmake an essential contribution to the avidity regulation ofendothelial adhesion receptors, fine-tuning their adhesive properties.

Results

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Endothelial ICAM-1 and VCAM-1 cluster at the docking structure independently of counterreceptor engagement and actin anchorage
We have previously shown that at contact sites with adherentleukocytes, activated endothelial cells form three-dimensionalactin-based docking structures that cluster VCAM-1 and ICAM-1(Barreiro et al., 2002). To analyze the dynamic recruitmentof adhesion molecules to these docking structures, we inducedtheir formation with K562 cells expressing either ${alpha}$ 4β1 or ${alpha}$ Lβ2 integrins (K562 ${alpha}$ 4 or K562 lymphocyte function-associatedantigen–1 [LFA-1]), which adhere to activated endothelialcells via VCAM-1 or ICAM-1, respectively. Surprisingly, bothICAM-1 and VCAM-1 clustered at the docking structure formedaround either K562 clone, regardless of whether they were directlyengaged by their corresponding integrin receptor (Fig. 1 A). To assess the generality of this corecruitment, we examinedthe docking structures formed with T lymphoblasts, which expressboth LFA-1 and very late antigen–4 (VLA-4); before adhesionto activated human umbilical vein endothelial cells (HUVECs),LFA-1 was blocked with a specific allosteric antagonist (BIRT377),or VLA-4 was blocked with a ligand-binding inhibitor (BIO5192).In both cases, VCAM-1 and ICAM-1 were corecruited in a similarway as observed with K562 cells (Fig. 1 B).

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Figure 1. VCAM-1 and ICAM-1 are copresented at lymphocyte–endothelium contact sites independently of ligand binding and actin anchorage. (A) K562 ${alpha}$ 4 or LFA-1 was adhered (30 min) to TNF- ${alpha}$ –activated HUVECs. Samples were fixed and double stained with anti–VCAM-1 (P8B1) and biotin-conjugated anti–ICAM-1 (MEM111). Confocal stacks were obtained, and orthogonal maximal projections and vertical three-dimensional reconstructions of the whole series are displayed. (B) Human T lymphoblasts were pretreated (5 min) with 10 µM BIRT377 or 10 µg/ml BIO5192 to inactivate LFA-1 or VLA-4 and were added to TNF- ${alpha}$ –activated HUVECs for 5 min. Fixed cells were double stained as in A. Confocal stacks were obtained, and a representative section from each treatment is shown together with its corresponding colocalization histogram and a mask showing the distribution of double green-red pixels (marked regions) within the cell. (C) Resting HUVECs transfected with VCAM ${Delta}$ Cyt were incubated with K562 ${alpha}$ 4 (i), K562 LFA-1 (ii), or T lymphoblasts (iii). Fixed cells were double stained with anti–VCAM-1 (VCAM ${Delta}$ Cyt was the only VCAM-1 species detected) and biotin-conjugated anti–ICAM-1. Confocal stacks were obtained; representative sections or vertical reconstructions of the whole series are displayed. Arrows show positions of adhered leukocytes. The deleted sequence in the VCAM ${Delta}$ Cyt construct is shown in red below the figure. TM, transmembrane; Cyt Dom, cytoplasmic domain. Bars: (A and C) 20 µm; (B) 10 µm.

To assess the involvement of the endothelial actin cytoskeletonin VCAM-1–ICAM-1 corecruitment, we transiently transfectedresting HUVECs with a cytoplasmic tail–truncated VCAM-1mutant (VCAM ${Delta}$ Cyt). Under these conditions, HUVECs bear low levelsof ICAM-1 and negligible levels of endogenous VCAM-1. Upon engagementof VCAM ${Delta}$ Cyt by K562 ${alpha}$ 4, discrete clusters containing VCAM ${Delta}$ Cyt andICAM-1 were observed around adhered cells, but in no case wasa well-developed three-dimensional structure formed (Fig. 1 C, i).In contrast, when ICAM-1 was directly engaged by K562 LFA-1,a proper docking structure was formed, also containing VCAM ${Delta}$ Cyt(Fig. 1 C, ii). Likewise, well-formed docking structures containingICAM-1 and VCAM ${Delta}$ Cyt were induced by adhered T lymphoblasts (Fig. 1 C, iii).These data suggest that the engagement of one endothelial adhesionreceptor by its corresponding leukocyte integrin corecruitsthe other receptor toward the contact area. This coclusteringmust involve the extracellular or transmembrane domains of bothadhesion molecules because it occurs with cytoplasmic tail–truncatedforms. However, subsequent reorganization of the endothelialactin cytoskeleton into the protrusive cup requires actin anchorageof the cytoplasmic tail of the ligand-bound endothelial adhesionmolecule.

Analysis of homo- and heterophilic interactions of ICAM-1 and VCAM-1 in living endothelial cells
Because cytoskeletal anchorage cannot account for adhesion receptorcorecruitment, we investigated the potential formation of VCAM-1–ICAM-1heterodimers at the apical membrane of living primary endothelialcells by Förster resonance energy transfer (FRET)–fluorescencelifetime imaging microscopy (FLIM) analysis. For this purpose,we generated functional VCAM-1 and ICAM-1 chimeras fused tomonomeric EGFP (mEGFP) as donor and mRFP1 as acceptor. The constructswere transiently cotransfected into primary HUVECs under restingconditions to prevent up-regulation of endogenous VCAM-1 andICAM-1 expression. We then analyzed the molecular interactionsat a nanometric scale between ICAM-1–ICAM-1, VCAM-1–VCAM-1,and ICAM-1–VCAM-1 by alternately using each receptor asdonor (Fig. 2). The fluorescence lifetime of the donor ineach cotransfection was compared with that of singly transfectedICAM-1– or VCAM-1–mEGFP (donor standards in Fig.S1 A, available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).In the case of ICAM-1–ICAM-1 interaction, although mostpixels were below the FRET detection threshold (FRET efficiency[FRETeff] $≤$ 10%), the remaining pixels (12%) showed positiveFRETeff of 14–34% and were localized in clusters at themembrane (Fig. 2 A). In contrast, the analysis showed no significantmolecular interactions of the VCAM-1–VCAM-1, ICAM-1–VCAM-1,and VCAM-1–ICAM-1 pairs (Fig. 2, B–D). Thus, underthese conditions, homophilic ICAM-1–ICAM-1 interactions,but not VCAM-1–VCAM-1 or heterophilic VCAM-1–ICAM-1interactions, are detected on the plasma membrane of livingprimary endothelial cells.

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Figure 2. VCAM-1 and ICAM-1 do not interact at the plasma membrane. Endothelial cells were cotransfected with mEGFP–mRFP1 pairs (ICAM-1–ICAM-1, VCAM-1–VCAM-1, ICAM-1–VCAM-1, and VCAM-1–ICAM-1). A representative FRET–FLIM analysis using the phasor plot is shown for each pair. The sine (s) and cosine (g) transforms of the lifetime data measured in the frequency mode generate the coordinate system presented in the phasor (Digman et al., 2008). Fluorescence intensity (F. intensity) images are in pseudocolor (left), and corresponding mEGFP lifetime distributions are shown in the plots after the phasor transformation (right). In each phasor plot, the green line represents 0% FRETeff and the red line marks 50% FRETeff (Caiolfa et al., 2007). The black circular cursors in the phasor plots select the subset of pixels shown in the correlated FLIM images (pink mask for positive FRET and white mask for negative FRET; middle). For the ICAM-1–ICAM-1 pair (A), most pixels lie very close to the green line (FRETeff $≤$ 10%; negligible), but 12% of pixels exhibit FRETeff of 14–34%. These positive pixels are localized in clusters, as shown by the FLIM image (pink mask). Other protein pairs (B–D) show phasor distributions indistinguishable from that of the negative controls (Fig. S1 A, available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1). a.u., arbitrary units. Bars, 20 µm.

Tetraspanin microdomains are involved in the formation of specialized EAPs
Because there is no heterophilic ICAM-1–VCAM-1 interaction,the coclustering of adhesion receptors may involve their lateralassociation with specific plasma membrane microdomains. We havepreviously found that the CD9, CD81, and CD151 tetraspaninsconcentrate at docking structures around primary human leukocytesand coprecipitate together with VCAM-1 and ICAM-1 (Barreiro et al., 2005).In this study, we found that tetraspanin proteins were alsoenriched at docking sites in the K562 ${alpha}$ 4 and LFA-1 adhesion models(Fig. S2 A, available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).To examine this association further, we engaged endothelialsurface proteins with specific magnetic bead–coated antibodies,finding that engagement of either CD9 or CD151 corecruited bothICAM-1 and VCAM-1. Conversely, beads coated with anti–VCAM-1corecruited ICAM-1 and vice versa, and both antibodies clusteredtetraspanins. In contrast, anti–vascular endothelial cadherin(VE-cadherin)–coated beads did not significantly recruitICAM-1, VCAM-1, or tetraspanins above basal levels (Fig. S2,B and C; and not depicted).

Sucrose gradient fractionation of lysates of TNF- ${alpha}$ –activatedHUVECs showed that most tetraspanins are soluble under theseconditions and migrate with the dense fractions (F1–F7)together with ICAM-1 and VCAM-1, which were not found in lipidraft fractions containing caveolin (Fig. S2 D). These resultsstrongly suggest that endothelial tetraspanin microdomains containingVCAM-1 and ICAM-1 are distinct from classical biochemicallydefined lipid rafts and may constitute specialized, organizedmembrane structures, which we have termed EAPs.

Molecular dynamics at EAPs
To explore the molecular dynamics of tetraspanins and adhesionreceptors at EAPs, we first used FRAP to study the diffusionalproperties of EGFP-tagged CD9, CD151, VCAM-1, and ICAM-1 atthe nude apical plasma membrane of HUVECs in comparison withthe lipid raft marker GPI-EGFP (Fig. 3 A and Table S1, availableat http://www.jcb.org/cgi/content/full/jcb.200805076/DC1; Sharma et al., 2004). The derived apparent diffusion coefficient (Table S1) and theimmobile fraction (1 – R) for each protein (Fig. 3 A)were calculated. GPI-EGFP showed the highest mobility ( $~$ 1 µm²/s,as previously described in Kenworthy et al., 2004). Tetraspaninsand ICAM-1 behaved similarly (D = $~$ 0.5 µm²/s), whereasVCAM-1 seemed to diffuse slower (D = $~$ 0.3 µm²/s) and exhibiteda higher immobile fraction.

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Figure 3. EAP component dynamics at nude membrane and docking structures. (A) Endothelial cells were transiently transfected with CD9-, CD151-, ICAM-1–, VCAM-1–, or GPI-EGFP and activated with TNF- ${alpha}$ . FRAP curves from comparable areas of nude plasma membrane were acquired and fitted by a simple diffusion model. Mean-fitted fluorescence recovery curves ± SEM are depicted on the overlay graphic. (B) Representative FRAP analysis at an endothelial docking structure. Prebleaching image shows an ICAM-1–EGFP-transfected endothelial cell with docking structures formed around attached K562 LFA-1 cells (circles of high fluorescence). The boxed docking structure, shown in the inset at high magnification during bleaching, was selected for photobleaching recovery. Bar, 20 µm. (C and D) Mean-fitted fluorescence recovery curves ± SEM for ICAM-1–, VCAM-1–, CD9-, and CD151-EGFP at docking structures (comparable areas) formed around K562 LFA-1 or K562 ${alpha}$ 4. (E) Mean-fitted fluorescence recovery curves ± SEM for GPI-EGFP at plasma membrane (PM) or docking structures (DS; comparable areas). Immobile fractions calculated from fitted curves are shown in the bar histograms. Statistical analysis and number of experiments are shown in Table S2 (available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).

To assess the influence of leukocyte adhesion on EAP dynamics,FRAP was performed on endothelial docking structures inducedby engagement of K562 ${alpha}$ 4 or LFA-1 (Fig. 3, B–D). The mostnotable effects were when an endothelial adhesion receptor wasspecifically bound to its ligand, a greater proportion of theprotein population remained immobile, and the mobility of theresidual mobile fraction was locally restricted (Fig. 3, C and D;and Fig. S3 A, available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).Other nonligated EAP components were affected to a lesser extent,exhibiting a variable slowdown in FRAP recovery curves comparedwith analyses of the same molecules at other plasma membraneregions of similar size (Fig. S3 A). Statistical analyses showedthat ICAM-1 engagement had the greater effect on CD9 mobility,whereas CD151 was more affected by VCAM-1 engagement (TableS2 and Fig. S3 A). These data thus suggest a degree of specificityamong tetraspanin–partner interactions within EAPs. GPI-EGFPdiffusion was not altered at docking structures (Fig. 3 E).

Differences in the diffusion of tetraspanins and adhesion receptorscould be related to their differential anchorage to the actincytoskeleton. We therefore analyzed the dynamics of a cytoplasmictail–truncated mutant of ICAM-1 (ICAM-1 ${Delta}$ Cyt-EGFP), whichlacks actin–cytoskeleton linking activity. Freed of cytoskeletalconstraints, this truncated ICAM-1 diffused at the plasma membranemore rapidly than the full-length receptor (Fig. S3 B). ICAM-1 ${Delta}$ Cyt-EGFPalso had a faster fluorescence recovery rate than the wild-typemolecule at docking sites with K562 LFA-1 cells, indicatingthat stabilization of the ICAM-1–LFA-1 interaction alsoimplies anchorage of ICAM-1 to the endothelial F-actin cytoskeleton(Fig. S3 B).

To accurately estimate the diffusional features of individualEAP components, we applied fluorescence correlation spectroscopy(FCS) to mEGFP-tagged ICAM-1, VCAM-1, CD9, and CD151 expressedin living primary human endothelial cells. The autocorrelationfunctions (ACFs) derived from fluorescence intensity traceswere best fitted using an anomalous diffusion model. We foundthat all of these proteins showed a pattern of local diffusionconfinement, with ICAM-1 and VCAM-1 showing slower overall diffusionthan tetraspanins, correlating with a higher diffusion anomality(smaller ${alpha}$ coefficient values; Fig. 4 A). Tetraspanins showeda higher relative frequency of faster diffusion than adhesionreceptors (Fig. S4 A, available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).This might indicate a more confined diffusion of VCAM-1 andICAM-1 within EAPs versus a more dynamic exchange of tetraspaninsamong different microdomains. Furthermore, we found a pronounceddecrease in the molecular mobility of CD9 within docking structurescompared with nude plasma membrane (Fig. 4 B), concurring withdata obtained by FRAP analysis.

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Figure 4. EAP component diffusion at nude membrane and docking structures. (A) Representative FCS measurements at plasma membranes of transiently transfected primary HUVECs expressing very low levels of CD9-, CD151-, ICAM-1–, or VCAM-1–mEGFP. For each condition, the figure shows the fluorescence intensity image (kCPS, kilo counts per second), the ACF (black line) derived from the fluorescence intensity trace acquired at the point marked with a white cross, the best-fitted curve using an anomalous diffusion model (red line), and the diffusion (D) and anomality ( ${alpha}$ ) coefficients. In the FCS autocorrelation curves, the x axis ( ${tau}$ ) represents the delay time in seconds, and the y axis (G( ${tau}$ )) is the autocorrelation amplitude as a function of delay time. Box-whisker plots show distributions of D and ${alpha}$ values obtained from several transiently transfected HUVEC batches using mEGFP and mRFP1 versions of the four proteins; minimum, 25th percentile, median, 75th percentile, and maximum values are shown. (B) Representative FCS measurements of CD9-mGFP at the plasma membrane and an endothelial ICAM-1–mediated docking structure formed around an adhered K562 LFA-1 cell. The same parameters described in A are shown. Box-whisker plots compare data from the plasma membrane (reproduced from A) with data from docking structures. Statistical analysis and number of experiments are reported in Table S3 (available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).

Specificity of tetraspanin–adhesion receptor interactions within EAPs
Next, we performed additional FRET–FLIM analyses in livingendothelial cells to explore the molecular interactions amongCD9, CD151, ICAM-1, and VCAM-1. These assays confirmed the homophilicCD9–CD9 and heterophilic CD9–CD151 interactions(Fig. 5, A and B) previously shown by biochemical studies (forreview see Hemler, 2005). In addition, we found that CD9 preferentiallyinteracted with ICAM-1 and CD151 with VCAM-1, with FRETeff valuesclose to those detected between tetraspanins (Fig. 5, C and D).In contrast, VCAM-1–CD9 and ICAM-1–CD151 interactionswere scarce throughout the cell membrane and were not detectedin all cells studied (Fig. S1, B and C). These results furthersupport the existence of differential molecular interactionsin EAPs and strongly suggest that there are preferential associationsbetween specific adhesion receptors and tetraspanins. In furtherbiochemical and microscopy analyses, we searched for other endothelialreceptors that might interact with tetraspanins and clusterat the leukocyte–endothelial contact area independentlyof ligand binding, identifying PECAM-1/CD31, CD44, JAM-A, andICAM-2 as putative EAP components (Fig. S4, B and C; and notdepicted). In contrast, VE-cadherin does not coprecipitate tetraspanins(Fig. S4 B), and its engagement does not induce corecruitmentof EAP components (Fig. S2, B and C), suggesting its exclusionfrom these specialized membrane microdomains.

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Figure 5. Specificity of molecular interactions in EAP HUVECs transfected with mEGFP–mRFP1 pairs (CD9–CD9, CD9–CD151, ICAM-1–CD9, and VCAM-1–CD151). FRET–FLIM analysis was performed as in Fig. 2. For each FRET pair, the figure shows the fluorescence intensity (F. intensity) image (in pseudocolor scale), the phasor plot, and the FLIM image corresponding to the cursor selection in phasors (black circles), with the location of the highest FRETeff population illustrated with the pink mask (14–34% FRETeff). a.u., arbitrary units; s, sine; g cosine. Bars, 20 µm.

Role of tetraspanins in the molecular dynamics and nanoclustering of adhesion receptors in EAPs
To investigate the role of tetraspanins in the molecular dynamicsof EAPs, we used the tetraspanin-blocking peptide CD9–largeextracellular loop (LEL)–GST. Tetraspanin-blocking peptideshave been used to perturb functions regulated by tetraspaninmicrodomains, such as egg–sperm fusion, monocytic giantcell formation and HIV infection (Zhu et al., 2002; Takeda et al., 2003;Ho et al., 2006), and VCAM-1– and ICAM-1–mediatedlymphocyte adhesion strength and transmigration under flow invitro (Barreiro et al., 2005). However, the mechanism of actionof LEL peptides has not been elucidated yet. FCS analyses showedthat CD9-LEL-GST decreased the diffusion of CD9 and CD151 (Fig. 6, A–C),suggesting that interference with CD9, the most abundant EAPcomponent, has a critical effect on EAP organization and dynamics.

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Figure 6. CD9-LEL-GST perturbs EAP dynamics. (A and B) Representative FCS measurements at the plasma membrane of endothelial cells transiently cotransfected with CD9-mRFP1 (A) and CD151-mEGFP (B) and treated with 250 µg/ml active or heat-inactivated CD9-LEL-GST. The figure shows the fluorescence intensity image, the ACF (black lines) derived from the fluorescence intensity trace acquired at the point marked with a white cross, the best-fitted curve using an anomalous diffusion model (red lines), and D and ${alpha}$ coefficients. (C) Box-whisker plots show distributions of D and ${alpha}$ values (as in Fig. 4). Statistical analysis and number of experiments are presented in Table S3 (available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1). kCPS, kilo counts per second.

The spatial organization of EAPs was assessed by scanning electronmicroscopy combined with immunogold labeling of VCAM-1 and ICAM-1.We found submicrometer-sized homo- and heteroclusters of theseadhesion receptors throughout the nude apical plasma membrane(Fig. 7 A and Fig. 8, left), supporting the concept of preexistentEAP microdomains. Localized high density clustering was observedat the microvilli of docking structures around adherent leukocytes(shown for ICAM-1; Fig. 8, right), indicating that EAPs coalesceduring the formation of such structures. Quantification of clustersand particles/cluster in cell membrane areas expressing highor low content of ICAM-1 and VCAM-1 revealed an increase incluster number in those areas containing higher numbers of adhesionmolecules, whereas there was no significant change in the numberof particles per cluster. EAPs therefore seem to be size restrictedto nanometric dimensions (apparent mean size of $~$ 300 nm; Fig. 7 Aand Fig. S5 A, available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1).

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Figure 7. Tetraspanins regulate endothelial adhesion receptor nanoclustering. (A) TNF- ${alpha}$ –activated endothelial cells were fixed and stained with anti–VCAM-1 or anti–ICAM-1 followed by 40-nm gold immunolabeling. Representative scanning electron microscope negative images of the endothelial plasma membrane are shown. Mean cluster number and size ± SEM for VCAM-1– and ICAM-1–containing microdomains analyzed in images with low or high particle number (i.e., indirect measurement of low or high receptor expression). Clustering parameters: ${delta}$ = 100 and ${lambda}$ = 1 (see Materials and methods). (B) Gold particle coordinates from individual scanning electron microscope images (15-µm² plasma membrane) were used to compute nearest neighbor distances (see Materials and methods). Graphs show comparison of VCAM-1 or ICAM-1 nanoclustering based on nearest neighbor profiles from control, CD9-LEL-GST–, and heat-inactivated CD9-LEL-GST–treated samples with statistically comparable numbers of particles. The bar plot represents the mean of the Euclidean distance of the nearest neighbor for the total of n particles in the several images analyzed for each treatment. (C) Clustering rates were computed from the samples in B (see Materials and methods). Clustering parameters: VCAM-1, ${delta}$ = 205 and ${lambda}$ = 2; and ICAM-1, ${delta}$ = 140 and ${lambda}$ = 2. Statistical significance in the figure was based on a Student's t test.

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Figure 8. Scheme of tetraspanin-enriched EAPs and docking structures. (top middle) Scanning electron microscopy image of a peripheral blood lymphocyte interacting with the apical membrane of an endothelial cell under flow conditions. The green square marks a zone of nude membrane containing EAPs as shown at high magnification in the left panel. The red square highlights the endothelial docking structure, as shown at a nanometric scale in the right panel. EAPs are preformed nanoclusters that serve as nucleating units for integrin ligands and their tetraspanin partners, whereas docking structures are microscopic clusters of EAPs organized in microvilli around adherent leukocytes. (bottom middle) Immunofluorescence staining showing the macroscopic appearance of EAPs and docking structures. K562 LFA-1 was adhered (30 min) to TNF- ${alpha}$ –activated HUVECs. Samples were fixed and double stained with anti–PECAM-1 and biotin-conjugated anti–ICAM-1. Confocal stacks were obtained, and an orthogonal maximal projection is displayed. Microscopic-sized clusters of EAPs in this image. (left) Activated endothelial cells were fixed and double stained with 40 nm VCAM-1 and 15-nm ICAM-1 gold particles. The panel shows a representative negative scanning electron microscopy image from the nude apical endothelial plasma membrane. The white asterisks mark the 15-nm anti–ICAM-1 gold particles, and the black dots are the 40-nm anti–VCAM-1 gold particles. The white boxes depict regions of VCAM-1–ICAM-1 heteroclustering, whereas the black box shows an ICAM-1 homoclustering zone. (right) T lymphoblasts were adhered to activated endothelial cells (5 min). Fixed cells were stained with anti–ICAM-1 and 40-nm immunolabeled gold. A representative negative scanning electron microscopy image shows the preferential localization of gold particles at the microvilli of the endothelial docking structure formed around a lymphoblast, where EAPs coalesce.

Nearest neighbor analysis of the spatial pattern of immunogold-labeledICAM-1 and VCAM-1 in the presence of CD9-LEL-GST showed thatreceptor spacing was increased compared with cells not treatedor treated with heat-inactivated peptide (Fig. 7 B). CD9-LEL-GSTalso reduced the percentage of clustered receptors (Fig. 7 C)and partially disrupted their patterned distribution on thecell membrane (Fig. S5 B). CD9-LEL-GST thus seems to competewith endogenous CD9 for binding to itself homophilically andto other tetraspanins and partners, probably by blocking interactionsand imposing steric hindrance, resulting in slower diffusionof EAP components and reduced receptor clustering, which inturn decreases adhesiveness.

Discussion

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Plasma membranes contain different kinds of organized microdomains,all of which play important roles in sensing and processinginformation from the cell exterior. The composition and biophysicalproperties of lipid rafts, which are based on lipid–proteininteractions, have been extensively studied (Kenworthy et al., 2004;Sharma et al., 2004). Much less is known about TEMs, which areprimarily based on protein–protein interactions. Previousmicroscopy analysis of fixed samples and biochemical studiesindicated that a network of specific protein–protein interactionsmay exist between tetraspanins and associated partners (Claas et al., 2001;Nydegger et al., 2006). In this study, we have used advancedanalytical microscopy and single-molecule spectroscopy techniquesto characterize the dynamic features and biophysical propertiesof TEMs in living primary human endothelial cells. Our resultsprovide the first description of tetraspanin microdomains asphysical entities in living cells with dynamic features thatclearly differ from lipid rafts. The transiently transfectedprimary human endothelial cells used are a physiologically relevantcell model that expresses an appropriate repertoire of membranetetraspanins and adhesion receptors. We show that these cellsbear a particular kind of TEM enriched in membrane adhesionreceptors to facilitate leukocyte–endothelial interactionsthat we have termed EAPs (Fig. 8, left). Moreover, we have characterizedthe molecular interactions of CD9 and CD151 tetraspanins andICAM-1 and VCAM-1 adhesion receptors in EAPs, both at nude apicalmembrane and in the docking structures formed between endothelialcells and adhered leukocytes. Our results show that EAPs playan essential role in the spatial organization of the membraneand in the recruitment of ICAM-1 and VCAM-1 toward the contactarea with adherent leukocytes, regulating endothelial cell adhesiveness(Fig. 8, right).

The coclustering of VCAM-1 at docking structures induced byligand engagement of ICAM-1 and vice versa initially suggestedthat these adhesion receptors might interact with each other.However, the FRET–FLIM analysis only showed significantassociation for ICAM-1–ICAM-1, with negligible heterophilicinteractions between ICAM-1 and VCAM-1. The existence of ICAM-1homodimers has been shown before by biochemical approaches (Miller et al., 1995;Reilly et al., 1995). However, BIAcore affinity measurementsrevealed that a single ICAM-1 monomer, not dimeric ICAM-1, representsthe complete, fully competent LFA-1–binding surface (Jun et al., 2001).

The possible role of tetraspanins in the corecruitment of theseadhesion receptors was confirmed by additional FRET–FLIManalysis, which showed homophilic (CD9–CD9) and heterophilic(CD9–CD151) tetraspanin interactions as well as associationof these tetraspanins with the adhesion receptors studied. Interestingly,the molecular interactions among tetraspanins and adhesion receptorsshow significant specificity, with a preferential associationof CD9 with ICAM-1 and of CD151 with VCAM-1. Although full elucidationof the molecular complexity of EAPs requires additional studies,it is very likely that other tetraspanins and adhesion receptorsare contained in these structures, interacting among themselvesand with CD9, CD151, ICAM-1, and VCAM-1. Indeed, our data indicatethat tetraspanin CD81 (Barreiro et al., 2005), CD44, PECAM-1/CD31,JAM-A, ICAM-2, and E-selectin (Fig. S4, B and C; and not depicted)all associate with tetraspanin CD9 and are included in EAPs.However, further studies are required to determine whether thereare distinct kinds of EAPs with defined protein composition.

The diffusional behavior of EAP components was investigatedby combining FRAP and FCS analyses; FRAP provided a qualitativeoverview of EAP diffusion at a microscopic level, and FCS allowedus to accurately quantify diffusion coefficients of EAP componentsat the single-molecule level. FRAP analyses indirectly examinethe diffusion of an overall molecular population within a microscopicarea at nude membrane or at sites of leukocyte anchorage. Therefore,a mixed steady-state molecular population (comprising proteinsbound or unbound to cytoskeleton, coupled to partners, etc.)is considered for each measurement. From FRAP data collectedat nude plasma membrane, we distinguished differences betweenthe immobile fractions of VCAM-1 and ICAM-1. These data indicateimportant differences in the binding of these receptors to corticalcytoskeleton that deserve further analysis. In this regard,it has been described as a direct association of VCAM-1 withezrin and moesin (Barreiro et al., 2002), whereas ICAM-1 interactswith ${alpha}$ -actinin and colocalizes but does not directly associatewith ezrin/radixin/moesin proteins in endothelial cells (Romero et al., 2002;Celli et al., 2006). The higher frequency of transiently immobilizedmolecules in the case of VCAM-1 might produce a decrease inthe average apparent D coefficient for this molecular speciesbecause FRAP calculations are made on an overall molecular population.In fact, these apparent D coefficients fitted by a simple diffusionmodel do not reveal the real diffusional behavior of the receptors,which turned out to be undistinguishable when precisely measuredby single-molecule FCS analysis fitted by an anomalous diffusionmodel. Diffusional analyses by FCS thus complement the FRAPdata.

When we used FRAP to analyze the diffusion of GPI-EGFP, a lipidraft marker widely used in microscopy studies (Varma and Mayor, 1998;Kenworthy et al., 2004), we found that this protein diffusedmuch faster than tetraspanins and other EAP components and showedalmost full fluorescence recovery. In addition, most D coefficientsfor EAP proteins that we have obtained using FCS are much lowerthan those reported for prototypic lipid raft proteins (Lenne et al., 2006).Moreover, GPI-EGFP was unaffected by engagement of integrin-bearingleukocytes, whereas EAP dynamics were altered. In fact, thedelay observed for nonligand-engaged EAP components at dockingstructures could well be the result of their transient interactionwith ligand-immobilized ICAM-1 or VCAM-1. These immobile complexesat docking sites could thus act as physical constraints on themobility of the overall molecular populations analyzed, producinga net restriction in local diffusion. The fact that each adhesionreceptor is less affected than tetraspanins by ligand engagementof the other receptor supports a model of tetraspanin-dependentreceptor coclustering. The higher relative frequency of fastdiffusion by tetraspanins indicates that they are more dynamicallyexchanged between EAPs than are adhesion receptors, furthersupporting their role as the active organizers of these microdomains.Moreover, adhesion receptors exhibit a higher anomality in diffusion,which accounts for their preferential binding to cortical cytoskeletonand transient immobilization compared with tetraspanins (Sala-Valdes et al., 2006).However, further studies are needed to define the residencetime of molecules within EAPs. The mix of endogenous and exogenousprotein populations precludes precise determination of the stoichiometryof submicrometer-sized EAPs. Nonetheless, analysis of brightnessfrom the photon-counting histograms obtained during FCS measurementsrevealed the existence of complexes containing more than onefluorescently labeled molecule. This was also confirmed by fluorescencecross-correlation spectroscopy analysis (unpublished data).

FRET analysis confirmed a degree of specificity inside the preexistentEAPs before leukocyte binding. The preferential interactionsof ICAM-1 with CD9 and VCAM-1 with CD151 are evident in theFRETeff for these pairs. FRET–FLIM analysis shows thatinteractions between tetraspanins and tetraspanin adhesion receptorsare more frequent compared with ICAM-1–ICAM-1 interactions,which supports the central role of tetraspanins in the moleculardynamics of adhesion receptors, strengthening the concept ofEAPs as the basic organizational unit of endothelial adhesionreceptors on the apical plasma membrane.

The regulation of endothelial adhesion receptor avidity by theirinclusion in tetraspanin-enriched EAPs represents a conceptualadvance in the understanding of leukocyte–endotheliuminteractions. Leukocyte integrin activity can be regulated byconformational changes (affinity) and/or clustering at the plasmamembrane (avidity; Luo et al., 2007). In contrast, no regulatorymechanism apart from transcription has been described beforefor endothelial integrin ligands (Collins et al., 1995). Ourdata demonstrate that tetraspanin and adhesion receptor colocalizationdoes indeed reflect highly specific and organized interactionsamong them, forming specialized TEMs (EAPs; Fig. 8, left andmiddle panels illustrate preformed EAPs). Inclusion of ICAM-1and VCAM-1 in EAPs allows homo- and heteroclustering of bothmolecules at the contact area with the adhered leukocyte independentof ligand binding and actin cytoskeleton anchorage (Fig. 8,right and middle panels illustrate a docking structure aroundthe adhered leukocyte). This novel role of tetraspanins seemsto represent a supramolecular level of regulation not previouslyenvisaged for integrin ligands. Additional tetraspanin moleculescould be involved in regulating the molecular dynamics and organizationof EAPs, among them CD81, which is also localized at endothelialdocking structures (Barreiro et al., 2005) and which, in leukocytes,is able to act as a homeostatic avidity facilitator of VLA-4(Feigelson et al., 2003).

The important role of tetraspanins in the molecular dynamicsof EAPs is also supported by our results with the CD9-LEL-GST–blockingpeptide. It seems evident that this CD9-blocking peptide perturbsEAP dynamics by competing with endogenous CD9 for binding topartners and other tetraspanins. As CD9 is the most abundantof the analyzed EAP components, intercalation of CD9-blockingpeptides into EAPs would alter the patterned distribution andmobility of all the proteins embedded within them, providingan explanation for the decrease in receptor-binding strength.EAPs thus appear to endow ICAM-1 and VCAM-1 with the properspatial distribution to exert their adhesive functions, promotingtheir clustering and, therefore, enhancing their avidity fortheir ligands expressed on leukocytes. Supramolecular organizationat the nanoscale has been reported for other receptor molecules,including LFA-1 integrin on leukocytes and the C-lectin receptordendritic cell–specific ICAM-grabbing nonintegrin on dendriticcells (Cairo et al., 2006; Cambi et al., 2006; de Bakker et al., 2007).Whether these molecules are included within TEMs on the leukocyteplasma membrane is an interesting issue that deserves investigation.

With the reagents currently available, it is not possible toaddress whether endothelial receptors undergo conformationalchange because of their interaction with tetraspanins. However,it will be of interest to identify the critical amino acid sequencesin tetraspanins and adhesion receptors that participate in theirlateral interactions. This information would have potentialuse in the future design of therapeutic blocking agents directedat reducing the adhesiveness of endothelial cells toward circulatingleukocytes. Such agents might provide novel therapeutic strategiesfor the treatment of chronic inflammatory and autoimmune diseasesin a more general manner than existing therapies focused onthe inhibition of a particular adhesion pathway mediated bya single integrin ligand.

In summary, our data indicate that EAPs are specialized tetraspanin-basedmembrane microdomains that regulate the avidity of several adhesionreceptors integrated in them, acting as a mechanism to organizemolecules with similar characteristics and functions and therebyfacilitating their coordinated action in rapidly occurring processessuch as extravasation.

Materials and methods

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Abstract
Introduction
Results
Discussion
Materials and methods
References

Cells
HUVECs were cultured as described previously (Barreiro et al., 2002).K562 erythroleukemic cells, which endogenously express β1integrin, were stably transfected with integrin ${alpha}$ 4 to yield cellsexpressing ${alpha}$ 4β1 integrin/VLA-4 or with integrin ${alpha}$ Lβ2/LFA1.K562 clones and T lymphoblasts were cultured as described previously(Barreiro et al., 2002). Integrin inhibitors BIO5192 and BIRT377were provided by Biogen Idec and Boehringer Ingelheim, respectively.

Antibodies
Anti-CD151 (LIA1/1), anti–VE-cadherin (TEA1/31), and anti-CD9(VJ1/20) mAbs have been described previously (Yanez-Mo et al., 1998).P8B1 (anti–VCAM-1), MEM-111 and Hu5/3 (anti–ICAM-1),and 8C3 (anti-CD151) mAbs were provided by E.A. Wayner (FredHutchinson Cancer Research Center, Seattle, WA), V. Horejsi(Academy of Sciences of the Czech Republic, Prague, Czech Republic),F.W. Luscinskas (Brigham and Women's Hospital, Harvard MedicalSchool, Boston, MA), and K. Sekiguchi (Osaka University, Osaka,Japan), respectively. Anticaveolin antibody was purchased fromSigma-Aldrich.

Recombinant DNA constructs and proteins and transfections
EGFP-tagged ICAM-1, VCAM-1, CD9, and CD151 have been previouslydescribed (Barreiro et al., 2002, 2005; Garcia-Lopez et al., 2005).The construct encoding VCAM ${Delta}$ Cyt, a C-terminally truncated VCAM-1protein in which the first cytoplasmic charged residue is retainedto ensure proper membrane insertion, was generated by PCR usingthe human VCAM-1 cDNA as template and CTCGAGTCTCATCACGACAGCAACand CTATCTTGCAAAGTAAATTATC as 5' and 3' primers, respectively.The PCR product containing a stop codon at position 1722 wascloned into pcDNA3.1/V5-His-TOPO (Invitrogen), and correct expressionof VCAM ${Delta}$ Cyt at the plasma membrane was tested. The equivalentICAM-1–tailless construct, but fused to EGFP, was providedby F.W. Luscinskas. For FCS and FRET–FLIM experiments,monomeric green and red variants of ICAM-1, VCAM-1, CD9, andCD151 were generated. mEGFP constructs were obtained by A206Kpoint mutation (Zacharias et al., 2002; Zhang et al., 2002)using the Quick Mutagenesis kit (Stratagene). The mRFP1 variantswere generated by subcloning the corresponding EGFP constructsinto an mRFP1 vector provided by R.Y. Tsien (University of California,San Diego, La Jolla, CA; Campbell et al., 2002). The GPI-EGFPconstruct was provided by M.A. del Pozo (Centro Nacional deInvestigaciones Cardiovasculares, Madrid, Spain). The LEL ofGST-fused human CD9 wild type was obtained as described previously(Barreiro et al., 2005).

HUVECs were transiently transfected by electroporation (Barreiro et al., 2005)or with lipofectin (Invitrogen) according to the manufacturer'sprotocol. Transfected cells were grown to confluence for 24–48h on 20 µg/ml fibronectin (FN; Sigma-Aldrich)-precoatedglass coverslips or glass-bottomed dishes (WillCo Wells). Activationwith 20 ng/ml TNF- ${alpha}$ was performed for 20 h unless indicated otherwise.

Cell adhesion, immunofluorescence, and confocal microscopy
Confluent HUVECs on FN-coated coverslips were activated withTNF- ${alpha}$ . Then, K562 clones or T lymphoblasts were added. Adhesionof K562 LFA-1 to activated HUVEC monolayers was assayed in thepresence of 1 mM Mn²⁺ to activate integrins. Where indicated,T lymphoblasts were treated with 10 µg/ml BIO5192 or 10µM BIRT377 for 5 min before adhesion assay. After incubation,samples were washed and fixed in 4% paraformaldehyde and processedfor immunofluorescence (Yanez-Mo et al., 1998). A series ofoptical sections were obtained at 21°C with a confocal laser-scanningunit (TCS-SP5; Leica) coupled to a microscope (DMI6000; Leica)using an HCX PL APO CS 63x NA 1.3 glycerol immersion objective.Images were analyzed with confocal software (Leica).

Bead adhesion
TNF- ${alpha}$ –activated HUVECs were incubated for 30 min with Dynabeadscoated with antitetraspanin, anti–VCAM-1, or anti–VE-cadherinmAb (Invitrogen) and were fixed and stained with biotinylatedanti–ICAM-1 mAb.

Sucrose density gradient fractionation
Confluent TNF- ${alpha}$ –activated HUVECs were rinsed with PBS andlysed for 20 min in 250 µl of 25 mM Tris-HCl, pH 7.5,150 mM NaCl, and 1% Brij96 at 4°C. The cell lysate was homogenizedby passing the sample through a 22-gauge needle. The extractwas brought to 40% sucrose (wt/wt) in a final volume of 4 mland placed at the bottom of an 8-ml 5–30% linear sucrosegradient. Gradients were ultracentrifuged to equilibrium for20 h at 39,000 rpm at 4°C in a rotor (SW41; Beckman Coulter).1-ml fractions were harvested from the bottom of the tube. Aliquotsfrom each fraction were subjected to SDS-PAGE and Western blottingwith appropriate antibodies.

FRAP
Cells transfected with EGFP fusion proteins (VCAM-1–,ICAM-1–, CD9-, CD151-, ICAM-1 ${Delta}$ Cyt–, and GPI-EGFP)were plated on FN-coated coverslips. After 24 h, cells werestimulated with TNF- ${alpha}$ , and FRAP experiments were performed within48 h of plating. To analyze FRAP at the endothelial dockingstructure, an adhesion assay was conducted using K562 ${alpha}$ 4 or LFA-1.Live cell microscopy was performed with a confocal laser-scanningunit (TCS-SP2; Leica) coupled to a microscope (DMIRBE; Leica)using the 488-nm Ar laser line and an HCX PL APO lambda blue63x NA 1.4 oil immersion objective. During observation, plateswere maintained at 37°C in a 5% CO₂ atmosphere using anincubation system (LaCon GbR/PeCon GmbH). Laser power for bleachingwas maximal but was reduced to 10% for imaging. 10 single-sectionprebleach images were acquired followed by three iterative bleachpulses of 1.7 s each. 10 single-section images were then collectedat 1.7-s intervals followed by 20 images every 10 s and finally15 images every 30 s for a total experimental time of $~$ 650 s.

Fluorescence recovery in the bleached region was measured asaverage signal intensity. All recovery curves were generatedfrom background-subtracted and bleaching-corrected images. Moreover,the fluorescence signal was normalized to the prebleach signalin the same region of interest.

The mobile fraction (R) corresponds to the final value of therecovered fluorescence intensity, and the immobile fractionis obtained as 1 – R. The half-time of recovery is thetime from bleaching to the time when the fluorescence intensityis half of the final recovered intensity. All three variableswere directly obtained from the normalized mean fluorescencerecovery curves.

The averaged recoveries were fitted with the equation

Formula
where F₀ = fluorescence intensity atthe first time point after bleach, F⁰ = fluorescence intensitybefore bleach, R = mobile fraction, and t_1/2 = half recoverytime. Apparent diffusion coefficients from averaged recoveryhalf-times were derived using a simple Brownian diffusion model.Averaged immobile fractions (1 – R) were derived fromaveraged fitted curves.

The possible perturbation of membrane dynamics that might resultfrom differential exogenous expression of tagged proteins wasovercome in FRAP experiments by making a large number of measurementsin several batches of transiently transfected primary endothelialcells and exhaustive statistical analysis. To assess the statisticalsignificance of differences between FRAP recovery curves, wederived a t test analysis on the average fitted curves for eachprotein in each condition.

Hetero-FRET by donor FLIM in intact living cells
HUVECs were single transfected with mEGFP standards or cotransfectedwith mEGFP–mRFP1 pairs and seeded on FN-coated glass-bottomeddishes. After 24 h and without TNF- ${alpha}$ treatment, the culture mediumwas replaced with a phenol red–free medium for optimalimage acquisition. FLIM was performed using the digital frequencydomain method and the new FLIM box, recently described in detail(Colyer et al., 2008), which were implemented at the Laboratoryof Fluorescence Dynamics (University of California, Irvine,Irvine, CA) on a commercial confocal system (FluoView 1000;Olympus). Excitation was provided by a modulated 471-nm diodelaser (ISS, Inc.). A 40x 1.2 NA water immersion objective (CarlZeiss, Inc.) was used. Data were acquired and processed by SimFCSsoftware (developed at the Laboratory of Fluorescence Dynamics).The scan area (256 x 256 pixels) corresponds to 32 x 32 µm².Before cell measurements, concentrated fluorescein at pH 9.0was measured. Fluorescein lifetime (4.04 ns) was determinedseparately in a fluorometer (PC1; ISS, Inc.).

The FLIM analysis for deriving FRETeff was performed using thephasor FLIM method recently described (Caiolfa et al., 2007;Digman et al., 2008) and commented on (Wouters and Esposito, 2008).The contour plots associated with each image show the entiredistribution of the donor fluorescence lifetimes in the image.The distribution was obtained by converting the multiexponentialfluorescence decays acquired in each pixel into the graphicalrepresentation of a phasor. In brief, the phasor transformationdoes not assume any fitting model for fluorescence lifetimedecays. It simply expresses the overall decay in each pixelin terms of a point of (s, g) polar coordinates in the so-called"universal circle" (Redford and Clegg, 2005). In each plot,the green line represents the position of all phasors having0% FRETeff and variable cellular autofluorescence. These pointswere derived from the lifetime analysis in cells expressingonly the donor molecules, whereas untransfected cells were usedas a control for autofluorescence. Once the phasors of the unquencheddonors and of the cell autofluorescence (green line in the phasorplots) are known, the FRET trajectory in the phasor plot canbe calculated according to the classical relationship FRETeff= [1 – ( ${tau}$ _{donor–acceptor})/ ${tau}$ _donor] and define the meanphasors of mEGFP constructs quenched by 50% FRET in the presenceof the acceptor and with different contributions from cell autofluorescence(red line in all phasor plots). In all of our experiments, phasorsresulting from any combination of unquenched donors, FRET-quencheddonors, and cell autofluorescence have been found within thearea delimited by the green and red lines in the phasor plots.The localization and distribution of the phasors of mEGFP constructswere not affected by the kind of protein linked to the fluorophoreor by the cells in which they were expressed. Endogenous untaggedproteins expressed in our cell model may interfere with FRET.To minimize interaction between endogenously and exogenouslyexpressed tagged proteins in FLIM analyses, quantificationswere performed in resting endothelial cells, where tetraspaninexpression is unaltered, ICAM-1 levels are low, and VCAM-1 plasmamembrane expression is negligible. Given that endogenous CD151and CD9 expression is much higher than ICAM-1 in resting endothelialcells, FRETeff from measurements involving tetraspanin proteinsmay be underestimated. Moreover, because CD9, CD151, and ICAM-1can homodimerize, the association of two green or red molecularspecies makes hetero-FRET events even more improbable. To substantiatethe experimental data on the absence of ICAM-1–VCAM-1heterodimers, ICAM-1 or VCAM-1 was used indistinctly as a donorin FRET–FLIM experiments.

FCS
HUVECs were transiently single or double transfected as forFLIM and treated either with growth factors (resting conditions)or with 20 ng/ml TNF- ${alpha}$ (activated conditions). Intensity fluctuationswere recorded on the described setup (Caiolfa et al., 2007)based on a dual-channel confocal fluorescence correlation spectrometer(ALBA; ISS, Inc.) equipped with avalanche photodiodes (SPCM-AQR-15;PerkinElmer) and interfaced to an inverted microscope (TE300;Nikon). A 60x 1.2 NA plan Apo water immersion objective wasused. Excitation was provided at 488 nm by a tunable Ar ionlaser (Melles Griot) and at 594 nm by a HeNe laser (Melles Griot).Calibration and data collection were performed according tothe procedures previously described (Caiolfa et al., 2007).

The ACFs were best fitted using the anomalous diffusion model(Banks and Fradin, 2005), according to the equation

Formula
where N is the average number of moleculesin the excitation volume, ${tau}$ is the increment of time, ${tau}$ _D is thediffusion time, and ${alpha}$ is the anomality coefficient. Accordingly,the diffusion coefficient (D) is derived from the relationshipD = ${omega}$ ²/4 ${tau}$ .

In FCS experiments, endogenous proteins were in excess comparedwith corresponding fluorescent-tagged variants, minimizing artifactsas a result of differences in local concentrations of the latter.FCS experiments were performed both either in resting or inTNF- ${alpha}$ –activated HUVECs, not finding statistically significantdifferences in diffusion between the treatments.

Scanning electron microscopy
Endothelial monolayers were activated with TNF- ${alpha}$ in the absenceor presence of 250 µg/ml of active or heat-inactivated(5 min at 90°C) CD9-LEL-GST peptide. T lymphoblasts wereadded when indicated. Cells were fixed in 2% paraformaldehyde/PBSand immunolabeled with P8B1 (anti–VCAM-1), Hu5/3 (anti–ICAM-1),or biotinylated MEM-111 (anti–ICAM-1) as primary antibodiesand 40 nm of gold-coupled anti–mouse antibody or 15 nmof gold-coupled streptavidin (British Biocell International)as detection reagents. Samples were fixed in 2.5% glutaraldehyde/PBS,sequentially dehydrated, critical point dried, and covered witha 5-nm carbon layer. Images were obtained with a scanning electronmicroscope (S-4100; Hitachi) at an acceleration voltage of 12kV and a 4-mm working distance. Images were processed with Metamorphsoftware (MDS Analytical Technologies).

Nearest neighbor distances and k nearest neighbor (knn) profiles
For each image, we computed the knn distance vector that containsin its i^th position the mean of the distances between objectsand their i^th nearest neighbor. Comparison of knn profiles allowsus to establish similarities and discrepancies between differenttreatments in terms of aggregation and dispersion of the cloudsof points in the image. The knn distances were assumed to beindependent realizations of a normal distribution (the nullhypothesis of normality could not be rejected using a Shapiro-Wilktest). Because the knn profile might be dependent on the numberof objects, the analysis was performed using images that containeda similar number of objects. Nearest neighbor analysis was evaluatedby using a custom-written software based on R language (R DevelopmentCore Team [2006]. R: a language and environment for statisticalcomputing. R Foundation for Statistical Computing, Vienna, Austria.ISBN 3-900051-07-0. http://www.R-project.org).

Cluster and statistical significance
The dissimilarities between clustered point patterns for differentimages were established in terms of the proportion of aggregation,defined for a given image, I_v, as the proportion of gold particles,p_v, that are included in any cluster identified in I_v. To identifythe cluster pattern of I_v, a cluster agglomerative algorithmbased on Euclidean distances between points was developed andimplemented in R language. In the way that the clusters aredefined, the minimum size of the cluster is ${lambda}$ + 1. The algorithmallows the formation of clusters of any shape, retaining pointsthat are close enough to each other to be considered as aggregated.This minimum distance at aggregation is set by the parameter ${delta}$ . The criteria to select different values for ${delta}$ and ${lambda}$ parameterswere based on the differential number of particles in the imagesused for the various analyses. For every image, I_v, and corresponding ${delta}$ and ${lambda}$ , a point cluster pattern is identified, and the proportionof points, p_v, that are included in any cluster is computed.Then, the differences between families of images can be establishedin terms of the different proportions, p_v. The statistical significanceamong families of images was assessed with a Student's t testusing the asin transformation of p_v as Formula .

Spatial randomness
To statistically assess whether the points in a given imageare located in random positions, we followed the method fortesting spatial randomness previously described (Manly, 1997).We computed the knn vector for each observed image. The nullhypothesis knn vector was generated by simulating 100 sets ofimages with points located at random positions, consideringthat all points have the same probability of being situatedanywhere in the image and are independent of each other. Randomdistribution of points is expected to produce greater knn values,so the significance level was defined for every i^th knn distanceas the proportion of values in the null distribution that weregreater than or equal to the observed value. Spatial randomnessanalysis was evaluated by using a custom-written software basedon R language.

Statistical analysis
All statistical analyses (one-sided or two-sided t tests andanalysis of variance with Tukey's Honest Significant Difference)were performed with R language or Prism software (GraphPad Software,Inc.).

Online supplemental material
Fig. S1 shows controls for FRET–FLIM experiments and studyof the specificity of molecular interactions within the EAPs.Fig. S2 shows involvement of tetraspanin microdomains in thecorecruitment of endothelial adhesion receptors. Fig. S3 showsa comparison of dynamic behaviors of EAP constituents and cytoplasmictail–truncated ICAM-1 mutant at nude plasma membrane andat docking structures. Fig. S4 shows the relative frequencyhistograms for D and ${alpha}$ coefficients obtained by FCS and studyof other adhesion receptors included in EAP. Fig. S5 shows examplesof receptor clustering patterns and spatial randomness analysis.Table S1 shows the derived apparent D coefficients from Fig. 3 A.Table S2 shows the statistical analysis on fluorescence recoverycurves from Fig. 3 and Fig. S3. Table S3 shows the statisticalanalysis on the diffusion coefficients from Figs. 4 and 6. Onlinesupplemental material is available at http://www.jcb.org/cgi/content/full/jcb.200805076/DC1.

Acknowledgments

We thank N. Cortadellas, R. Fontarnau, E. Prats, A. Domínguez(Serveis Cientificotècnics de la Universitat de Barcelona),M. Sala-Valdés, A. Batista, D. Megías, R. Samaniego(Hospital Gregorio Marañón), G. Malengo, R. Colyer,C. Lee, and T.L. Hazlett for technical assistance and S. Barlettfor critical reading of the manuscript.

This work was funded by Salud grant SAF2008-02635, BiologíaFundamental grant 2005-08435/Biología Molecular y Celular,Ayuda a la Investigación Básica 2002 FundaciónJuan March, and the Lilly Foundation (to F. Sanchez-Madrid),National Institutes of Health grant P41-RRO3155 (to E. Gratton),European Union grant LSHG-CT-2003-502935 (to O. Barreiro), andRed Temática de Investigación Cooperativa en EnfermedadesCardiovasculares grant RD06/0014-0030. The Centro Nacional deInvestigaciones Cardiovasculares (CNIC) is supported by theSpanish Ministry of Health and Consumer Affairs and the Pro-CNICFoundation.

Submitted: 14 May 2008

Accepted: 9 September 2008

References

Top
Abstract
Introduction
Results
Discussion
Materials and methods
References

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