Mutagenesis of the Phosphatidylinositol 4,5-Bisphosphate (Pip2) Binding Site in the Nh2-Terminal Domain of Ezrin Correlates with Its Altered Cellular Distribution

doi:10.1083/jcb.151.5.1067

Published online 27 November 2000. doi:10.1083/jcb.151.5.1067

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© The Rockefeller University Press, 0021-9525/2000//1067 $5.00
The Journal of Cell Biology, Volume 151, Number 5, , 2000 1067-1080

Original Article

Mutagenesis of the Phosphatidylinositol 4,5-Bisphosphate (Pip₂) Binding Site in the Nh₂-Terminal Domain of Ezrin Correlates with Its Altered Cellular Distribution

Cécile Barret^a, Christian Roy^a, Philippe Montcourrier^a, Paul Mangeat^a, and Verena Niggli^b

^a Dynamique Moléculaire des Interactions Membranaires, Université Montpellier II, Unité Mixte de Recherche (UMR) Centre National de la Recherche Scientifique 5539, 34095, Montpellier Cedex 5, France
^b Department of Pathology, University of Bern, 3010-Bern, Switzerland
Dept. of Pathology, University of Bern, Murtenstr. 31, P.O. Box 62, CH-3010 Bern, Switzerland.41 31 381 34 1241 31 632 87 44

The cytoskeleton-membrane linker protein ezrin has been shownto associate with phosphatidyl-inositol 4,5-bisphosphate (PIP₂)-containingliposomes via its NH₂-terminal domain. Using internal deletionsand COOH-terminal truncations, determinants of PIP₂ bindingwere located to amino acids 12–115 and 233–310.Both regions contain a KK(X)_nK/RK motif conserved in the ezrin/radixin/moesinfamily. K/N mutations of residues 253 and 254 or 262 and 263did not affect cosedimentation of ezrin 1-333 with PIP₂-containingliposomes, but their combination almost completely abolishedthe capacity for interaction. Similarly, double mutation ofLys 63, 64 to Asn only partially reduced lipid interaction,but combined with the double mutation K253N, K254N, the interactionof PIP₂ with ezrin 1-333 was strongly inhibited. Similar datawere obtained with full-length ezrin. When residues 253, 254,262, and 263 were mutated in full-length ezrin, the in vitrointeraction with the cytoplasmic tail of CD44 was not impairedbut was no longer PIP₂ dependent. This construct was also expressedin COS1 and A431 cells. Unlike wild-type ezrin, it was not anymore localized to dorsal actin-rich structures, but redistributedto the cytoplasm without strongly affecting the actin-rich structures.We have thus identified determinants of the PIP₂ binding sitein ezrin whose mutagenesis correlates with an altered cellularlocalization.

Key Words: cytoskeleton • actin • CD44 • A431 cells • COS1 cells

Introduction

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Members of the ezrin/radixin/moesin (ERM) family and the relatedtumor suppressor merlin are part of the protein 4.1 superfamily.They are defined as cytoskeleton-membrane linkers (for reviews,see Bretscher 1999; Mangeat et al. 1999). The anchorage of theERM family to the plasma membrane occurs in different ways.Indirect binding of ERM to different proteins with several transmembranousdomains, such as the cystic fibrosis transmembrane conductanceregulator (Short et al. 1998) or the Na⁺/H⁺ antiporter (Murthy et al. 1998;Yun et al. 1998), involves an adaptor protein such as EBP 50(Reczek et al. 1997). ERM can also be linked to the cytoplasmictail of membrane proteins with a single transmembranous domainsuch as CD43, CD44, I-CAM 1, I-CAM 2, and I-CAM 3. These interactionsappear to be facilitated by the phospholipid phosphatidylinositol4,5-bisphosphate (PIP₂) (Hirao et al. 1996; Serrador et al. 1997;Yonemura et al. 1998). It is not clear whether this dependencyis due to a requirement for PIP₂ of the transmembranous proteinor of the ERM itself (Hirao et al. 1996; Heiska et al. 1998).Some studies suggest that PIP₂ could help unmask cryptic bindingsites in ERM. PIP₂ could thus be involved in the activationprocess of the ERM, switching the inactive "dormant" moleculeto an activated state (Matsui et al. 1999; Nakamura et al. 1999).ERM could also directly interact with PIP₂-containing phospholipidbilayers (Niggli et al. 1995; Hirao et al. 1996; Heiska et al. 1998).Thus, the direct association of ezrin with PIP₂ and also withthe p85 subunit of the phosphatidylinositol 3-kinase may providea mechanism to anchor the enzyme in proximity to its substrate(Gautreau et al. 1999).

Talin, another member of the 4.1 family, has been shown to insertinto bilayers of liposomes containing acidic phospholipids usinghydrophobic photolabeling. Lipid interaction was attributedto a 47 kD NH₂-terminal domain (Niggli et al. 1994). Similarly,we have demonstrated that the NH₂-terminal domain of ezrin (aminoacids 1–309) was necessary and sufficient for interactionwith PIP₂-containing liposomes. We showed that ezrin binds preferentiallyto liposomes containing PIP₂ as compared with other phospholipidssuch as phosphatidylserine, and that this interaction occursat physiological ionic strength. Under these conditions, ezrindiscriminates between PIP₂, phosphatidylinositol 4-monophosphate,and phosphatidylinositol (Niggli et al. 1995).

In this study, we further characterized the interaction of theNH₂-terminal domain of ezrin with PIP₂-containing liposomesby truncation and site-directed mutagenesis. Amino acids thatare involved in binding to PIP₂-containing liposomes have beenidentified. They are located in two distinct regions of thisdomain. Similarly, PIP₂ interaction was abolished when the samecritical mutations were introduced in the full-length ezrinmolecule. Although the PIP₂-independent interaction of ezrinwith proteins was not affected, its intracellular localizationwas drastically changed. Expression of the mutated first 310amino acids of ezrin led to a loss of the ability of the NH₂-terminaldomain of ezrin to promote cell extensions (Martin et al. 1997;Amieva et al. 1999).

Materials and Methods

Top
Abstract
Introduction
Materials and Methods
Results
Discussion
References

Site-directed Mutagenesis
The preparation of constructs with internal deletions as wellwith COOH-terminal truncations has already been described (Roy et al. 1997).The numbering of the amino acid sequence of ezrin includes thefirst methionine, corresponding to the protein expressed inbacteria. The quick change site-directed mutagenesis kit fromStratagene was used. The changed bases are underlined. The oligonucleotides(sense) (5'–3') used for introducing the K63N mutationin pGEX-2T ezrin 1-586 were GGCTGAAGCTGGATAATAAGGTGTCTGCCCAGG(12 cycles, 95°C, 30 s; 55°C, 1 min; 68°C, 15 min)and GGAACATCTCTTTCAATGACAATAATTTTGTCATTAAACCC for K253N, K254N(16 cycles, 95°C, 30 s; 50°C, 1 min; 68°C, 14 min).The following oligonucleotides were used to mutate the pGEX-2Tezrin 1-333: GGCTGAAGCTGGATAATAATGTGTCTGCCCAGGAGG (K63N, K64N),GTCATTAAACCCATCGACAATAATGCACCTGACTTT-GTG (K262N, K263N) andGCTGGATAAGAAGGTGGCTGCCCAGGAGGTCAGG (S66A). For this later series,14 cycles were performed (95°C, 30 s; 55°C, 1 min; 68°C,12 min). The K63N mutation was introduced in the pGEX-2T ezrin1-333 vector by excising the XmaI/AatII fragment of pGEX ezrin1-333 and cloning this fragment in the pGEX-2T ezrin 1-586 K63Ndeleted from its XmaI/AatII fragment. The K253N, K254N, K262N,and K263N mutations were introduced in the pGEX-2T ezrin 1-333K63,64N vector after purification of the inserts Cfr9I/KpnIcontaining the indicated mutations. The K253N, K254N, K262N,and K263N mutations were introduced in pGEX-2T ezrin 1-586 afterexcising the Asp718/Cfr9I fragment from pGEX-2T ezrin 1-333and ligation in the similarly cut recipient vector. The K63N,K64N, K253N, K254N, K262N, and K263N mutations from pGEX-2Tezrin 1-333 K63N, K64N, K253N, K254N, K262N, and K263N wereintroduced in pGEX-2T ezrin 1-586 after excising the NcoI/Cfr9Ifragment. For transfection experiments, the K253N, K254N, K262N,and K263N mutations were introduced into the pCB6 vesicularstomatitis virus glycoprotein G (VSV-G)–tagged plasmidencoding for the wild-type ezrin, a kind gift of Dr. MoniqueArpin (Curie Institute, Paris, France) (Algrain et al. 1993).The similarly mutated ezrin 1-310 tagged with the VSV-G peptidewas derived from the above construct using appropriate restrictionenzymes. All constructs were sequenced using the T7 Sequenaseversion 2.0 (Amersham Pharmacia Biotech).

Plasmid (pSR CD44) encoding the full-length CD44 protein wasobtained from R. Lamb (MRC, London, UK). The region coding forthe cytoplasmic tail of the protein (amino acids 291–360)was amplified by polymerase chain reaction using the Pfu polymerase(Stratagene) and subcloned in the BamHI/EcoRI site of the pGEX-2Tvector. The vector encoding the amino acids 329–358 ofEBP50 in fusion with glutathione S-transferase (GST) was providedby A. Bretscher (Cornell University, Ithaca, NY).

Protein Expression and Purification
After an overnight culture in LB medium (Luria Broth) at 37°C,protein expression was induced with 0.5 mM isopropyl β-D-thiogalactopyranosidefor 45 min (NH₂-terminal constructs) or 1 h (full-length ezrin).The following conditions are given for a 1 liter culture scaleand all steps were performed at 4°C. Bacteria were pelletedat 5,000 g, resuspended in 15 ml PBS containing protease inhibitors(Complete; Boehringer) and sonicated three times for 2 min withpulses for 50% of the time. The sonicated bacteria were dilutedto 30 ml with PBS, centrifuged for 30 min at 17,000 g, and thesupernatant was diluted to 50 ml. Glutathione-agarose (1.5 mlgel) was added to the supernatant and left on a rotary shaker.For NH₂-terminal constructs, fusion proteins were allowed toadsorb on the gel overnight. The slurry was then poured in acolumn and washed with PBS. Further washing of the column wascarried out with Tris-HCl, pH 7.4, and 100 mM NaCl. Nucleicacids bound on the fusion protein were then degraded by adding150 U benzonase and 50 µg RNase after an incubation atroom temperature for 90 min. After washing the column, the samebuffer, but containing 2.5 mM CaCl₂, was added together with5 IU thrombin and the cleavage was allowed to process for 90min. The protein was recovered in the eluate and the thrombinaction was stopped with para-aminobenzamidine beads (Sigma-Aldrich).

For full-length ezrin constructs, the fusion proteins were allowedto adsorb on the glutathione agarose gel for 2 h. The gels werepoured in a column and washed sequentially with PBS and Tris-HCl,pH 8.0. After glutathione elution (10 mM), full-length ezrinwas dialyzed overnight against a buffer containing 20 mM Tris-HCl,pH 7.4, 0.1 mM EDTA, and 15 mM mercaptoethanol. 50 mM NaCl and2.5 mM CaCl₂ were added to the dialysate. Digestion with thrombinwas allowed to proceed for 90 min at 37°C. Samples werediluted twice with FPLC buffer A (25 mM MES, pH 6.2, 20 mM NaCl,and 0.01% mercaptoethanol). Elution from the mono-Q column ofwild-type ezrin as well as of ezrin with mutations K253N, K254N,K262N, and K263N occurred at 65 mM NaCl, that of ezrin withmutations K63N, K64N, K253N, K254N, K262N, and K263N at 85 mMNaCl. All proteins were stored at 4°C in the presence of0.05% NaN₃.

The cytoplasmic tail of CD44 and the EBP50 fragment were obtainedusing procedures similar to that used for ezrin full-lengthconstructs, except that the fusion proteins were not elutedfrom the glutathione agarose gel. The adsorbed GST-CD44 proteinwas kept at 4°C and used within 24 h after preparation.

Determination of Protein Concentration
The UV spectra were recorded and the protein concentration wascalculated from the absorption coefficients at 220 and 280 nm.The Bradford assay (Bradford 1976) did not allow a quantitativeestimation of the protein content because of the peculiar aminoacid composition of the NH₂-terminal constructs; this assaywas used only for comparing relative amounts of the protein.

Phospholipids
Phosphatidylcholine (PC) and PIP₂ were obtained from Lipid Products.For some experiments, PIP₂ was also obtained from Sigma-Aldrich.No difference was detected between the two products.

Cosedimentation of Ezrin and Ezrin Constructs with Lipid Vesicles
Analysis of protein–lipid interactions by cosedimentationof proteins with large multilamellar liposomes has been documentedin detail elsewhere (Niggli et al. 1994). Large, multilamellarliposomes were prepared from PC and PIP₂ in a buffer containing20 mM Hepes, pH 7.4, 0.2 mM EGTA as described (Niggli et al. 1995).Ezrin, and ezrin constructs (dialyzed after purification againsta buffer containing 20 mM Tris/HCl, pH 7.4, 0.1 mM EDTA, 15mM mercaptoethanol) were centrifuged before the experimentsfor 20 min at 20,000 g, 4°C, followed by protein determination.Proteins were subsequently incubated for 15 min at 22°Cin the presence of 130 mM KCl and in the absence of liposomes,followed by a further incubation in the absence or presenceof liposomes for 15 min. In part of the experiments, proteinswere not dialyzed after purification, and lipid interactionsof ezrin constructs were assayed directly in the buffer in whichthe protein was recovered after column chromatography. In thiscase, EGTA was added to the protein solution to neutralize Ca²⁺,which interferes with the liposome cosedimentation assay (seeResults). This resulted in a protein solution containing (mM):50 Tris/HCl, pH 7.4, 100 NaCl, 1.25 CaCl₂, 2.8 EGTA, and 0.05%NaN₃. No difference in lipid interaction of the same preparationof wild-type ezrin domains could be detected when proteins wereadded to the lipids before or after dialysis provided that Ca²⁺was neutralized by EGTA. Proteins were kept under nitrogen duringincubation with lipids. Final concentrations of protein were27.5–55 µg/ml and of lipid 0.5 mg/ml. The fractionof wild-type ezrin (1-333) cosedimenting with PIP₂-containingliposomes was similar for both protein concentrations. The mixtureswere subsequently centrifuged for 30 min at 100,000 g, 4°C.The pellets were solubilized in 50–100 µl samplebuffer (Niggli et al. 1994). The supernatants were mixed withthe corresponding amount of the threefold concentrated samplebuffer. After heating the samples for 5–10 min at 95°C,they were applied to SDS-polyacrylamide gradient gels (Niggli et al. 1995).The amount of protein present in pellets and supernatants wasquantified by scanning the bands of the Coomassie blue-stainedgels. The amount of ezrin sedimented in the absence of liposomeswas always subtracted from that sedimenting in the presenceof lipid (= specific cosedimentation). In a series of representativeexperiments, 22 ± 8% (n = 10) of wild-type ezrin 1-333sedimented in the absence of lipid. Comparable data were obtainedfor mutated proteins. The amount of wild-type ezrin 1-333 recoveredin the pellet was increased in the presence of liposomes containing20% PIP₂ to 77 ± 9% (n = 10) of total protein. The specificcosedimentation of wild-type ezrin 1-333 corresponds thus to300 ± 160% (n = 10) of the amount of protein sedimentingin the absence of lipid. Some variations were observed in theextent of cosedimentation with liposomes when comparing differentprotein preparations, possibly due to variable denaturationduring purification and/or storage.

The data are given as mean ± SD of n experiments. Differencesbetween data were analyzed with the Student's t test for paireddata, with a P < 0.05 considered significant.

Interaction of Ezrin with the Cytoplasmic Tail of CD44
GST or GST-CD44 (5 µg, 10 µl) bound to glutathioneagarose beads were equilibrated in the reaction buffer (25 mMTris-HCl, pH 7.4, 150 mM KCl, 1 mM MgCl₂, and 1 mM DTT). PIP₂was added in micellar form (Hirao et al. 1996). Full-lengthwild-type ezrin or ezrin K253N, K254N, K262N, and K263N (3.5µg, 1 µM) were incubated in a final volume of 50µl with beads for 1 h at room temperature. Beads werethen washed three times with 500 µl buffer at 4°C.After the final wash, 20 mM glutathione was added for 1 h. Aliquotsof the supernatant were then analyzed by SDS-PAGE and Westernblotting for the presence of ezrin using procedures describedin Roy et al. 1997.

Homotypic Interaction Assay
Wild-type ezrin 1-586 was coated in wells of a microtiter plateand residual binding sites saturated with 2% bovine serum albumin(Roy et al. 1997). Ezrin 1-333 constructs (0.5 µM each)were then added in buffer (20 mM Tris-HCl, pH 7.4, 5 mM MgCl₂,100 mM KCl, and 0.2 mM dithiothreitol). After 1 h of incubation,wells were rinsed with the same buffer and samples were processedfor SDS-PAGE analysis and Western blotting.

Intrinsic Tryptophane Fluorescence Measurements
Fluorescence spectra were recorded with an Aminco-Bowman Series2 luminescence spectrometer at 30°C. Protein samples wereincubated in 50 mM Tris-HCl, pH 7.4, 100 mM NaCl. The tryptophaneemission fluorescence spectrum was recorded by excitation at292 nm. Both excitation and emission beams were set at 2-nmbandwidth.

Cell Culture and Transient Transfection
COS1 and A431 cells were maintained in DMEM containing 10% FBS.Cells were seeded 24 h before transfection at a density of 200,000cells per 35-mm dish. Transfection of plasmids into COS1 cellswas carried out by using Effectene (Qiagen) as recommended bythe manufacturer (0.4 µg plasmid in 100 µl EC bufferand 3.2 µl enhancer for 5 min at room temperature, thenaddition of 10 µl Effectene followed by contact with cells10 min later). Superfect (QIAGEN) was used for transfectionof A431 cells: 2 µg DNA was mixed with 100 µl DMEMand 10 µl Superfect for 5 min at room temperature beforeaddition to cells. The medium was changed 3 h later. Immunofluorescenceand cell fractionation were carried out 30 and 42 h after transfection,respectively.

Cell Fractionation
The cells were washed twice with PBS with 0.5 mM MgCl₂ and 2mM CaCl₂. Lysis buffer [(mM) 10 Hepes, pH 7.4, 2.5 MgCl₂, 1EGTA, 1 EDTA, 1 vanadate, 10 NaF, 0.1 PMSF, 100 µg/mlCHAPS, 10% glycerol, and a cocktail of antiproteases] was added(300 µl per 35-mm dish). Cells were scraped off with arubber policeman and homogenized by 20 strikes in a Dounce homogenizer(pestle B). The homogenates were centrifuged at 25,000 g for30 min at room temperature. The supernatant corresponds to thecytosolic fraction. The pellet was resuspended in 300 µlbuffer A [(mM) 50 MES, pH 6.4, 2.5 MgCl₂, 1 EGTA, 1 vanadate,10 NaF, 10% glycerol, 0.5% Triton X-100, antiprotease cocktail]and centrifuged at 18,000 g for 15 min at 4°C. The pellet(Triton X-100 nonextractable material) was resuspended in 300µl buffer A and sonicated. Fractions (30 µl) wereapplied to SDS-polyacrylamide gels and immunoblotted with P5D4anti–VSV-G mAb or anti-ezrin antibodies (Andréoli et al. 1994;Roy et al. 1997). Anti-ezrin antibodies generated either againstthe full-length protein or the first 310 residues were definedas anti–C and –N antibodies, respectively (Andréoli et al. 1994).

Immunofluorescence Analysis
Cells were fixed with 3.7% formaldehyde in PBS for 20 min andtreated with TBS containing 0.2% Triton X-100 for 4 min. Cellswere incubated with anti–VSV-G mAb (clone P5D4; Kreis 1986)for 1 h at room temperature, washed, and incubated with FITC-conjugatedphalloidin and Texas red–conjugated anti–mouse IgAb (Sigma-Aldrich). After final washes and mounting in Mowiol,cells were examined using a laser scanning confocal microscope(Leica or Bio-Rad Laboratories) using a 63x 1.4 oil immersionobjective.

Results

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

Mapping of the PIP₂ Binding Site
Association of ezrin with the lipid bilayer was first studiedwith fusion proteins corresponding to the NH₂-terminal domainof ezrin, a region which has been previously shown to mediatethe interaction of ezrin with PIP₂-containing liposomes (Niggli et al. 1995).As a measure for bilayer association, cosedimentation of proteinswith large liposomes containing 20% PIP₂ and 80% PC was analyzed.Control values of protein sedimenting in the absence of lipidwere always subtracted. Lipid interactions were measured underphysiological ionic strength conditions. We have found previouslythat addition of 1 mM MgCl₂ (in the presence of 60 µMEGTA and 50 µM EDTA) markedly reduced cosedimentationof wild-type full-length ezrin with PIP₂-containing liposomesby 40–70% (data not shown). According to Flanagan et al. 1997,divalent cations promote fusion of PIP₂ micelles into insolubleaggregates and may thus also adversely affect PIP₂-containingliposomes. All the experiments were therefore carried out inthe absence of added divalent cations.

Progressive deletions from the COOH terminus of ezrin 1-333illustrated the importance of amino acids 233–310 in theassay of cosedimentation with liposomes (95 ± 8% inhibitionof cosedimentation for ezrin 1-233, n = 4; Fig. 1). The internaldeletion of residues 13–114 also led to a dramatic lossof the resulting construct to interact with liposomes (89 ±18% inhibition, n = 3). GST alone did not cosediment with theliposomes and elimination of the GST moiety did not affect associationwith PIP₂-containing liposomes (Fig. 1). This finding showsthat unspecific trapping of protein in the lipid pellet is negligibleunder our experimental conditions. The results shown in Fig. 1also demonstrate that ezrin 1-333 is capable of recruiting aprotein incapable of membrane interaction (GST) to the bilayer.The PIP₂ binding domain of ezrin therefore appears to consistof nonlinear determinants and involves distinct portions ofthe molecule.

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Figure 1 Effects of truncations and internal deletions on the cosedimentation of the NH₂-terminal domain of ezrin with PIP₂-containing liposomes. The cosedimentation of ezrin domains, with or without the GST moiety (55 µg protein/ml), with large liposomes containing 20% PIP₂ and 80% PC (0.5 mg lipid/ml) in the presence of 130 mM KCl was determined as described in Materials and Methods. n.d., not done; n.a., not applicable.

By analogy with several PIP₂-binding proteins and pleckstrinhomology (PH) domains, it was inferred that a number of basicresidues could be involved in such an interaction. Typical PIP₂-bindingmotifs consist of clusters of basic amino acids; e.g., (K/R)XXXKX(K/R)(K/R)in gelsolin or (K/R)XXXX(K/R)(KR) in villin (Janmey et al. 1992;Yu et al. 1992). Two similar motifs are conserved in the entireERM family at identical positions and also at comparable positionsin merlin, if one takes into account the extended NH₂ terminusof merlin (Fig. 2). A third motif (RXRXXRR) as well as a clusterof basic amino acids (RRRK) are present in the ERM family atpositions 273–279 and 293–296, respectively. However,we demonstrate below that the two motifs shown in Fig. 2 arecrucial for PIP₂ interaction. Interestingly, one of these motifswas present in the 234–309 region and one in the 13–114portion of the molecule, the two regions identified by truncationexperiments as important for PIP₂ interaction. As shown in Fig. 1,interaction with PIP₂-containing liposomes was abolished wheneither of these regions was deleted. The COOH-terminal domainof ezrin also contains regions with clusters of basic aminoacids. However, we have shown previously that this domain doesnot significantly interact with PIP₂-containing liposomes (Niggli et al. 1995).These motifs thus are not functionally relevant for lipid interaction.

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Figure 2 Potential PIP₂ binding sites in the ERM family. Sequences were obtained from the Swiss Protein data bank. Accession numbers are: ezrin, P15311; radixin, P35241; moesin, P26038; and merlin, P35240.

Site-directed Mutagenesis of Potential PIP₂ Binding Sites
Several double mutations of the lysine residues located in thepresumed motifs were introduced in the ezrin 1-333 molecule.As shown in Table , double mutations of either lysines 253 and254, or lysines 262 and 263 to asparagine did not significantlyimpair the ability of the mutated construct to cosediment withPIP₂-containing liposomes. The double substitution K63N, K64Nby contrast led to a significant (P < 0.025) partial reductionin the amount of mutated ezrin 1-333 that cosedimented suggestinga particularly important role of these residues (Table ). Thecombination of the K253N, K254N and the K262N, K263N mutationsled to an almost complete loss of interaction with PIP₂ (84± 11% inhibition, n = 6). The combination of K63N, K64Nand K253N, K254N mutations resulted similarly in a protein withstrongly reduced PIP₂-binding capacity (78 ± 11% inhibition,n = 3), far exceeding the effect of the double mutation of K63N,K64N alone. The introduction of the K262N, K263N mutations intothis mutant did not further reduce binding. For optimal binding,the presence of either lysines 63, 64, 253, and 254 or lysines253, 254, 262, and 263 is thus required. The presence of lysines63 and 64 alone is not sufficient to maintain binding, correlatingwith the experiments on the truncated NH₂ terminus (Fig. 1).

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Table 1 Effects of K to N Mutations on Cosedimentation of Ezrin 1-133 with PIP₂-containing Liposomes

The finding that some double mutations (K253N, K254N or K262N,K263N) did not significantly alter PIP₂ binding of ezrin 1-333could be due to the use of saturating amounts of PIP₂ in theliposomes, which may not allow us to detect subtle changes inlipid binding. According to our previous findings, the interactionof full-length wild-type ezrin with liposomes is maximal at20% PIP₂ and 80% PC (Niggli et al. 1995). We therefore comparedinteractions of mutated and wild-type proteins with liposomescontaining lower amounts of PIP₂. As shown in Fig. 3, at 10and 5% PIP₂, no statistically significant difference was detectablebetween cosedimentation of mutants ezrin 1-333 K253N, K254N,ezrin 1-333 K262N, K263N, and the wild-type form of ezrin 1-333.

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Figure 3 Cosedimentation of wild-type and mutant ezrin 1-333 with large liposomes containing different amounts of PIP₂. Wild-type (WT) and mutant ezrin domains (55 µg protein/ml) were incubated in the presence of 100 mM NaCl and in the absence or presence of large liposomes containing 5, 10, or 20% of PIP₂, the remainder being PC (0.5 mg lipid/ml). The fraction of cosedimenting protein was assessed as described in Materials and Methods. Mean ± SD of three to eight experiments.

Since the serine 66 residue corresponds to a potential proteinkinase A phosphorylation site, we performed a S66D mutationin ezrin 1-333 to analyze the effects of introducing a negativecharge next to the neighboring lysine residues involved in PIP₂binding. However, the S66D mutant behaved as the wild-type domain(not shown). Introduction of a negative charge next to lysines63 and 64 thus does not disturb PIP₂ binding.

On the basis of the findings summarized in Fig. 1 and Table ,the full-length ezrin molecule was mutated in positions 253,254, 262, and 263 and in combination with positions 63 and 64.The amount of mutated construct recovered in the liposome-containingpellet corresponded to 2% of total protein for K253N, K254N,K262N, and K263N and to 3% for K63N, K64N, K253N, K254N, K262N,and K263N, as compared with 24% of wild-type ezrin cosedimentingwith liposomes (n = 2). PIP₂ interaction of these two mutantswas thus almost completely abolished, corresponding to the findingswith the 1-333 constructs.

Conformation and Functional Properties of Mutated Ezrin
To exclude that our findings were due to an unstable foldingand/or overall denaturation of the mutated protein, we comparedthe sensitivity of wild-type ezrin and ezrin K253N, K254N, K262N,and K263N to chymotrypsin (Fig. 4 A). Chymotrypsin has beenpreviously used to partially proteolyze ezrin and identify achymotryptic-resistant NH₂-terminal domain (Franck et al. 1993;Niggli et al. 1995). No major differences in the degradationpatterns were observed when ezrin was mutated: the 35- and 24-kDbands detected with an antibody directed against the first 310amino acids of ezrin were the major degradation products forboth the wild-type and the mutated ezrin, indicating thereforethat both molecules were similarly folded (Fig. 4 A). However,the 24-kD degradation product appeared earlier with ezrin K253N,K254N, K262N, and K263N, suggesting that its folding was lessstable than that of wild-type ezrin.

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Figure 4 The mutations introduced specifically target ezrin-PIP₂ interactions. (A) Introduction of four K > N mutations in ezrin did not change the chymotrypsin digestion pattern. Wild-type (WT) and mutated ezrin 1-586 (K253N, K254N, K262N, and K263N) (285 µg/ml) were incubated in the presence or absence of 3.3 µg/ml chymotrypsin at room temperature for the indicated times. After SDS-PAGE, membranes were immunoblotted with a polyclonal antibody targeted against the first 310 amino acids of ezrin. No major difference in the digestion patterns was observed when wild-type or mutated ezrin were compared. (B) Introduction of four K > N mutations in ezrin (K253N, K254N, K262N, and K263N) did not alter F-actin binding. F-actin binding was measured using a solid phase assay as described by Roy et al. 1997. Actin concentrations were chosen so that they were below, around, and above the dissociation constant (500 nM) for actin binding to ezrin. For each actin concentration, binding was measured in the presence or absence of PIP₂. Bound actin was detected using a monoclonal anti-actin antibody. The top two blots illustrate the binding of actin to the NH₂-terminal domain of wild-type and mutant ezrin (residues 1–333). The bottom two blots correspond to actin binding to full-length ezrin with or without the four K > N mutations. No obvious difference in F-actin binding capacity was observed when comparing mutated ezrin constructs with their parent wild-type counterparts. (C) Mutagenesis of the PIP₂ binding site in ezrin 1-333 did not impair the interaction of the NH₂-terminal domain of ezrin with the cytoplasmic tail of EBP50. The binding of wild-type ezrin 1-333 (WT and *) or mutated ezrin 1-333 (mutated and **) (1 µM) to GST-EBP 50 or GST was assessed as described for binding to CD44 in Materials and Methods. (Top) Coomassie staining, (bottom) Western blotting. The experiment had been done in triplicate for each construct. Western blotting showed that there was no major difference between WT ezrin 1-333 and the mutated form concerning binding to GST-EBP50. The right two lanes demonstrate the lack of binding of ezrin 1-333 WT (*) or mutated (**) when assayed with the control GST free of fusion protein. (D) Introduction of up to six K > N mutations in ezrin did not affect homotypic interactions. Wild-type ezrin 1-586 was coated in wells of a microtiter plate (Roy et al. 1997). Ezrin 1-333 constructs (0.5 µM each) were then added in F-actin buffer, except for the first lane, where no construct was added (*). Similar amounts of ezrin 1-586 were coated in each well as judged by the Coomassie stain of the top blot. The same polyclonal anti-ezrin antibody as in A was used to detect the construct overlaid and, irrespective of the mutations introduced, no major difference in the amount of ezrin 1-333 construct bound to ezrin 1-586 was observed (bottom). When no ezrin 1-586 was coated, no ezrin 1-333 was detectable (not shown). (E) Intrinsic tryptophane fluorescence was not modified upon introduction of four K > N mutations in full-length ezrin. (Top curve) Full-length mutated ezrin K253N, K254N, K262N, and K263N; (bottom curve) wild-type ezrin 1-586. Note that neither the maximum intensity of tryptophane fluorescence nor the wavelength for maximum emission were significantly affected upon introduction of the four mutations.

The same mutations also did not alter the ability of the full-lengthezrin molecule nor that of the ezrin 1-333 construct to bindto F-actin at relatively high concentrations (0.5–2.5µM F-actin) as measured in the solid phase assay (Fig. 4B) (Roy et al. 1997). Under more stringent conditions (0.1 µMF-actin), the binding capacity of mutated molecules may be lowered.The addition of PIP₂ was without effect on the F-actin bindingof both constructs whether they were mutated or not, emphasizingtherefore the lack of requirement for PIP₂ to bind to F-actinunder our assay conditions. The K253N, K254N, K262N, and K263Nezrin 1-333 also interacted with the cytoplasmic tail (aminoacids 329–358) of EBP 50 in fusion with GST to the sameextent as wild-type ezrin 1-333 (Fig. 4 C). No interaction withcontrol GST was detectable.

Using the solid phase assay, we demonstrated that the threepair mutations (K > N; residues 63 and 64, 253 and 254, and262 and 263) introduced in ezrin 1-333, either alone or in combination,did not impair its homotypic association with the full-lengthmolecule (Fig. 4 D).

In addition, the intrinsic tryptophane fluorescence spectraof both wild-type ezrin and mutated molecule were similar uponnormalization and exhibited identical maximum wavelength emission(Fig. 4 E). The 10% difference observed in the maximum intensitymay be due to an overestimation of the protein concentrationof wild-type ezrin, but in no case did the tryptophane fluorescenceof the mutated ezrin appear to be significantly quenched uponexposure of trytophane(s) to solvent due to an inappropriatefolding of the molecule.

Overall, the differences in the properties of wild-type andmutated ezrin documented in Fig. 4 are all very small, whereasthe effects of the mutations on PIP₂ binding were drastic. Theoverall conformation of the ezrin molecule as well as some ofits major functional binding properties appeared to be essentiallypreserved after introducing these mutations, except for itsability to interact with PIP₂-containing liposomes.

Alteration of the PIP₂-dependent Ezrin-CD44 Interaction
The interaction of ezrin with CD44 has been demonstrated tobe PIP₂-dependent under physiological ionic strength conditions(Hirao et al. 1996). We therefore tested whether mutations inthe residues involved in PIP₂ binding affected ezrin interactionwith the cytoplasmic tail of CD44 in vitro. Indeed in the presenceof PIP₂ micelles, the amount of wild-type ezrin binding to GST-CD44immobilized on glutathione agarose beads was significantly increased(Fig. 5). In contrast, the binding of ezrin K253N, K254N, K262N,and K263N to the same beads was unaffected by PIP₂ addition,and was already comparable with the level obtained with wild-typeezrin in the presence of PIP₂. As a control, both the wild-typeand mutated forms of ezrin did not bind to GST-glutathione agarosebeads, irrespective of the presence of PIP₂ (Fig. 5).

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Figure 5 Mutagenesis of the PIP₂ binding site in ezrin results in a loss of PIP₂ requirement of the interaction of ezrin with the cytoplasmic tail of CD44. Binding of full-length wild-type ezrin or ezrin K253N, K254N, K262N, and K263N (K253,254,262,263N) to GST or GST-CD44 in the absence or presence of PIP₂ was assessed as described in Materials and Methods. Aliquots of the supernatant were then analyzed by SDS-PAGE and immunoblotted for the presence of ezrin. (A) Coomassie blue staining of the blots shows that comparable amounts of GST-CD44 (or GST) were detected in all lanes (top, incubation with GST-CD44 beads; bottom, incubation with GST beads). In contrast to wild-type (WT) ezrin (top left), K253N, K254N, K262N, and K263N (K253,254,262,263N) mutations in ezrin induced constitutive binding to GST-CD44–coupled agarose beads independently of the addition of PIP₂ micelles (top right). GST beads alone (bottom) were used as control. During the GST-CD44 preparation, significant cleavage of the fusion protein occurred, resulting in large amount of GST adsorbed on the gel. (B) The amount of wild-type or mutated ezrin bound to GST-CD44 or to GST alone was quantified by densitometry of the immunoblots shown in A. Black and hatched columns represent ezrin bound to GST and GST-CD44, respectively. The results shown are representative of three independent experiments.

Abnormal Localization of Ezrin Deficient in PIP₂ Binding
A431 epithelial cells and COS1 fibroblasts were transfectedwith ezrin K253N, K254N, K262N, and K263N or with wild-typeezrin, both constructs being tagged with VSV-G epitope. In A431cells, wild-type ezrin VSV-G colocalized with F-actin at apicalruffles and microvilli, plasma membranes, and microspikes, asalready described for endogenous ezrin (Gould et al. 1986; Algrain et al. 1993).Stress fibers and adhesive plaques were decorated with actinbut not with ezrin (Fig. 6, a–c and g–i). On thecontrary, in A431 and COS1 cells, mutated ezrin VSV-G was foundto be located as a sponge-like network within the cytoplasm,clearly visible on single focal planes (Fig. 6d and Fig. j)and xz sections. Mutated ezrin was only faintly detectable atthe leading edge of plasma membranes or microspikes (Fig. 6j). Clearly, mutated ezrin VSV-G labeling was excluded fromvesicular structures. Expression of this mutated form of ezrin,however, did not alter cell size and morphology or actin-richstructures.

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Figure 6 Mutated ezrin loses its cell membrane localization in transfected A431 and COS1 cells. Human adenocarcinoma A431 epithelioid cells (a–f) and monkey kidney COS1 fibroblasts (g–l) were transfected with either VSV-G–tagged wild-type ezrin (a–c and g–i) or mutated ezrin (K253N, K254N, K262N, and K263N) (d–f and j–l) DNA and treated for indirect Texas red localization of ezrin with anti–VSV antibody (left) and F-actin with FITC-coupled phalloidin (middle). Pictures represent the projected maximum intensities of several focal planes ranging from substrate to apical level, except for d and j. Vertical xz sections at the level of the dotted lines are under each figure. Insets are enlargements of the squared areas in a–c. Dual localizations of ezrin and actin are merged in color, colocalization appearing in yellow. Transfected wild-type ezrin is located in actin-rich cell surface structures such as microspikes, dorsal microvilli (a–c, circles) or ruffles (g–i, arrows), and in lateral cell membranes (a and c, intercellular contacts). Note that focal adhesion plaques (b, c, e, and f, insets, arrowheads) and stress fibers (k) are devoid of any ezrin. Transfected mutated ezrin is essentially located as a cytosolic network (d, f, j, and l; note that single focal planes are used only in d and j for clearer visualization of ezrin), but is also faintly detectable on the cell membranes in COS1 cells (j, arrow). Localization of wild-type ezrin in actin-rich dorsal structures and mutated ezrin in cytoplasm is evident in xz sections. Bars, 10 µm.

The subcellular distribution of wild-type and K253N, K254N,K262N, and K263N VSV-G–tagged ezrin was compared uponcell fractionation of COS1 cells. No marked difference was observedin partition of these proteins between cytosol and total membranefractions (Fig. 7 A). However, the amount of Triton X-100 insolubleezrin associated with the cytoskeleton was significantly lowerin the case of mutated ezrin (37% of total cellular ezrin VSV-Gvs. 27% of K253N, K254N, K262N, and K263N ezrin VSV-G; Fig. 7A). As pointed out for actin, the distribution of endogenousezrin was not significantly affected by expression of eitherform of ezrin VSV-G.

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Figure 7 Subcellular localization of transfected mutated and wild-type ezrin in COS1 cells. Transfected cells were fractionated as described in Materials and Methods and the resulting fractions were analyzed by SDS-PAGE and immunoblotting. Before immunodecoration, blots were stained with Coomassie blue to ensure that protein loadings were comparable. (A) Transfection of full-length ezrin. Transfected VSV-tagged wild-type and K253N, K254N, K262N, and K263N (K253,254,262,263N) ezrin were recovered in cytosol (C), Triton X-100 extractable (E), or nonextractable (N) material, as revealed after immunoblotting with anti–VSV-G mAb. Anti-ezrin antibody, which recognizes both endogenous and VSV-G–tagged ezrin, was used as a control (top). *Internal control with recombinant wild-type ezrin (100 ng load). Results shown are representative of three independent experiments. (B) Transfection of ezrin 1-310. Detection of the top blot was performed with an antibody against the NH₂-terminal portion of ezrin. The proportion of cytosolic full-length ezrin (#) detected with this antibody is lower than that presented in A due to the poor accessibility of the anti–N antibody to the epitopes in the full-length ezrin. Note that some degradation of ezrin was detectable in the nonextractable material (N). Immunodetection of the bottom blot was performed with anti–VSV-G mAb.

Loss of the Cell Extension Activity of the NH₂-Terminal Domain of Ezrin Upon Mutation of Its PIP₂ Binding Domain
COS1 fibroblasts were also transfected with the VSV-G–taggedNH₂-terminal domain of either wild-type or mutated ezrin. Aspreviously described (Martin et al. 1997), the transfectionof the 1–310 fragment of ezrin induced formation of longfilopodia, which contain both tagged ezrin 1-310 and actin (Fig. 8,a–c). This cell extension activity of the ezrin NH₂-terminaldomain is dependent on the cell type used and was not observedin the case of CV1 cells (Algrain et al. 1993). Ezrin 1-310and actin colocalized to a variable extent along these structures.Transfected ezrin 1-310 was also localized in actin-containingstructures such as surface microvilli, dorsal ruffles, and lateralmicrospikes, comparable with the wild-type full-length molecule.Possibly due to its overexpression, tagged ezrin 1-310 was regularlyobserved in the cytoplasm and was excluded from vesicles. Strikingly,upon transfection of the cells with mutated ezrin 1-310, almostno cell extensions developed and the cells were extremely flattened.The localization of the mutated form of NH₂-terminal domainof ezrin appeared essentially cytoplasmic even if colabelingof some extensions containing actin persisted (Fig. 8, d–f).Note that with this construct some staining of the nucleoliwas apparent (see Discussion). Upon cell fractionation, wild-typeezrin and mutated ezrin 1-310 were recovered in the particulatefraction (Fig. 7 B). At variance with the microscopic observations,no ezrin 1-310 was recovered in the cytosolic fraction. Thisdiscrepancy can be explained with the relative insolubilityof the NH₂-terminal domains of ezrin, especially in low saltbuffers such as those used for cell lysis.

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Figure 8 The mutated NH₂-terminal domain of ezrin partly loses its interactions with membranes. Monkey COS1 fibroblasts were transfected with either VSV-G–tagged wild-type (a–c) or mutated (K253N, K254N, K262N, and K263N) (d–f) ezrin 1-310 and treated for immunolocalization of actin (b and e) and VSV (a and d) as in Fig. 6. Transfected wild-type NH₂-terminal ezrin was mainly localized in actin-rich structures such as dorsal microvilli and ruffles (b and c, arrows; xz sections, circles). It induces formation of long filopodia containing both actin (b and c, arrowheads) and transfected ezrin (a and c, arrowheads). Note the presence of nodes along filopodia, particularly rich in NH₂-terminal ezrin (open arrows). The transfected mutated form of NH₂-terminal ezrin was predominantly localized in the cytoplasm (d and f), although some mutant ezrin localized in the same actin-rich structures (e and f) as wild-type NH₂-terminal ezrin. Staining of nuclei was observed only in cells transfected with mutated ezrin 1-310 (d and f). Bars, 10 µm.

	Discussion

Top Abstract Introduction Materials and Methods Results Discussion References

PIP₂, a lipid whose turnover is modified upon cell activation,has been implicated in the regulation of the functions of anumber of cytoskeletal proteins (Janmey 1995; Isenberg and Niggli 1998).Depending on the protein studied, PIP₂ interactions may concentrateproteins at the plasma membrane in a manner affected by cellactivation, possibly within PIP₂-enriched domains (Martin 1998).PIP₂ may also modulate the function of the protein to whichit binds (Gascard et al. 1993; Huttelmaier et al. 1998; Steimle et al. 1999).Knowledge of the molecular determinants involved in lipid–proteininteractions is a prerequisite for studying their physiologicalrole in intact cells. We have therefore analyzed the natureof PIP₂-binding determinants in ezrin by truncations, internaldeletion, and site-directed mutagenesis. PIP₂ binding was studiedusing large liposomes containing 20% PIP₂ and 80% PC, in physiologicalsalt concentrations. Presenting PIP₂ in mixed bilayers is muchcloser to the cellular environmental conditions than presentationas micelles of pure lipid. The advantage of the cosedimentationassays is also that free ezrin is always exposed to the bilayerand never separated during the assay. A disadvantage is thatit cannot be completely excluded, that ezrin extracts some PIP₂molecules to form a small complex that does not sediment. Aspreviously shown, binding of full-length ezrin is maximal at $~$ 20% PIP₂, and 5–10% of PIP₂ still induced significantassociation (Niggli et al. 1995). This is similarly the casefor wild-type ezrin 1-333 (Fig. 3).

We first showed, by progressive truncations and internal deletions,that the NH₂ terminus of ezrin contains two domains essentialfor PIP₂ binding, located in regions 12–115 and 233–310.The loss of one of the sites resulted in almost complete lossof binding. Interestingly, recent findings for gelsolin similarlysuggest that this protein binds to PIP₂-containing bilayersvia a site formed by the juxtaposition of the NH₂- and COOH-terminaldomains of gelsolin (Tuominen et al. 1999). To our knowledge,these are so far the only two proteins known with a pair ofPIP₂-binding sites.

Inspection of the sequence of the NH₂-terminal domain of ezrinrevealed two potential PIP₂ binding motifs, which are similarto the motifs identified in gelsolin and villin (Fig. 2). Wehave analyzed the role of these motifs in ezrin-PIP₂ bindingby mutation of selected lysines to asparagines. These experimentsrevealed an important role of lysines 63 and 64, which are requiredfor optimal binding. In contrast, two independent double mutationsof lysines 253 and 254 or 262 and 263 to asparagines were ofno consequence for the interaction with PIP₂. However, thisdoes not mean that they are not involved in binding since mutationof all four lysines 253, 254, 262, and 263 resulted in an almostcomplete loss of binding similar to that observed after mutationof lysines 63, 64, 253, and 254. The presence of the lysinesin the 63–72 motif is thus clearly necessary, but notsufficient for interaction. This conclusion is supported alsoby the inability of fragment 1–233 to bind to PIP₂. Foroptimal binding, the combined presence of K63, K64, K253, andK254 or K253, K254, K262, and K263 is thus required. Our resultssuggest that the two domains located in regions 63–72and 253–263 do cooperate in PIP₂ binding. The site atamino acids 63–72 corresponds to a KKXXXXXX(K/R)K motif,which is similar to, but not identical with, the consensus sequencein villin, (K/R)XXXX(K/R)(K/R) (Yu et al. 1992). The site atamino acids 253–263, a KKXXXKXXXKK motif resembles a consensussequence for gelsolin, (K/R)XXXKX(K/R)(K/R) (Yu et al. 1992).Typically, the motifs involved in ezrin–PIP₂ interactionstart and end with two basic amino acids, whereas the sitesin gelsolin and villin start with only one lysine or arginine.In addition, the numbers of interspersed amino acids are differentin ezrin. Another motif has been detected in the cytoskeletalprotein ${alpha}$ -actinin, and also in spectrin and the PH domain ofphospholipase C- ${delta}$ 1 and Grb7: RXXXXXXX(H/RK)XX(X)W(K/R) (Fukami et al. 1996).Again, this motif is not identical with those detected in ezrin.

During the completion of this manuscript, the crystal structureof a complex of the NH₂-terminal domain of moesin (residues1–297) with the tail (residues 467–577) has beenpublished (Pearson et al. 2000). According to this work, residues63, 64, 253, 254, 262, and 263 are all located in loops connectingβ sheets. In a space-filling model of moesin, the residuesimplicated in PIP₂ binding are all located on the surface ofthe molecule (Fig. 9 A). The residues form a triangle (Fig. 9A). The surface enclosed by this triangle is relatively planar,so that a simultaneous contact of all residues with severalPIP₂ molecules in a bilayer appears to be feasible. The residuesenclosed by this triangle and exposed on the surface of moesinhave been highlighted in the moesin sequence (Fig. 9 B). Theseresidues, which could form a zone of contact with a PIP₂-containingbilayer, are identical in moesin and ezrin, with the exceptionof asparagine 62 in moesin, which corresponds to aspartic acid62 in ezrin. Of these residues, including the lysines identifiedin this study, 36% are positively charged, 16% are negativelycharged, 24% are uncharged but polar, and 24% are hydrophobic.Interestingly, Pearson et al. 2000 detected a hitherto unrecognizedPH-like domain in the structural module F3 of moesin, whereresidues 253, 254, 262, and 263 are located. Such PH domainsare involved in phosphoinositide binding and feature an antiparallelβ sheet consisting of seven strands and a COOH-terminal ${alpha}$ -helix (Harlan et al. 1995), comparable with the structure ofF3 of moesin. Using the web-based tool SMART (Simple MolecularArchitecture Research Tool; Schultz et al. 1998), we searchedfor a PH domain in the NH₂-terminal domain of ezrin, but wereunsuccessful. If F3 indeed corresponds to a functional PH domain,then the distribution of charged amino acids is not typicalfor such domains. According to Pearson et al. 2000, the highlypositively charged surface of lobe F3 of moesin may be suitablefor binding of negatively charged phospholipids, in agreementwith our results. Based on the crystallization results, thePIP₂ binding domain in ezrin is thus also different from thelipid-binding domain identified in vinculin, which has beenshown to form an amphipathic helical hairpin (Johnson et al. 1998).Ezrin appears to contain two structural elements cooperatingin PIP₂ binding and one of these elements may be part of a PHdomain. These two domains do not appear to be directly involvedin F-actin binding, nor do these mutations affect a distal F-actinbinding site, as F-actin interaction of ezrin K253N, K254N,K262N, and K263N was not altered. A similar conclusion can bedrawn for the interaction of ezrin with EBP 50.

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Figure 9 Location of the targeted lysines in moesin. The crystallographic data of moesin were treated with the molecular visualization program RASMOL (R. Sayle, Glaxo Wellcome, Greenford, UK). (A) The different domains of the molecule defined by Pearson et al. 2000 were colored as follows: residues 4–94, violet (domain FI); residues 95–201, blue (domain F2); residues 202–297, green (domain F3); and residues 488–577, red (COOH-terminal domain). The lysines of interest have been highlighted in yellow. The distances between the epsilon NH₂ of lysines 63–262, 63–254, and 254–263 are equal to 38.1, 27.6, and 19 Å, respectively. Note that all these lysines are accessible to solvent and therefore to PIP₂. They are all located on the same side of the molecule. (B) Moesin residues that may be in direct contact with the bilayer. Using RASMOL, residues exposed on the surface of moesin and enclosed by the triangle formed by lysines 63, 64, 253, 254, 262, and 263 (bold and underlined) have been identified (bold).

It is unlikely that the effects reported in this paper on ezrin–PIP₂interaction could be simply due to an overall change of thepositive charges of the protein. For example, the double mutationK63N, K64N significantly decreased PIP₂ binding, whereas thetwo double mutations of lysines to asparagines at positions253 and 254 or 262 and 263 had no significant effects. At pH7.4, the calculated net global charge for the wild-type proteinis +6.26 (ezrin 1-333) and –8.34 (ezrin 1-586). Introducingsix K > N mutations yielded global charges that were +0.27and –14.34. In spite of the net charge difference betweenezrin 1-333 and full-length ezrin, the very same PIP₂-bindingdeterminants were found to be important in the two molecules.Moreover, experiments were carried out under physiological ionicstrength conditions. Under these conditions, the range of distanceswhere electrostatics overcome thermal energies is relativelysmall, and the precise positioning of specific basic amino acids,rather than the overall charge of the NH₂-terminal domain, islikely to be important for ezrin–PIP₂ interaction. Forexample, the PH domain of pleckstrin is electrically polarized(Blomberg and Nilges 1997), and mutation of three conservedlysine residues in this domain has been shown to result in 10-folddecrease in lipid-binding affinity (Harlan et al. 1995). Asoutlined for the PH domain, other determinants for PIP₂ interaction,based, for example, on interactions with acyl chains of thelipid, exist and may account for a pronounced, albeit incomplete,loss in affinity as described in the case of the mutated PHdomain of pleckstrin (Harlan et al. 1995).

Interestingly, the introduction of two double mutations (K253N,K254N and K262N, K263N) results in the loss of PIP₂ requirementfor optimal binding of ezrin to the cytoplasmic tail of CD44.As shown in Fig. 5, the binding between CD44 and the mutatedform of ezrin is not impaired but becomes PIP₂ independent.This portion of the CD44 molecule contains clusters of basicamino acids involved in the CD44/ezrin interaction (Legg and Isacke 1998).PIP₂ may neutralize basic residues in ezrin, resulting in eliminationof repulsive forces between the two molecules. Introducing themutations may generate the same effect. However, using truncationexperiments, Yonemura et al. 1998 demonstrated that the first19 residues of the cytoplasmic tail of CD44, containing a clusterof basic residues, were sufficient, at physiological ionic strength,to allow ERM-CD44 interactions, whereas binding of the full-lengthcytoplasmic tail was markedly reduced under these conditions.These interactions were studied in the absence of PIP_2. Thisfinding cannot be reconciled with the hypothesis that chargeneutralization by lipid is required for such a protein interactionto occur.

Wild-type VSV-G–tagged ezrin is massively recruited todorsal actin-rich structures. The K253N, K254N, K262N, and K263Nmutated form of ezrin was introduced into both epithelioid andfibroblastic cell lines. Immunofluorescence localization showedthat the VSV-G–tagged mutant was now mainly located inthe cytoplasm, without colocalization with F-actin and onlyweak binding to plasma membranes. Based on our in vitro findings,one would expect that mutated ezrin would bind to plasma membraneproteins independently of PIP₂. In fact, Legg and Isacke 1998concluded, using CD44-negative cells, that the localizationof ezrin to microvilli was not mediated through an interactionwith CD44, but rather with other sites at which the actin networkclosely associated with the plasma membrane. In our study, mutatedezrin expressed in cells no longer localizes to microvilli andruffles, suggesting that a direct PIP₂–ezrin interactionmay be one of the necessary events to address ezrin to thesespecific membrane structures. Since ERM proteins are involvedin the formation of the very same structures, the cytoplasmiclocalization of the mutated ezrin protein might simply resultfrom an upstream defect (PIP₂ binding) absolutely required forthe formation of a novel ezrin-containing membrane structure.Cell fractionation studies showed indeed that recovery of themutated ezrin in the cytoskeleton-associated membrane fractionwas significantly reduced as compared with the wild-type protein,supporting the immunofluorescence studies. However, total recoveryin the membrane fraction appeared not to be altered. This maybe due to redistribution occurring during the isolation procedureusing detergent.

It has been suggested that multimeric forms of ezrin are involvedin the generation of actin-rich structures (Gary and Bretscher 1993).Interactions between NH₂-terminal domains of ERM proteins andfull-length proteins resulting in multimer formation have beenshown to interfere with the normal functions of endogenous proteinsin the NIH3T3 cell line (Henry et al. 1995; Amieva et al. 1999).Using a solid phase assay, we found that wild type as well asmutated ezrin 1-333 and full-length ezrin engaged in homotypicinteractions (Fig. 4 D). However, by immunolocalization, nomutated ezrin was found associated with actin-rich structures.We can thus conclude that the formation of heterodimers of wild-typeand mutated ezrin is not sufficient for the association withactin-containing domains.

A number of reasons led us to transfect cells with the wholeNH₂-terminal domain of ezrin (residues 1–310) rather thanthe portion of the protein containing the PIP₂ binding determinants(residues 63–263). Amino acids beyond 296 are necessaryfor engaging in homotypic as well as heterotypic interactions(Gary and Bretscher 1993). Deletion of amino acids 13–30in ezrin (Martin et al. 1997) or of the first 11 residues ofmoesin (Amieva et al. 1999) led to drastic changes of the localizationof the NH₂-terminal portion of these proteins. Ezrin 1-320 stilllocalizes to the membrane, whereas fragment 1-276 is cytosolic(Amieva et al. 1999). Thus, deleting any of these portions ofthe molecule may be dominant over the mutations of the PIP₂binding determinants. In fact, introduction of the latter mutationsled to an expression pattern similar to the one observed forany of the deletions described above. These observations suggestthat any change in the NH₂-terminal domain of the ERM can drasticallyaffect the protein structure and/or function. Of interest isthe observation that when the PIP₂ binding determinants weremutated, the NH₂-terminal domain of ezrin localized within thenucleoli. Although the possibility of an artifact has to beconsidered, a 55-kD ezrin-related protein that cross-reactswith antibodies against the NH₂-terminal domain of ezrin hasbeen detected in the nucleus of many human transformed cells(Kaul et al. 1999). Evidence has also been presented for thenuclear localization of isoforms of protein 4.1, the first memberof the ERM family (Correas 1991). In this latter case, at variancewith our observations, a cluster of basic residues was necessaryfor such a localization to occur (Luque et al. 1998).

In conclusion, two PIP₂ binding determinants exist in ezrinin regions 12-115 and 233-310 of the protein, with lysines 63,64, 253, 254, 262, and 263 playing a major role for efficientinteraction. As these residues are conserved in the ERM family(Fig. 2), ezrin, moesin, and radixin may specifically bind toPIP₂ using the same determinants. Although we cannot excludethe possibility that the mutations described in this work alterother functions of ezrin, these mutated residues are likelycandidates involved in the targeting of ezrin to, and presumablyin the formation of, F-actin–rich membrane structures.

Acknowledgments

We thank Kathy Mujynya Ludunge and Christelle Anguille for excellenttechnical assistance, Professor H.U. Keller for continuous support,Dr. E. Sigel for critical reading of the manuscript, and SabineBaumann for helpful discussions. We are most grateful to Drs.M. Arpin, A. Bretscher, and R. Lamb for generous sharing ofmaterials.

This work was supported by the Centre National de la RechercheScientifique (Cell Biology project 96033 to C. Roy), by l'Associationpour la Recherche sur le Cancer (to P. Mangeat, C. Roy, andC. Barret), by la Ligue Nationale contre le Cancer and la Fondationpour la Recherche Médicale (to C. Barret), and by theSwiss National Foundation for Scientific Research (grant 31-49197.96to V. Niggli).

Note added in proof. During revision of this manuscript, K.Hamada and colleagues published the crystal structure of radixincomplexed to inositol-(1,4,5)-triphosphate (IP3) (Hamada, K.,T. Shimizu, T. Matsui, Sh. Tsukita, Sa. Tsukita, and T. Hakoshima.2000. EMBO (Eur. Mol. Biol. Organ.) J. 19:4449–4462).Most other residues identified in our study are in the vicinityof IP3.

Submitted: 16 May 2000

Revised: 6 October 2000

Accepted: 12 October 2000

Abbreviations used in this paper: ERM, ezrin/radixin/moesin;GST, glutathione S-transferase; PH, pleckstrin homology; PIP₂,phosphatidylinositol 4,5-bisphosphate; PC, phosphatidylcholine;VSV-G, vesicular stomatitis virus glycoprotein G.

References

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Abstract
Introduction
Materials and Methods
Results
Discussion
References

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