Biochemical Characterization of the Binding of Echistatin to Integrin alpha vbeta 3 Receptor

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Vol. 283, Issue 2, 843-853, 1997

Biochemical Characterization of the Binding of Echistatin to Integrin $alpha$ _v $beta$ ₃ Receptor

C. Chandra Kumar, Huiming-Nie, Christine Prorock Rogers, Mike Malkowski, Eugene Maxwell, Joseph J. Catino and Lydia Armstrong

Department of Tumor Biology, Schering Research Institute, Kenilworth, New Jersey

	Abstract

Top Abstract Introduction Materials & Methods Results Discussion References

Echistatin is a 49-amino-acid peptide belonging to the family of disintegrins that are derived from snake venoms and are potentinhibitors of platelet aggregation and cell adhesion. Integrin $alpha$ _v $beta$ ₃ receptor plays a critical role in several physiological processessuch as tumor-induced angiogenesis, tumor cell metastasis, osteoporosisand wound repair. In this study, we have characterized the bindingof echistatin to purified integrin $alpha$ _v $beta$ ₃ receptor and the formexpressed on human embryonic kidney 293 cells. We show that bothpurified and membrane-bound integrin $alpha$ _v $beta$ ₃ binds to echistatinwith a high affinity, which can be competed efficiently by linearand cyclic peptides containing the RGD sequence. Previous studieshave shown that $alpha$ _v $beta$ ₃ binds to vitronectin in a nondissociablemanner, whereas an RGD-containing peptide derived from vitronectinbinds in a dissociable manner with a K_d of 9.4 × 10⁷ M. Our studies indicate that radiolabeled echistatin binds to $alpha$ _v $beta$ ₃ in a nondissociable manner, similar to native echistatin.However, echistatin does not support the adhesion of 293 cellsexpressing $alpha$ _v $beta$ ₃ receptor because of poor binding to plastic dishesand is a potent antagonist of the adhesion of these cells to vitronectin.These studies demonstrate that echistatin binding to $alpha$ _v $beta$ ₃ is ofhigh affinity and irreversible similar to vitronectin and providesan alternate ligand for high-throughput screening for $alpha$ _v $beta$ ₃ antagonists.

	Introduction

Top Abstract Introduction Materials & Methods Results Discussion References

Adhesion receptors of the integrin family are responsible for a wide range of cell-extracellular matrix and cell-cell interactions(Hynes, 1992; Clark and Brugge, 1995). Each integrin consistsof noncovalently associated alpha and beta subunits which pairto create heterodimers ( $alpha$ $beta$ ) with distinct adhesive capabilities.As receptors of extracellular matrix proteins, integrins provideanchorage and convey signals that regulate cell growth, differentiationand migration (Juliano and Haskill, 1993; Sastry and Horowitz,1993). The integrin $alpha$ _v $beta$ ₃ is expressed on endothelial cells, osteoclasts,melanoma and other cell types (Cheresh and Spiro, 1987; Cheresh,1987;Miyuchi et al., 1991; Horton, 1990), where it plays a role inphysiological processes that include angiogenesis and tissue repairas well as pathological conditions such as osteoporosis, tumorcell metastasis, adenoviral infections and tumor-induced angiogenesis(Schwartz, 1993; Brunhilde,1992; Davis et al., 1993; Ross et al.,1993; Brooks et al., 1994a,b; Wickham et al., 1993). Recent resultswhich demonstrate a critical role for integrin $alpha$ _v $beta$ ₃ in angiogenesishave sparked an interest in this receptor (Brooks et al., 1994a,b).Brooks et al. (1994a,b) have shown that antibody and peptide antagonistsof integrin $alpha$ _v $beta$ ₃ inhibit angiogenesis on the chick chorioallantoicmembrane when introduced intravenously into the chick embryo.Evidence has been presented indicating that antagonists of integrin $alpha$ _v $beta$ ₃ inhibit this process by selectively promoting apoptosis ofvascular endothelial cells (Brooks et al., 1994a). These findingsindicate a key role for integrin $alpha$ _v $beta$ ₃ in a signaling event criticalfor the survival and ultimately differentiation of vascular cellsundergoing angiogenesis in vivo. These results also provide evidencethat antagonists of integrin $alpha$ _v $beta$ ₃ may provide a novel therapeuticapproach for the treatment of neoplasia or other diseases characterizedby angiogenesis.

Although originally isolated as a receptor for vitronectin, $alpha$ _v $beta$ ₃ actually recognizes a broad range of extracellular matrixprotein ligands such as vitronectin, fibronectin, fibrinogen,von Willebrand factor, thrombospondin and osteopontin, all ofwhich contain the classical integrin recognition motif, Arg-Gly-Asp(RGD) (Leavesly et al., 1992; Charo et al., 1990). The relaxedspecificity of $alpha$ _v $beta$ ₃ contrasts sharply with the selectivity of $alpha$ ₅ $beta$ ₁ integrin which binds to only fibronectin and fibrinogen (D'Souzaet al., 1991; Suehiro et al., 1997). Thus, even though the RGDmotif has been firmly established as a key determinant in therecognition of extracellular matrix protein ligands by $alpha$ _v $beta$ ₃, $alpha$ _v $beta$ ₁and other integrins, the molecular basis for differences in receptor-ligandspecificity remains poorly understood.

Investigation of the role of RGD-interactive adhesion molecules has been facilitated by the identification of small RGD-containingproteins derived from snake venoms termed disintegrins (Gouldet al., 1990). Disintegrins are a family of naturally occurring,cysteine-rich, small (5-9 kDa) polypeptides that potently inhibitplatelet aggregation and cell adhesion (Gould et al., 1990; Niewiaroskiet al., 1994). The biological activity of disintegrins dependson the structure of an RGD-containing loop maintained in an appropriateconformation by disulfide bridges. Because they are relativelysmall (each is 50-80 amino acids), they provide a unique opportunityto gain insight into the three-dimensional structure of RGD-activeproteins and the factors that are important in controlling specificity.Echistatin from the venom of Echis carinatus is the smallest (49amino acids) member of the family and has been the focus of intenseresearch (Gan et al., 1988).

Echistatin is believed to bind to the $alpha$ _v $beta$ ₃ integrin expressed on osteoclasts (Sato et al., 1990, 1994; Fisher, et al., 1993).Sato et al. (1990) have shown that echistatin inhibits both excavationof bone by rat osteoclasts and the release of ³H-proline from prelabeled bone particles by chicken osteoclasts(Sato et al., 1994). Because $alpha$ _v $beta$ ₃ is the predominant receptorexpressed on osteoclasts, these studies suggested that echistatincan bind to integrin $alpha$ _v $beta$ ₃. These activities depend on the RGDdomain, because substitutions of the arginine of the RGD sequenceof the echistatin with alanine resulted in loss of activity (Fisheret al., 1993). However, detailed biochemical studies on the bindingof echistatin to $alpha$ _v $beta$ ₃ receptor are lacking. This study providesa quantitative biochemical characterization of the binding ofechistatin to integrin $alpha$ _v $beta$ ₃. In this study, we show that integrin $alpha$ _v $beta$ ₃ receptor binds to echistatin with a high affinity both inits purified form and the form expressed on the cell surface.Echistatin can also inhibit the adhesion of human embryonic kidneycells expressing $alpha$ _v $beta$ ₃ receptor to vitronectin, which suggeststhat it can function as an antagonist of the receptor. We alsodemonstrate that echistatin binds to $alpha$ _v $beta$ ₃ in a nondissociablemanner similar to vitronectin.

	Materials and Methods

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Materials. Human embryonic kidney (HEK 293) cells were obtained from American Type Culture Collection (CRL 1573). DMEM, L-glutamine,nonessential amino acids, gentamycin and synthetic RGD-containingpeptides were purchased from Gibco-BRL (Gaithersburg, MD). Fetalbovine serum was from Hazleton Biologicals (Lenox, KS). Octyl- $beta$ -D-glucopyranosideand Nonidet P-40 were purchased from Sigma Chemical Company (St.Louis, MO). Microlite-2 plates were obtained from Dynatech Corporation(Chantilly, VA). Multiscreen-FB opaque plates (1.0 µm Glass FiberType B filter) were from Millipore (Billerica, MA). Falcon MicrotestIII microtiter plates are from Falcon (Franklin Lakes, NJ). $alpha$ _v $beta$ ₃specific (LM609) monoclonal antibodies, anti- $alpha$ _v $beta$ ₅ specific antibodies(mAb 1961) and LM609-coupled to Affi-Gel matrix were purchasedfrom Chemicon International Inc. (Temecula, CA). Anti $alpha$ _v specificmonoclonals (12084-018) were from Gibco-BRL, and anti- $beta$ ₃ (550036)and anti- $beta$ ₁ (55034) specific monoclonal antibodies were purchasedfrom Becton Dickinson (Franklin Lakes, NJ). ¹²⁵I-Echistatin labeled by the lactoperoxidase method to a specificactivity of 2000 Ci/mmol was from Amersham International (Chicago,IL). Echistatin was purchased from Bachem (Torrence, CA).

Protein purification. $alpha$ _v $beta$ ₃ was purified as described by Orlando and Cheresh (1991). Human placenta was cut into 2-cm² pieces and washed with 0.05% Digitonin, 2 mM PMSF, 2 mM CaCl₂in water for 60 min on ice. The placenta was then extracted byincubation with 100 mM octylglucoside, 2 mM CaCl₂, 1 mM PMSF inPBS for 60 min on ice. The resulting extract was filtered throughsterile gauze and centrifuged at 50,000 × g for 30 min. The supernatantwas then recirculated over LM609-Affi-Gel column overnight at4°C. The column was washed with 50 column volumes of 0.1% NonidetP-40, 2 mM CaCl₂ in PBS, followed by 50 column volumes of 0.01M NaHOAc, pH 4.5, 0.1% Nonidet P-40, 2 mM CaCl₂, in PBS. $alpha$ _v $beta$ ₃was then eluted with 0.01 M NaHOAc, pH 3.0, 0.1% Nonidet P-40and 2 mM CaCl₂. The column fractions were rapidly neutralizedby collecting the fractions directly into 3.0 M Tris, pH 8.8.Fractions containing the receptor, as judged by SDS-PAGE, werepooled and concentrated against high molecular weight Polyethyleneglycol. The receptor preparation was then dialyzed against 0.1%Nonidet P-40, 2 mM CaCl₂ in PBS and stored at $-$ 80°C. The identityand purity of the protein was confirmed by Western blot analysiswith monoclonal antibodies specific for $alpha$ _v and $beta$ ₃ subunits.

Solid-phase receptor binding assay. The receptor binding assay was performed as described previously (Orlando and Cheresh, 1991). $alpha$ _v $beta$ ₃ was diluted at 500 ng/mlin coating buffer (20 mM Tris, pH 7.4, 150 mM NaCl, 2 mM CaCl₂,1 mM MgCl₂, 1 mM MnCl₂) and an aliquot of 100 µl/well was addedto a 96-well microtiter plate (Microlite-2 from Dynatech) andincubated overnight at 4°C. The plate was washed once with blocking/bindingbuffer (50 mM Tris, pH 7.4, 100 mM NaCl, 2 mM CaCl₂, 1 mM MgCl₂,1 mM MnCl₂, 1% bovine serum albumin), and incubated an additional2 h at room temperature. The plate was rinsed twice with the samebuffer and incubated with radiolabeled ligand at the indicatedconcentrations for 3 h at room temperature. For coincubations,unlabeled competitor was included at the concentrations described.For preincubations, after the 3-h incubation with radiolabeledligand, the plate was washed three times with blocking/bindingbuffer and further incubated for indicated times in the presenceof either competitor or buffer alone. After an additional threewashes, the plates were counted by liquid scintillation methodwith Top count (Packard, Meriden, CT). When ¹²⁵I-ligand incubations were performed without receptor, no interactionwas detected because of nonspecific adsorption with the microtiterwell. Nonspecific binding of ligand to the receptor was determinedwith molar excess (200-fold) of the unlabeled ligand. Each datapoint is a result of the average of triplicate wells.

Cell lines. HEK-293 cells were maintained in DMEM supplemented with 10% fetal bovine serum (Hazleton, Lenox, KS), 1% glutamine, 1% penicillinand 1% streptomycin (Sigma). Human $alpha$ _v and $beta$ ₃ cDNAs (3.2 kb and2.4 kb in length) were isolated from published sequences (Suzukiet al., 1987; Rosa et al., 1988) by the reverse transcriptase-polymerasechain reaction method with human placental poly(A)⁺ RNA as a template. The identity of the cDNAs were confirmed bypartial sequencing using Sanger's dideoxy method (Fitzgerald etal., 1987a,b). The $alpha$ _v and $beta$ ₃ cDNAs were subcloned into the mammalianexpression vector pcDNA3 (Clontech, Palo Alto, CA) which containsa CMV promoter and a G418 selectable marker. HEK-293 cells weretransfected with equimolar concentrations of $alpha$ _v/pcDNA3 and $beta$ ₃/pcDNA3vectors by the calcium phosphate method (Chen and Okayama, 1987).Stable transfectants were obtained after selection in 800 µg/mlof G418 (Gibco-BRL) for 2 weeks and maintained thereafter in 250µg/ml of G418. Cells expressing high levels of $alpha$ _v $beta$ ₃ receptor wereidentified by FACS with LM609 monoclonal antibodies (Chemicon,Temecula, CA).

FACS analysis. FACS analysis was performed by use of standard protocols. Cells were harvested by ethylenediaminetetraacetic acid (0.02%,Gibco) treatment and washed twice with PBS and resuspended ata concentration of 1 × 10⁶ cells/ml in PBS. Cells were incubated with primary antibodies(1:250 dilution) for 1 h on ice and then washed twice with PBSto remove excess primary antibody. Cells were then incubated withfluorescein isothiocyanate-conjugated rabbit anti-mouse secondaryantibody (1:250 dilution, Zymed, San Francisco, CA) for 1 h onice. Cells were washed twice with PBS and resuspended in PBS forFACS analysis on a Becton Dickinson FACvantage (Mountain View,CA).

Radioligand binding measurements. To determine the affinity of ¹²⁵I-echistatin for $alpha$ _v $beta$ ₃ integrin on 293 cells, binding isotherms of the interaction between radiolabeledechistatin and 293 cells were generated. Echistatin radiolabeledby the lactoperoxidase method to a specific activity of 2000 Ci/mmol(Amersham, Chicago, IL) was used. For binding assays, cells wereharvested and resuspended (2 × 10 ⁶ cells/ml) in adhesion buffer containing 1× Hanks' balanced saltsolution lacking divalent cations, 50 mM HEPES (pH 7.4), 1 mg/mlof bovine serum albumin, .5 mM MnCl₂ and 2 mM CaCl₂. A concentrationrange of ¹²⁵I-echistatin was added to the A4 ( $alpha$ _v $beta$ ₃ $-$ ve) or the B10 ( $alpha$ _v $beta$ ₃ +ve)293 cells in suspension (2 × 10⁵ cells/well) in 96-well microtiter plate (Falcon Microtest III)and the mixture was incubated for 2 h by shaking at room temperature.At the end of the incubation period, the cells were filtered withuse of Millipore Multiscreen-FB (glass fiber type B) plates whichhad been pretreated with 100 µl of 0.3% polyethylenimine solutionfor 2 h. The filters were then washed three times with 100 µlof adhesion buffer. The plates were allowed to dry and the individualfilters were punched out and counted in a gamma counter. Nonspecificbinding was measured in the presence of 200-fold molar excessof echistatin and was subtracted from the total binding to yieldspecific binding. Each data point is an average of values fromtriplicate wells. All measurements were repeated at least threetimes yielding identical results. Bound ligand was calculatedfrom the specific activity of the ligand and the results are presentedas picomoles bound per million cells. Scatchard plots were derivedby plotting bound/free ligand against ligand bound (pmol/millioncells). The binding affinity (K_d) of echistatin to cell surfacebound $alpha$ _v $beta$ ₃ is derived from the slope of the plot (Scatchard, 1943).The K_d values were also calculated by analyzing the data withnonlinear regression by use of Graph Pad Prism (version 2) andidentical results were obtained by both methods (Munson and Rodbard,1980).

Cell adhesion measurements. Forty-eight-well plates (Costar, Cambridge, MA) were coated overnight at 4°C with 20 µg/ml of vitronectin in PBS, followedby blocking nonspecific sites with 1% heat-treated BSA in PBSfor 2 h at 37°C. HEK-293 cells, grown to confluence in 75-cm² flasks, were harvested with trypsin and resuspended in adhesionbuffer (10 mM HEPES, pH 7.4, 140 mM NaCl, 5.4 mM KCl, 5.56 mMglucose, 3% bovine serum albumin, 2 mM CaCl₂, 1 mM MgCl₂, 1 mMMnCl₂) to a density of 5 × 10⁵ cells/ml. Cells were either coincubated with the indicated concentrationsof competitor or allowed to adhere to vitronectin-coated wellsin the absence of competing ligand for 10 min at 37°C. Unboundcells were then removed by rinsing wells three times with adhesionbuffer. Bound cells were quantitated as described previously (Orlandoand Cheresh, 1991). Adherent cells were fixed with 3% paraformaldehydein PBS for 20 min at room temperature. Cells were then rinsedonce with 0.1 M borate buffer, pH 8.5, and stained with 1% crystalviolet in 0.1 M borate buffer, pH 8.5, for 20 min at room temperature.Wells were rinsed four times with 0.1 M borate buffer, and thedye was solubilized with the addition of 10% acetic acid for 20min. The color was quantitated by measuring optical densitiesat 595 nm with a Microtek Plate Reader (Molecular Devices, Sunnyvale,CA).

	Results

Top Abstract Introduction Materials & Methods Results Discussion References

Binding of echistatin to purified $alpha$ _v $beta$ ₃ receptor. To characterize the binding of echistatin to integrin $alpha$ _v $beta$ ₃ receptor in detail, we purified the receptor from human placentawith monoclonal antibody (LM609) affinity chromatography as describedunder "Materials and Methods" (Orlando and Cheresh, 1991). Theidentity and purity of the receptor was assessed by running thepreparation on SDS-polyacrylamide gels followed by Western blotanalysis with monoclonal antibodies specific for $alpha$ _v and $beta$ ₃ subunits(Orlando and Cheresh, 1991). The binding of echistatin to purified $alpha$ _v $beta$ ₃ was measured by a solid-phase receptor binding assay as describedunder "Materials and Methods." As shown in figure 1A, ¹²⁵I-echistatin binds to purified $alpha$ _v $beta$ ₃ in a saturable and specificmanner, because it is effectively competed by coincubation withcold echistatin. Incubation of $alpha$ _v $beta$ ₃ receptor (50 ng) with increasingconcentrations of ¹²⁵I-echistatin resulted in a saturable binding. Nonspecific bindingwas evaluated by carrying out the binding assay in the presenceof a 200-fold molar excess of echistatin and was typically lessthan 10% of the total binding (fig. 1A). Scatchard analysis ofthe binding data gave a linear fit with a K_d of 0.33 nM and B_maxof 750 pmol/mg protein as determined by the ligand computer program(results not shown). As described below, because echistatin bindsto $alpha$ _v $beta$ ₃ in a nondissociable manner, we can only assign an apparentK_d value. The data were also analyzed by nonlinear regressionwith Graph Pad Prism and identical results were obtained (Munsonand Rodbard, 1980).

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Fig. 1. Saturation binding isotherm and competitor concentrations required for half-maximal binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃. (A) Saturation binding isotherms of ¹²⁵I-echistatin binding to $alpha$ _v $beta$ ₃ receptor were determined in a solid-phasereceptor binding assay as described under "Materials and Methods."Integrin $alpha$ _v $beta$ ₃ purified from human placenta was coated at a concentrationof 10 ng/well onto Microlite-2 plates and incubated with variousconcentrations (0.05-5 nM) of ¹²⁵I-echistatin for 3 h at room temperature. Bound ligand concentrationwas determined by solubilizing the counts with boiling 2 N NaOHand was subjected to gamma counting. Nonspecific binding was evaluatedby carrying out the binding assay in the presence of 200-foldmolar excess of cold echistatin and was subtracted from the totalbinding to calculate specific binding. $black-down-triangle$ , total binding; $black-square$ , specificbinding (SP); $black-diamond$ , nonspecific binding (NSP). Each data point isan average of triplicate measurements in which the error was lessthan 5% of the total binding. To derive the affinity of the interactionbetween echistatin and $alpha$ _v $beta$ ₃, the data shown in panel A were analyzedby nonlinear regression analysis with the Graph Pad Prism programand also according to the method of Scatchard (1943)

. (B) Purifiedreceptor was coated onto Microlite-2 plates at a concentrationof 50 ng/well as described above. ¹²⁵I-Echistatin was added to the wells to a final concentration of0.05 nM in binding buffer (50 µl/well) in the presence of competingligand. Cold unlabeled echistatin ( $bullet$ ), GRGDSP ( $black-triangle$ ), and Gpen RGDSp( $black-square$ ) peptides dissolved in binding buffer at the concentrationsindicated were added to the wells before the addition of radioligand.After a 3-h incubation at room temperature, the wells were washedand radioactivity was determined with Top count (Packard). Allmeasurements were done in triplicate with standard deviationsless than 5%.

Next, we wanted to determine the K_i values for the various RGD peptides and echistatin in competition-type experiments bybinding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ receptor. Binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ receptor was competed by cold echistatin,linear RGD and cyclic RGD peptides in a concentration-dependentmanner (fig.1B). A linear hexamer peptide containing RGE sequencedid not compete for the binding of echistatin to $alpha$ _v $beta$ ₃ receptor(data not shown), which confirms the previous results that thebinding of echistatin to $alpha$ _v $beta$ ₃ involves the RGD sequence (Fisheret al., 1993

). The concentrations required for half-maximal competitionsare calculated as 0.27 nM for echistatin, 445 ± 25 nM for linearRGD peptide and 183 ± 17 nM for cyclic peptide containing theRGD sequence.

¹²⁵I-Echistatin binds to $alpha$ _v $beta$ ₃ in a nondissociable manner. Previous studies have shown that vitronectin and fibronectin bind to integrin $alpha$ _v $beta$ ₃ in a nondissociable manner, whereas thebinding of an RGD peptide derived from vitronectin to $alpha$ _v $beta$ ₃ isspecific but is completely dissociable with a K_d of 9.4 × 10⁷ M (Orlando and Cheresh, 1991). The interaction of $alpha$ _v $beta$ ₃ with theligands vitronectin and fibronectin involves the initial integrin-ligandrecognition event, which is RGD dependent and fully dissociable,followed by stabilization of the receptor-ligand complex leadingto a nondissociable interaction between these proteins. To determinethe nature of interaction between ¹²⁵I-echistatin and $alpha$ _v $beta$ ₃ receptor, the radiolabeled ligand was preincubatedwith the receptor for 3 h, the unbound ligand was removed andthe wells were washed with binding buffer, followed by the additionof variable amounts of unlabeled competitors. Under these conditions,the binding of radiolabeled echistatin to $alpha$ _v $beta$ ₃ cannot be competedby cold echistatin, linear RGD and cyclic RGD peptides, whichindicates that radiolabeled ¹²⁵I-echistatin binds to $alpha$ _v $beta$ ₃ in a nondissociable manner (fig. 2A).When 6 mM ethylenediaminetetraacetic acid was added after 10 minof incubation of ¹²⁵I-echistatin with $alpha$ _v $beta$ ₃, there was very little dissociation ofechistatin from $alpha$ _v $beta$ ₃, which suggests that binding is irreversibleeven with shorter incubation times (data not shown). When thecompetition for bound ligand was performed for longer periods(up to 40 h), there was minimal competition by the competing RGDpeptides (fig. 2B), which suggests that binding of echistatinto $alpha$ _v $beta$ ₃ results in a highly stabilized association, similar tovitronectin binding to $alpha$ _v $beta$ ₃. However, the bound ligand can beeluted from the plates by hot SDS solution and the complex canbe dissociated on SDS-PAGE, which suggests that the nature ofbinding is noncovalent (data not shown). When the $alpha$ _v $beta$ ₃ receptorwas saturated with native unlabeled echistatin for 3 h beforeremoving the unbound ligand and replacing it with radiolabeledligand, there was very little binding of the radioligand, whichsuggests that the native echistatin binds to the receptor in anondissociable manner (data not shown).

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Fig. 2. Lactoperoxidase labeled ¹²⁵I-echistatin binds to $alpha$ _v $beta$ ₃ in a nondissociable manner. (A) The binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ was determined by solid-phase receptor assayas described in the legend to figure1. For coincubation conditions,¹²⁵I-echistatin was added to a final concentration of 0.05 nM inthe presence of competing peptides at the concentrations indicated.After a 3-h incubation at room temperature, the wells were washedand radioactivity was determined by gamma-counting. [ $black-square$ , Echistatin(ECH) coincubation; $bullet$ , linear RGD peptide coincubation; $triangle$ , cRGDpeptide coincubation] For preincubation conditions, ¹²⁵I-echistatin was incubated with the receptor for 3 h at room temperature.Wells were washed thoroughly to remove unbound ligand and incubatedfor an additional 3 h at room temperature with 100 µl/well ofblocking/binding buffer containing the indicated concentrationsof competing peptides. ( $black-triangle$ , echistatin preincubation; $square$ , linearRGD peptide preincubation; $down-triangle$ , cRGD peptide preincubation) (B)The dissociability of the lactoperoxidase-labeled ¹²⁵I-echistatin was determined by competition studies by preincubatingthe receptor with radiolabeled echistatin for 3 h and removingthe unbound ligand, washing with binding buffer and then incubatingwith either buffer ( $black-square$ $---$ $black-square$ ). or 50 nM of cold echistatin ( $black-triangle$ $---$ $black-triangle$ ) or500 nM of linear RGD ( $black-down-triangle$ ) or 500 nM of ( $black-diamond$ ) cyclic RGD peptide fordifferent times. The concentration of bound ligand was determinedat various times as described in the legend to figure 1. The amountof labeled ligand bound to $alpha$ _v $beta$ ₃ was given an arbitrary value of100%. All points represent triplicate determinations with an errorof less than 5%.

Association kinetics of echistatin interaction with $alpha$ _v $beta$ ₃ receptor. To further characterize the ligand binding characteristics of $alpha$ _v $beta$ ₃ for echistatin, the association rate for echistatin interactionwith $alpha$ _v $beta$ ₃ was determined. Radiolabeled echistatin binding to $alpha$ _v $beta$ ₃at different time points was determined for several ligand concentrationsby the solid-phase receptor binding assay (fig. 3A). Assumingpseudo first-order kinetics, because the amount of unbound ligandfar exceeded the amount bound, K_obs versus ligand concentrationwas plotted and the rate constant was determined by the slopeof the plot (fig. 3B). The association rate constant for the bindingof echistatin to $alpha$ _v $beta$ ₃ was calculated as 6.33 × 10⁵ s¹ M¹. The values determined for vitronectin and VN-peptide were 9.0× 10³ s¹ M¹ and 1.6 × 10⁴ s¹ M¹, respectively (Orlando and Cheresh, 1991). This result showsthat echistatin binds to $alpha$ _v $beta$ ₃ at a significantly faster rate thaneither vitronectin or the vitronectin-derived peptide. It shouldbe pointed out that the VN-derived peptide is a linear 15-mercontaining the RGD motif, whereas echistatin folds into a rigidcore structure stabilized by four disulfide bridges. The RGD sequenceis located in a mobile loop-like structure enabling it to fitinto the ligand binding site of the receptor.

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Fig. 3. Determination of the association rate constant for echistatin binding to $alpha$ _v $beta$ ₃. (A) To determine the pseudo first-order timecourses, ¹²⁵I-echistatin was incubated with $alpha$ _v $beta$ ₃ at concentrations of 0.05nM ( $triangle$ ), 0.1 nM ( $open circle$ ), 0.2 nM ( $diamond$ ) and 0.5 nM ( $square$ ). At the indicatedtimes, wells were rinsed and radioactivity determined as describedunder "Materials and Methods." Nonspecific binding for each timewas determined by coincubation of ¹²⁵I-echistatin in the presence of excess cold echistatin and represented10% of the total ligand bound. (B) The measurements of the slopesof pseudo first-order time courses (K_obs) versus a range of ligandconcentrations were plotted. The slope of this plot representsthe association rate constant. The R² value for this analysis is 0.973.

Generating stable cell lines to study the binding between echistatin and $alpha$ _v $beta$ ₃ integrin receptor. To characterize the binding of echistatin to $alpha$ _v $beta$ ₃ receptor expressed on the cell surface, we chose the human embryonic kidney293 cells because they lack the $alpha$ _v $beta$ ₃ receptor (Bodary and McLean,1990; Bodary et al., 1989). These cells express the endogenous $alpha$ _v $beta$ ₁ receptor (Bodary and McLean, 1990). Thus the wild-type cellsserve as a model for measuring echistatin binding to $alpha$ _v $beta$ ₁. Togenerate a cell line with which we could measure echistatin bindingto $alpha$ _v $beta$ ₃, the 293 cells were transfected with the pCDNA3 expressionvectors carrying human $alpha$ _v and $beta$ ₃ cDNAs. Stable transfectants obtainedafter selection with G418 were analyzed by FACS analysis withLM 609 monoclonal antibodies that specifically recognize $alpha$ _v $beta$ ₃integrin receptors. The integrin expression profile of the wild-typeand $alpha$ _v $beta$ ₃-transfected 293 cells was compared by FACS analysis.As shown in figure 4, these studies confirm that 293 cells donot express $alpha$ _v $beta$ ₃ because they lack the $beta$ ₃ subunit. However, theydo express the $alpha$ _v subunit, which associates with the $beta$ ₁ subunitto form the $alpha$ _v $beta$ ₁ receptor (fig. 4C). After transfection with the $alpha$ _v and $beta$ ₃ cDNAs, the 293 stable cell line (B10) expresses the $alpha$ _v $beta$ ₃ heterodimer on the cell surface (Fig. 4D). The stable lineB10 displays a 10-fold greater binding of LM 609 antibody thanthe parental 293 cells or the G418 resistant line (A4) that isnegative for $alpha$ _v $beta$ ₃ expression (data not shown).

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Fig. 4. FACS analysis of integrin expression on human embryonic kidney 293 cells. A panel of monoclonal antibodies was used to assessintegrin expression on wild-type and $alpha$ _v and $beta$ ₃ transfected humankidney 293 cells. Cells were incubated with mouse IgG or withthe noted primary antibodies and then with secondary fluoresceinthiocyanate-conjugated goat anti-mouse IgG. After extensive washingto remove free antibody, the cells were analyzed by flow cytometry.The expression level of each integrin subunit is indicated bythe mean fluorescence intensity. The integrin expression profileof wild-type 293 cells was analyzed with mAb LM609 against $alpha$ _v $beta$ ₃integrin receptor (A), 14H4 against $alpha$ _v (B), 550036 mAb against $beta$ ₃ (C). After transfection of 293 cells with cDNAs for $alpha$ _v and $beta$ ₃ subunits in pCDNA3 expression vector, the G418 resistant celllines were analyzed with mAb LM609 (D). Cells negative for $alpha$ _v $beta$ ₃expression (clone A4) and resistant to G418 showed a profile identicalwith wild-type 293 cells (not shown).

Binding of echistatin to $alpha$ _v $beta$ ₃ expressed on 293 cells. To measure the binding of echistatin to $alpha$ _v $beta$ ₃ expressed on the cell surface, $alpha$ _v $beta$ ₃-transfected 293 cells (B10) were harvestedfrom tissue culture flasks, placed in suspension and incubatedwith ¹²⁵I-echistatin for 2 h. G418 resistant line (A4) that is negativefor $alpha$ _v $beta$ ₃ expression was used as a control in these experiments.The B10 cell line binds a 5- to 10-fold higher amount of radiolabeledechistatin than the $alpha$ _v $beta$ ₃ negative A4 clone (fig. 5, A and B).The binding of ¹²⁵I-echistatin to B10 clone is competed by linear and cyclic RGDpeptides, but not by the peptide containing the RGE sequence (fig.5A). Addition of increasing concentrations of radioligand to thecells resulted in a linear increase in the total amount of radioligandbound to the B10 cells (fig. 5B). However, there was no appreciablebinding to the $alpha$ _v $beta$ _{3 (ve)} A4 cells, which suggests thatthe endogenous $alpha$ _v $beta$ ₁ receptor binds poorly to echistatin.

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Fig. 5. Binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ expressed on 293 cells. HEK-293 cells (A4 $alpha$ _v $beta$ ₃ $-$ ve and B10 $alpha$ _v $beta$ ₃ +ve) were harvested from tissueculture flasks and were resuspended in adhesion buffer containing1 mM Mn⁺⁺. ¹²⁵I-Echistatin (1 nM) was added to the cells in the presence ofcompetitors (A). Cold echistatin (5 nM), linear RGD peptide (500nM) and linear RGE peptide (500 nM) were added to the cells beforethe addition of radioligand and the mixture was allowed to incubatewith shaking for 2 h at room temperature. Bound ligand was separatedfrom free ligand by filtration through microtiter plates withglass fiber filters at the bottom of the wells, as described under"Materials and Methods." The wells were washed and radioactivitywas determined by punching the membranes out and counting by gammacounting. Each point is the average of triplicate data pointsand the results shown are a representative of at least three experiments.(B) A4 and B10 cells (2 × 10⁵ cells/well) were incubated with increasing concentration of ¹²⁵I-echistatin for 2 h at room temperature and the bound ligandwas estimated as described above.

To measure the binding affinity of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ receptor expressed on 293 cells, binding isotherms were generatedacross a concentration range of ¹²⁵I-echistatin (fig. 6A) as described under "Materials and Methods."Nonspecific binding was evaluated by carrying out the bindingassay in the presence of 200-fold molar excess of cold echistatinand was typically less than 5% of the total binding. Scatchardanalysis of the binding isotherms revealed that the number ofcell surface binding sites is 56,000 per cell (fig. 6B).

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Fig. 6. A measurement of the binding affinity between ¹²⁵I-echistatin and $alpha$ _v $beta$ ₃ expressed on 293 cells. Isotherms of ¹²⁵I-echistatin binding to $alpha$ _v and $beta$ ₃ cDNA transfected 293 cells (cloneB10) maintained in suspension were generated. Cells were harvestedfrom tissue culture flasks and were resuspended in adhesion buffercontaining 1 mM Mn⁺⁺. ¹²⁵I-Echistatin of increasing concentration was added to the cellsand the mixture was allowed to incubate with shaking for 2 h atroom temperature. Bound ligand was separated from free ligandby filtration as described above. Each point is the average oftriplicate data points, and the isotherm shown represents at leastthree experiments. ( $square$ , total ¹²⁵I-echistatin bound to the receptor; $diamond$ , specific binding; $open circle$ , nonspecificbinding. To derive the number of receptors expressed on 293 cells,the data were replotted according to the method of Scatchard (1943)

.B_max is the x-intercept. The R² value for this analysis is 0.987.

The binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ receptor expressed on 293 cells was competed with unlabeled echistatin, linear RGD peptideand cyclic RGD peptides. Native echistatin competed with a K_iof 0.3 nM, and the K_i values for linear RGD and cyclic RGD peptideswere 9.8 µM and 2.3 µM, respectively (fig. 7). The K_i values obtainedfor linear and cyclic RGD peptides in these experiments were higherthan the values obtained with purified preparations. This canbe explained by the fact that RGD peptides bind nonspecificallyto other integrin receptors, such as $alpha$ _v $beta$ ₁ expressed on 293 cells,whereas echistatin may bind poorly to these other integrins. Hence,higher concentrations of the RGD peptides are required for competingthe binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ receptor expressed on 293 cells.

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Fig. 7. Competitor concentrations required for half-maximal binding of ¹²⁵I-echistatin to $alpha$ _v $beta$ ₃ expressed on HEK-293 cells. Conditions of¹²⁵I-echistatin binding to $alpha$ _v $beta$ ₃ expressed on 293 cells are exactlyas described in the legend to figure 5. ¹²⁵I-Echistatin was added to the cells to a final concentration of1 nM in binding buffer (50 µl/well) in the presence of competingunlabeled echistatin ( $black-square$ ), GRGDSP (linear peptide) ( $black-triangle$ ) and GpenRGDSP (cyclic peptide) ( $black-down-triangle$ ), dissolved in binding buffer at theconcentrations indicated. After a 2-h incubation at room temperaturewith shaking, the bound ligand was separated from free ligandby filtration with microtiter plates with glass fiber filtersin a vacuum manifold. All measurements were done in triplicatewith standard deviations less than 5%.

Echistatin inhibits the adhesion of $alpha$ _v $beta$ ₃ expressing 293 cells to vitronectin matrix. A cell adhesion assay was established as an additional way to examine the ligand binding characteristics of cell surface bound $alpha$ _v $beta$ ₃. We compared the adhesion of parental 293 cells expressing $alpha$ _v $beta$ ₁ receptor versus transfected 293 cells expressing $alpha$ _v $beta$ ₃ receptorby allowing these cells to adhere to immobilized vitronectin orBSA. The transfected cells (B-10 cells) adhered very efficientlyto vitronectin, but did not adhere to echistatin (result not shown)or BSA (fig. 8A). The inability of echistatin to support the adhesionof cells could be caused by its poor binding to plastic, becausepeptides and sometimes even polypeptides of more than 10,000 daltonsshow little or no integrin-binding activity in the adhesion assay.The parental 293 cells adhere very poorly to vitronectin, whichsuggests that the adhesion of B10 cells to vitronectin is mediatedby the transfected $alpha$ _v $beta$ ₃ receptor. The adhesion of B-10 cells tovitronectin can be blocked by echistatin, RGD peptides and LM609antibodies that specifically recognize the $alpha$ _v $beta$ ₃ receptor (fig.8B). Peptides containing the RGE sequence do not compete for adhesionto vitronectin. These results show that echistatin can bind tothe $alpha$ _v $beta$ ₃ receptor efficiently and acts as an antagonist for thisreceptor presumably by competing for the binding of vitronectinto the RGD recognition site.

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Fig. 8. Echistatin antagonizes the adhesion of 293 cells expressing $alpha$ _v $beta$ ₃ receptor. (A) The adhesion of wild-type (open bars) and $alpha$ _vand $beta$ ₃ transfected (dark bars) 293 cells to BSA and vitronectinwas determined as described under "Materials and Methods." Cellswere allowed to attach for 10 min at room temperature to 48-wellplates coated with BSA (3 mg/ml) or vitronectin (10 µg/ml). Eachpoint is the mean ± S.D. of triplicates. Unbound cells were thenremoved by rinsing wells three times with adhesion buffer. Boundcells were quantitated as described under "Materials and Methods."(B) The adhesion of $alpha$ _v $beta$ ₃ transfected 293 cells to vitronectinwas challenged with echistatin (10 µM), linear RGD peptide (10µM), linear RGE peptide (10 µM) and LM609 monoclonal antibodies(10 µg/ml).

	Discussion

Top Abstract Introduction Materials & Methods Results Discussion References

In this study, we have carried out a detailed biochemical characterization of the binding of echistatin to $alpha$ _v $beta$ ₃ receptor.We have shown that echistatin binds to purified $alpha$ _v $beta$ ₃ with highaffinity and that both the native and radiolabeled echistatinbind to $alpha$ _v $beta$ ₃ in an irreversible manner. Hence, one can only assignan apparent K_d value by Scatchard analysis. The apparent K_d valueagrees closely with the K_i value (0.27 nM) for native echistatindetermined by competition experiments. The binding of echistatinto $alpha$ _v $beta$ ₃ is competed by linear and cyclic RGD peptides with K_ivalues of 445 ± 25 nM and 183 ± 17 nM, respectively, which indicatesthat the binding is through the RGD sequence.

Our studies with stable 293 cells expressing $alpha$ _v $beta$ ₃ receptor suggest that echistatin binds poorly to the endogenous $alpha$ _v $beta$ ₁ receptorexpressed on 293 cells. This conclusion is based on the observationthat ¹²⁵I-echistatin binds very poorly to $alpha$ _v $beta$ ₃ negative A4 clone. Thenumber of $alpha$ _v $beta$ ₁ receptors expressed on 293 cells is about 51,000(Hu et al., 1995). This number is similar to the number of $alpha$ _v $beta$ ₃receptors (56,000) expressed in the stable cell line B12. Hencethe lack of binding of echistatin to 293 cells cannot be explainedby the low number of $alpha$ _v $beta$ ₁ receptors expressed on 293 cells. TheK_i value determined for unlabeled echistatin in competition experimentswith 293 cells (0.24 nM) is in agreement with the value obtainedwith purified receptor (0.27 nM), which suggests that echistatinbinds preferentially to $alpha$ _v $beta$ ₃ receptor expressed in the stable293 cells.

Previous studies have shown that ¹²⁵I-vitronectin binds to $alpha$ _v $beta$ ₃ in a nondissociable manner. In contrast, ¹²⁵I-VN-derived peptide containing the RGD sequence rapidly dissociatesfrom the receptor into the aqueous phase with a dissociation rateof 1.6 × 10⁴ s¹ (Orlando and Cheresh, 1991). Vitronectin and VN-derived peptideassociate with the receptor with an association rate of 9.0 ×10³ s¹ M¹ and 1.7 × 10² s¹ M¹, respectively. Thus, vitronectin has a 50-fold higher associationrate than the VN peptide. In contrast, echistatin appears to bindto $alpha$ _v $beta$ ₃ at a much faster rate with a rate constant of 6.33 × 10⁵ s¹ M¹. The structure of echistatin in aqueous solution has been determinedby nuclear magnetic resonance spectroscopy (Saudek et al., 1991).The protein has been shown to fold in a series of irregular loopsto form a rigid core stabilized by four disulfide bridges (Calveteet al., 1992). The RGD sequence is located in a mobile loop atthe tip of the hairpin. Apart from the restriction imposed bythe strands of the hairpin, the RGD recognition site is very mobileand exposed (Saudek et al., 1991; Brockel et al., 1992). Suchbehavior is typical of small segments of proteins whose functionis fast recognition and fitting (Williams, 1989). The hand-in-glovemodel describes how the speed is paid for by somewhat reducedspecificity (Williams, 1978).

It is worth noting an important biochemical distinction between vitronectin and echistatin. Vitronectin exists as a multimercontaining between 12 and 15 moieties per multimer (Bittorf etal., 1993). There is also evidence that multimeric vitronectinis also present in extracellular matrices in vivo. In contrast,echistatin used in these studies is a monomer as determined bymass spectral analysis (data not shown). The multimeric natureof vitronectin results in higher nonspecific binding in solid-phasereceptor binding assays. On the other hand, echistatin shows verylittle nonspecific binding in these assays, and binds to $alpha$ _v $beta$ ₃with high affinity and in an irreversible manner similar to vitronectin.These results suggest that echistatin could be used an alternateligand for high-throughput screening of $alpha$ _v $beta$ ₃ antagonists.

This study demonstrates that even though echistatin is a 49-amino-acid-long peptide, it binds to $alpha$ _v $beta$ ₃ receptor in an irreversiblemanner, similar to vitronectin. It has been shown that the interactionof $alpha$ _v $beta$ ₃ with vitronectin involves the initial integrin-ligandrecognition event, which is RGD dependent and fully dissociablefollowed by stabilization of the integrin-ligand complex leadingto a nondissociable interaction. These results suggested thatthe primary event of integrin $alpha$ _v $beta$ ₃ substrate recognition involvethe binding of the RGD sequence followed by additional molecularinteractions resulting in a highly stabilized receptor-ligandassociation. It is suggested that this stabilized molecular interactionbetween receptor and ligand may be necessary for the transductionof signals between extracellular matrix and the intracellularcompartment. Recently, a hierarchy of molecular responses leadingfrom initial integrin interactions with an extracellular ligand,to trans membrane effects on the localization of cytoskeletalproteins or signaling molecules, to the activation of signalingpathways and to eventual regulation of gene expression, has beendescribed (Miyamoto et al., 1995). Echistatin does not supportthe adhesion of cells because of poor binding to plastic. However,a method by which cytoskeletal and signaling responses to integrin-ligandinteraction with beads coated with a variety of molecules hasbeen described (Miyamoto et al., 1995). It would be interestingto see if the binding of echistatin to $alpha$ _v $beta$ ₃ leads to signal transductionevents similar to vitronectin binding or induces an apoptoticresponse.

	Acknowledgments

We thank Dr. Judy Varner for many helpful discussions and Dr. David Whyte for his comments on the manuscript.

	Footnotes

Accepted for publication July 16, 1997.

Received for publication February 13, 1997.

Send reprint requests to: Dr. C. Chandra Kumar, Dept. of Tumor Biology, Schering Research Institute, 2015, Galloping Hill Road, Kenilworth, NJ 07033.

	Abbreviations

DMEM, Dulbecco's modified Eagle's medium; PMSF, phenylmethylsulfonyl fluoride; SDS, sodium dodecyl sulfate; PBS, phosphate-buffered saline; FACS, fluorescence-activated cell sorter; VN, vitronectin; PAGE, polyacrylamide gel electrophoresis; HEPES, N-2-hydroxyethylpiperazine-N $'$ -2-ethanesulfonic acid.

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Biochemical Characterization of the Binding of Echistatin to Integrin v3 Receptor

Biochemical Characterization of the Binding of Echistatin to Integrin $alpha$ _v $beta$ ₃ Receptor