Binding of [3H]-SK&F 107260 and [3H]-SB 214857 to Purified Integrin alpha IIbbeta 3: Evidence for a Common Binding Site for Cyclic Arginyl-Glycinyl-Aspartic Acid Peptides and Nonpeptides

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Blood Thinners

Vol. 285, Issue 1, 228-235, April 1998

Binding of [³H]-SK&F 107260 and [³H]-SB 214857 to Purified Integrin $alpha$ _IIb $beta$ ₃: Evidence for a Common Binding Site for Cyclic Arginyl-Glycinyl-Aspartic Acid Peptides and Nonpeptides

Angela Wong, Shing Mei Hwang, Kyung Johanson, James Samanen, Donald Bennett, Scott W. Landvatter, Wenting Chen, J. Richard Heys, Fadia E. Ali, Thomas W. Ku, William Bondinell, Andrew J. Nichols, David A. Powers and Jeffrey M. Stadel

Departments of Cellular Biochemistry (A. W., S. M. H.), Protein Biochemistry (K. J.), Macromolecular Sciences (D. B.), Synthetic Chemistry (S. W. L., W. C., J. R. H.), Medicinal Chemistry (J. S., F. A., T. W. K., W. B.), and Pharmacology (A. J. N., D. A. P., J. M. S.), SmithKline Beecham Pharmaceuticals, King of Prussia, Pennsylvania

	Abstract

Top Abstract Introduction Procedures Results Discussion References

The aggregation of activated platelets is mediated by the binding of fibrinogen to its cell surface receptor, the integrin $alpha$ _IIb $beta$ ₃. The recognition of fibrinogen by $alpha$ _IIb $beta$ ₃ depends, in part,on the tripeptide sequence Arg-Gly-Asp (RGD) in the adhesive protein.The interactions of a cyclic RGD-containing pentapeptide, [³H]-SK&F-107260, and a 1,4-benzodiazepine-based nonpeptide [³H]-SB-214857, with purified $alpha$ _IIb $beta$ ₃ have been investigated. Bothcompounds potently inhibit platelet aggregation at submicromolarconcentrations. Binding of both [³H]-SK&F-107260 (K_d = 1.19 nM) and [³H]-SB-214857 (K_d = 1.85 nM) to $alpha$ _IIb $beta$ ₃ is of high affinity andfully reversible. The binding is monophasic, indicating a singleclass of noncooperative binding sites. The two radioligands exhibitedsimilar values in binding to $alpha$ _IIb $beta$ ₃ purified on an RGD-affinitycolumn (B_max = 0.2 mol/mol $alpha$ _IIb $beta$ ₃) or to $alpha$ _IIb $beta$ ₃ purified overa lentil lectin column (B_max = 0.03 mol/mol $alpha$ _IIb $beta$ ₃), suggestingthat SK&F-107260 and SB-214857 interact with the same populationof receptors. Binding of [³H]-SK&F-107260 and [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃ require divalent cations, Mg⁺⁺, Ca⁺⁺ and Mn⁺⁺ are able to support binding, with Mn⁺⁺ being the most effective. Thirteen $alpha$ _IIb $beta$ ₃ antagonists, includingfour linear and three cyclic RGD peptides, five peptidomimetics,the fibrinogen $gamma$ -chain dodecapeptide (HHLGGAKQAGDV) and the snakevenom protein, echistatin, complete for [³H]-SK&F-107260 or [³H]-SB-214857 binding to $alpha$ _IIb $beta$ ₃. The affinity constants (K_i) ofthese compounds, determined by the two radioligand binding assays,are similar. Furthermore, these compounds exhibit the same rankorder of potency in inhibiting biotinylated-fibrinogen bindingto $alpha$ _IIb $beta$ ₃. Scatchard plot analyses of the [³H]-SK&F-107260 binding isotherms in the presence of unlabeledSB-214857 and $gamma$ -chain dodecapeptide reveal competitive-type antagonism,indicating that SB-214857, $gamma$ -chain dodecapeptide and SK&F-107260interact with mutually exclusive binding sites on $alpha$ _IIb $beta$ ₃.

	Introduction

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The platelet integrin, $alpha$ _IIb $beta$ ₃, (also termed fibrinogen receptor and glycoprotein IIb/IIIa) plays a pivotal role in the finalpathway for platelet aggregation and thrombus formation (Marguerieet al., 1980). In response to platelet activation, $alpha$ _IIb $beta$ ₃ bindsfibrinogen, which in turn cross-links other platelets, formingplatelet rich thrombi (Frojmovic et al., 1991). Antagonists of $alpha$ _IIb $beta$ ₃ may be useful for the treatment and prevention of the acutecoronary syndromes of myocardial infarction and unstable anginaas well as the acute-phase response to percutaneous coronary interventions(Topol, 1995).

$alpha$ _IIb $beta$ ₃ interacts with several adhesive proteins in addition to fibrinogen, including von Willebrand factor, vitronectin andfibronectin (Plow and Ginsberg, 1988). The recognition site commonto the adhesive proteins that bind to $alpha$ _IIb $beta$ ₃ contains the tripeptidesequence RGD (Pytela et al., 1996). In addition, fibrinogen hasa second receptor recognition site found at the C-terminus ofthe fibrinogen $gamma$ -chain (HHLGGAKQAGDV) (Kloczewiak et al., 1982).Recombinant fibrinogen with a 20-amino acid insert in place ofthe terminal AGDV sequence was unable to support platelet aggregation(Farrell et al., 1992).

Small peptides containing the sequence RGD have been shown to be $alpha$ _IIb $beta$ ₃ antagonists. Increase in potency was observed whenthe RGD sequence was contained in a conformationally constrainedmolecule (Pierschbacher and Ruoslahti, 1987; Ali et al., 1994;Cheng et al., 1994; Gurrath et al., 1992; Baker et al., 1992).A potent, RGD-containing $alpha$ _IIb $beta$ ₃ antagonist, SK&F-107260, was generatedusing a strategy that produced conformational constraints viacyclization (Ali et al., 1994). The conformational and compositionalfeatures derived from SK&F-107260 were used in the design of apotent nonpeptide $alpha$ _IIb $beta$ ₃ antagonist, SB-207448 (1) (seetable 1 for structure). Compound 1 contains a 1,4-benzodiazepine-2-aceticacid nucleus, which mimics the extended C₇ turn conformation ofthe Gly-Asp moiety in SK&F-107260 (Ku et al., 1993, 1995; Bondinellet al., 1994). Continual optimisation of 1 led to the synthesisof SB-214857, a potent and orally active inhibitor of plateletaggregation (Samanen et al., 1995, 1996). In our study, both SK&F-107260and SB-214857 were radiolabeled with tritium to high specificactivity and were used to characterize direct binding interactionswith purified $alpha$ _IIb $beta$ ₃. Development of the radioligands allowedus to compare the binding domains of peptide and nonpeptide antagonistson $alpha$ _IIb $beta$ ₃.

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TABLE 1
Structure of $alpha$ _IIb $beta$ ₃ antagonists.

	Experimental Procedures

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Synthesis of [³H]-SK&F-107260 and [³H]-SB-214857. [³H]-SK&F-107260 was prepared with tritium in the N-methyl group of the arginine residue. The key intermediate in this synthesis,N^g-mesitylenesulfonyl-[³H]-methylarginine, was prepared in high specific activity tritiumlabeled form by treating methyl N-2,4-dimethoxybenzyl-N^g-mesitylenesulfonylarginate with methyl-[³H] iodide and silver oxide (for a review see Landvatter, 1993).Removal of the dimethoxybenzyl group by catalytic transfer hydrogenation(4.4% formic acid in methanol/Pd black) followed by saponificationgave N^g-mesitylenesulfonyl-[³H]-methylarginine in 32% overall from methyl-[³H] iodide. Successive solution phase coupling to N²-glycyl-N-2(2-[(4-methylphenyl)methylthio]phenyl)-o-phenylmethyl- $alpha$ -aspartamideand (2-carboxyphenyl)-1-ethyldisulfide followed by treatment with`anhydrous hydrogen fluoride gave [³H]-SK&F-107260 at a radiochemical purity of 95.3% after high-performanceliquid chromatography purification and a specific activity of65-85 Ci/mmol.

For the synthesis of [³H]-SB-214857 the starting material A (see table 1 for structure) was tritiated by stirring itunder tritium gas with 1.2 molar equivalent of [Ir(COD)(PPH₃)₂]BF₄in CH₂Cl₂. After high-performance liquid chromatography purification,[³H]-A (146.5 mCi) was hydrolyzed with 5% NaOH in 1:1 meOH/THF.Subsequent treatment with 20% TFA in CH₂Cl₂ afforded [³H]-SB-214857 in 10% overall radiochemical yield after HPLC purification.The specific activity of [³H]-SB-214857 is 22.2 Ci/mmol and the radiochemical purity is 99.7%.

Purification of $alpha$ _IIb $beta$ ₃. Ten units of outdated, washed human platelets (obtained from The American Red Cross, Philadelphia, PA) were lysed by gentlestirring in 3% octylglucoside, 20 mM Tris-HCl, pH 7.4, 140 mMNaCl, 2 mM CaCl₂ at 4°C for 2 hr. The lysate was centrifuged at100,000×g for 1 hr. The supernatant obtained was split in twoequal portions and these were applied to (A) a 5-ml lentil lectinsepharose 4B column (E. Y. Labs, San Mateo, CA) or (B) a 5-mlRGD-affinity column, each preequilibrated with 20 mM Tris-HCl,pH 7.4, 100 mM NaCl, 2 mM CaCl₂, 1% octylglucoside (buffer A).After 2 hr incubation, the column was washed with 50 ml cold bufferA. The lectin-retained glycoproteins were eluted with buffer Acontaining 10% dextrose. Proteins bound to the RGD affinity columnwere eluted with buffer A containing 1 mM of Arg-Gly-Asp-Ser.The RGD affinity chromatography procedure resulted in a ~6-foldenrichment in active receptor compared to the lectin-purifiedmaterial. SDS polyacrylamide gel analysis (Laemmli, 1970) revealedthat the $alpha$ _IIb and $beta$ ₃ subunits constituted >90% of the CoomassieBrilliant Blue-stained protein. Protein determination was basedon absorbance at 280 nm and the moles of $alpha$ _IIb $beta$ ₃ calculated usinga molecular weight of 223.2 kDa. The purified $alpha$ _IIb $beta$ ₃ was incorporatedin mixed phospholipid vesicles (phosphatidylserine:phosphatidylcholine= 7: 3) as described previously (Parise and Phillips, 1985).

Ligand binding to $alpha$ _IIb $beta$ ₃-containing liposomes. Binding assays were performed in a 96-well filtration plate assembly (Millipore Corporation, Bedford, MA) using 0.22-µm hydrophilicdurapore membranes. In saturation binding assays, $alpha$ _IIb $beta$ ₃-containingliposomes were incubated with various concentrations (0.25-30nM, diluted in a binding buffer, containing 20 mM Tris-HCl, pH7.4, 100 mM NaCl and 2 mM CaCl₂) of [³H]-SK&F-107260 (65-86 Ci/mmol) or [³H]-SB-214857 (22 Ci/mmol) at room temperature for 1 hr. For [³H]-SK&F-107260 binding, 0.5 and 0.07 µg of the lentil lectin columnand RGD affinity column-purified receptors, respectively was used.As for [³H]-SB-214857 binding, twice the amount of $alpha$ _IIb $beta$ ₃ was used. Afterthe incubation, receptor-bound [³H]-SK&F-107260 was separated from the unbound by filtration usinga Millipore filtration manifold, followed by washing with ice-coldbinding buffer (three times, each 0.2 ml). Bound radioactivityremaining on the filters was determined in 1.5 ml Ready Safe (Beckman,Fullerton, CA) in a Beckman Liquid Scintillation Counter (modelLS6800), with 40% efficiency. Nonspecific binding was determinedin the presence of 2 µM unlabeled SK&F-107260 or SB-214857. Theprocedures for ¹²⁵I-echistatin (Amersham Corp., Arlington Heights, IL) binding wereidentical to those used for the tritiated ligands. Nonspecificbinding was consistently less than 1% of the total radioactivityadded to the samples. The data presented are representative offive separate receptor preparations or as indicated in the text.All data points are the mean of triplicate determinations. S.D.sof the triplicates were always less than 5% of the mean. Saturationbinding data were analyzed by the LIGAND program (Munson and Rodbard,1980).

In competition binding assays, various concentrations of unlabeled antagonists (0.001-100 µM) were added to the wells, followedby the addition of 4.5 nM of [³H]-SK&F-107260 or [³H]-SB-214857. The lentil lectin purified $alpha$ _IIb $beta$ ₃ (0.5 µg) was routinelyused in competition binding assays. The IC₅₀ (concentration ofthe antagonist to inhibit 50% binding of [³H]-SK&F-107260) was determined by a nonlinear, least squares curve-fittingroutine, which was modified from the LUNDON-2 program (Lundeenand Gordon, 1986

). The K_i (dissociation constant of the antagonist)was calculated according to Cheng and Prusoff (1973)

: K_i = IC₅₀/(1+ L/K_d), where L and K_d were the concentration and the dissociationconstant of [³H]-SK&F-107260, respectively.

Binding of biotinylated-fibrinogen to $alpha$ _IIb $beta$ ₃. Biotinylation of fibrinogen and binding of the biotinylated-adhesive protein to $alpha$ _IIb $beta$ ₃ were performed essentially as describedby Charo et al. (1991).

	Results

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Equilibrium binding of [³H]-SK&F-107260 and [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃. The $alpha$ _IIb $beta$ ₃ used in the binding studies were purified by RGD affinity column chromatography as described in "Experimental procedures."Specific binding of [³H]-SK&F-107260 to the purified $alpha$ _IIb $beta$ ₃ was of high affinity andsaturable. Figure 1A shows a typical example of receptor saturationbinding with increasing concentrations of [³H]-SK&F-107260 in the absence or in the presence of 2 µM unlabeledSK&F-107260. A Scatchard plot (Scatchard, 1949) of the bindingdata indicated a single class of binding sites (fig. 1B), exhibitinga dissociation constant (K_d) of 1.19 ± 0.34 nM and a maximum bindingcapacity (B_max) of 0.24 ± 0.05 mol/mol $alpha$ _IIb $beta$ ₃, as determined fromfive separate experiments.

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Fig. 1. Equilibrium binding of [³H]-SK&F-107260 to $alpha$ _IIb $beta$ ₃. A, The RGD affinity purified, liposome-incorporated $alpha$ _IIb $beta$ ₃ (0.07 µg) was incubated with various concentrations of [³H]-SK&F-107260 for 1 hr at room temperature as described in "Experimental procedure." The amount of total ( $bullet$ ) and specific ( $triangle$ ) radioactivity bound were plotted as a function of the concentration of [³H]-SK&F-107260 added. Nonspecific binding ( $open circle$ ) was determined in the presence of 2 µM unlabeled SK&F-107260. Each point is the mean ± S.E.M. of triplicate determinations. B, The same data was plotted by the method of Scatchard.

[³H]-SB-214857 also demonstrated specific and saturable binding to $alpha$ _IIb $beta$ ₃ (fig. 2A). Scatchard analysis of the binding isothermsrevealed a single binding site of high affinity (K_d = 1.85 ± 0.6nM, from three experiments, fig. 2B). The B_max was 0.28 ± 0.10mol/mol, which was comparable to that determined by the [³H]-SK&F-107260 binding assay. Therefore, [³H]-SK&F-107260 and [³H]-SB-214857 exhibited similar characteristics in binding to purified $alpha$ _IIb $beta$ ₃.

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Fig. 2. Equilibrium binding of [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃. A, Assays conditions were identical to those of [³H]-SK&F-107260 binding, except that 0.15 µg of RGD affinity purified $alpha$ _IIb $beta$ ₃ was used. ( $bullet$ ): total binding; ( $triangle$ ): specific binding; ( $open circle$ ): nonspecific binding. B, Scatchard analysis of the binding data in A.

Binding of [³H]-SK&F-107260, [³H]-SB-214857 and ¹²⁵I-echistatin to the lentil lectin purified $alpha$ _IIb $beta$ ₃. Previous studies have shown that $alpha$ _IIb $beta$ ₃ undergoes conformational changes from low- to high-affinity state during plateletactivation (Marguerie et al., 1979). Similar to the receptor onthe platelet surface, solubilized $alpha$ _IIb $beta$ ₃ exists in at least twodifferent conformations as assessed with specific monoclonal antibodies(Parise et al., 1987; Shattil et al., 1985; Honda et al., 1995).Although fibrinogen and other soluble extracellular matrix proteinsbind selectively to activated $alpha$ _IIb $beta$ ₃, the small RGD peptides andsnake venom peptides, e.g., echistatin, appear to bind to multiplestates of the receptor (Plow and Ginsberg, 1988; Kiewiarowskiet al., 1994; Gan et al., 1988; Savage et al., 1990). It has beenshown that RGD affinity chromatography selectively enriches for $alpha$ _IIb $beta$ ₃ that can bind ligands, whereas a lectin column purifiesthe total receptor population (Konus et al., 1992; Steiner etal., 1989). In our study, we have compared the binding of [³H]-SK&F-107260, [³H]-SB-214857 and ¹²⁵I-echistatin to the RGD-affinity purified and lectin purified $alpha$ _IIb $beta$ ₃.

[³H]-SK&F-107260 and [³H]-SB-214857 exhibited single-component isotherms in binding to the lentil lectin purified $alpha$ _IIb $beta$ ₃, asanalyzed by the method of Scatchard (data not shown). Similarresults were obtained using ¹²⁵I-echistatin as the radioligand (fig. 3). A second, low affinitybinding component was not observed for any of the radioligands.The B_max of the RGD-affinity purified $alpha$ _IIb $beta$ ₃ was approximately6-fold higher than that of the lentil lectin purified receptors(table 2), while the K_d of the two receptor preparations remainedthe same. That [³H]-SK&F-107260 and [³H]-SB-214857 exhibited similar B_max values as ¹²⁵I-echistatin, coupled to the observation of a single class ofbinding sites, suggest that the three radioligands bind indiscriminantlyto the same population of $alpha$ _IIb $beta$ ₃.

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Fig. 3. Scatchard analysis of ¹²⁵I-echistatin binding to lentil lectin-purified $alpha$ _IIb $beta$ ₃. Assay conditions were identical to those used for [³H]-SK&F-107260 binding as described in "Experimental Procedures."

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TABLE 2
Binding of [³H]-SK&F-107260 and [³H]-SB-214857 to the RGD affinity column purified and the lentil lectin purified $alpha$ _IIb $beta$ ₃

Reversible binding of [³H]-SK&F-107260 and [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃. Figure 4 shows that the binding of [³H]-SK&F-107260 or [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃ was completely displaced by 1 µM of either unlabeledSB-214857 or SK&F-107260. Similar results were observed even ifthe receptor was preequilibrated with [³H]-SK&F-107260 or [³H]-SB-214857 for 1 hr before the unlabeled ligands were addedto the incubation. These results demonstrate the reversible natureof [³H]-SK&F-107260 and [³H]-SB-214857 binding to $alpha$ _IIb $beta$ ₃.

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Fig. 4. Reversibility of [³H]-SK&F-107260 and [³H]-SB-214857 binding to $alpha$ _IIb $beta$ ₃. Binding of 2 nM [³H]-SK&F-107260 or 5 nM [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃ was determined under various conditions. $alpha$ _IIb $beta$ ₃ was incubated with the radioligand ligands in the presence or absence of unlabeled SK&F-107260 or SB-214857 for 2 hrs. Alternatively, $alpha$ _IIb $beta$ ₃ was preequilibrated with the radioligands for 1 hr, 2 µM unlabeled SK&F-107260 or SB-214857 was then added, and the samples were incubated for an additional hr. A total of 0.5 µg and 1 µg of the lentil lectin purified $alpha$ _IIb $beta$ ₃ was used in the [³H]-SK&F-107260 and [³H]-SB-214857 binding assays, respectively.

Divalent cation dependency. It has been shown that $alpha$ _IIb $beta$ ₃ contains multiple cation binding sites and that divalent cations regulate the binding of ligandsto $alpha$ _IIb $beta$ ₃ (Gulino et al., 1992; Smith et al., 1994). Binding of[³H]-SK&F-107260 and [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃ also requires divalent cations. Figure5 shows that Mg⁺⁺, Ca⁺⁺ and Mn⁺⁺ are able to support the binding of [³H]-SK&F-107260 and [³H]-SB-214857, with Mn⁺⁺ being more effective.

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Fig. 5. Effects of divalent cations. The lentil lectin purified $alpha$ _IIb $beta$ ₃ was incubated with 3 nM of [³H]-SK&F-107260 (black bars) or 5 nM of [³H]-SB-214857 (gray bars), in a binding buffer containing 0.1 mM EGTA, in the presence or absence of 1 mM divalent cations (Mg⁺⁺, Ca⁺⁺ or Mn⁺⁺).

Competition of unlabeled ligands for the binding of [³H]-SK&F-107260, [³H]-SB-214857 and biotinylated-fibrinogen to $alpha$ _IIb $beta$ ₃. To characterize further the binding of SK&F-107260 and SB-214857 to $alpha$ _IIb $beta$ ₃, competition experiments were performed employinga series of peptide and nonpeptide $alpha$ _IIb $beta$ ₃ antagonists and using[³H]-SK&F-107260 and [³H]-SB-214857 as radioligands. Figure 6A shows the competitioncurve of unlabeled SK&F-107260 for the binding of [³H]-SK&F-107260. The dissociation constant (K_i) for SK&F-107260was determined as 2.2 nM. This value was comparable to the K_dof [³H]-SK&F-107260 obtained in saturation binding experiments shownin figure 1, indicating that the radioactive and nonradioactiveforms of SK&F-107260 have similar properties in receptor-bindingassays. Also shown in figure 6A are the competition curves ofunlabeled SB-214857 and three selected inhibitors (2, 3, 5and the $gamma$ -dodecapeptide, see table 1 for structures). Compound2 and 3 are potent nonpeptide $alpha$ _IIb $beta$ ₃ antagonists,designed and synthesised by a combination of random screeningand structure optimisation (Alig et al., 1992). Peptide 5(SK&F-106760) is a conformationally constrained cyclic RGD peptidethat inhibits platelet aggregation at submicromolar concentrations(Ali et al., 1994). At high concentrations of the inhibitors,binding of [³H]-SK&F-107260 decreased to a plateau, which was less than 5%of total binding. The same set of unlabeled ligands were alsoactive in competing for the binding of [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃ (fig. 6B).

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Fig. 6. Competition binding assays. The lentil lectin purified $alpha$ _IIb $beta$ ₃ was incubated with 4.5 nM [³H]-SK&F-107260 (A) or 5 nM [³H]-SB-214857 (B) in the presence of various concentrations of unlabeled SK&F-107260 ( $bullet$ ), 2 ( $black-square$ ), 3 ( $open circle$ ), 5 ( $triangle$ ), $gamma$ -dodecapeptide ( $black-triangle$ ) and SB-214857 ( $square$ ). The amount of radioligand bound to $alpha$ _IIb $beta$ ₃ was determined by rapid filtration as described in "Experimental Procedures." Each data point is the mean of quadruplicate samples.

Table 3 summarises the K_i values of fourteen $alpha$ _IIb $beta$ ₃ antagonists in competing for the binding of [³H]-SK&F-107260 or [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃. These compounds are selected to providea variety of molecular structures. Echistatin is a snake venomprotein (Gan et al., 1988

); RGDS, GRGDS, GRGDSP and GRGESP arelinear peptides; peptides 5, 6 and SK&F-107260 are cyclicRGD peptides (Ali et al., 1994

); and compounds 1-4 arenonpeptides. Peptide 4 (MK383, L-700,462) is an o-alkylated-L-tyrosineanalogue that inhibits platelet aggregation (Hartman et al., 1992

).Also included is the $gamma$ -dodecapeptide, which is the C-terminalfragment of the $gamma$ -chain of fibrinogen (Kloczewiak et al., 1982

).The K_i values of these $alpha$ _IIb $beta$ ₃ antagonists, determined by the tworadioligand competition binding assays, were nearly identical,suggesting that SK&F-107260 and SB-214857 share a common bindingsite on $alpha$ _IIb $beta$ ₃.

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TABLE 3
Competition of the binding of [³H]-SK&F-107260, [³H]-SB-214857 and biotinylated-fibrinogen to $alpha$ _IIb $beta$ ₃ by antagonists: comparison with inhibition of platelet aggregation

To determine how well [³H]-SK&F-107260 (and [³H]-SB-214857) binding to $alpha$ _IIb $beta$ ₃ reflected the binding interaction of the naturalligand, fibrinogen, to receptor, we have examined the potenciesof the same set of fourteen $alpha$ _IIb $beta$ ₃ antagonists in inhibiting biotinylated-fibrinogenbinding to $alpha$ _IIb $beta$ ₃. The K_i values obtained in the biotinylated-fibrinogenbinding assay are apparent because of the nonlinearity of detectionsignals (Tangemann and Engel, 1995

). Table 3 shows that samerank order of potency for the antagonists is obtained from the[³H]-SK&F-107260 and the biotinylated-fibrinogen binding assays.An excellent correlation (r = 0.992) is observed between the resultsobtained from the [³H]-SK&F-107260 and the biotinylated-fibrinogen binding assays(fig. 7). Therefore, the two binding assays show similar pharmacology.

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Fig. 7. Correlation of affinities values for 13 inhibitors obtained in [³H]-SK&F-107260 and biotinylated-fibrinogen binding assays. ( $bullet$ ): nonpeptides; ( $open circle$ ): cyclic RGD peptides; ( $triangle$ ): linear RGD peptides; ( $black-square$ ) $gamma$ -dodecapeptide; ( $square$ ): echistatin. The slope of the regression line was 0.88, with a correlation coefficient of 0.992.

SB-214857 and $gamma$ -dodecapeptide show competitive inhibition of [³H]-SK&F-107260 binding to $alpha$ _IIb $beta$ ₃. To provide additional evidence that SB-214857 and SK&F-107260 share a common binding site on $alpha$ _IIb $beta$ ₃, we have performed [³H]-SK&F-107260 saturation binding experiments in the presenceof two concentrations of unlabeled SB-214857. As seen in figure8A, SB-214857 appears to be a competitive inhibitor of [³H]-SK&F-107260 as indicated by its ability to decrease the affinityof [³H]-SK&F-107260 for $alpha$ _IIb $beta$ ₃ although not reducing the maximal bindingcapacity. A similar mode of inhibition was observed when the $gamma$ -dodecapeptidewas used, suggesting that it is also a competitive inhibitor ofRGD peptide binding to $alpha$ _IIb $beta$ ₃ (fig. 8B).

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Fig. 8. Scatchard plots of [³H]-SK&F-107260 saturation binding in the presence of antagonists. The lentil lectin purified $alpha$ _IIb $beta$ ₃ (0.5 µg) was used in the assays. The lines drawn represent the best fit to the data determined by linear regression analysis. The concentrations of [³H]-SK&F-107260 used were 0.3 to 10 nM. A, Binding of [³H]-SK&F-107260 in the absence ( $bullet$ ) or presence of 2 nM ( $black-triangle$ ) and 4 nM ( $triangle$ ) of unlabeled SB-214857; B, $gamma$ -dodecapeptide: 25 µM ( $black-triangle$ ), 50 µM ( $triangle$ ) and 100 µM ( $open circle$ ).

	Discussion

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We previously reported the design and synthesis of a highly potent 1,4-benzodiazepine-based nonpeptide $alpha$ _IIb $beta$ ₃ antagonist,1, which displays an atom for atom overlay with the conformationaland compositional features of SK&F-107260 (Ku et al., 1993). In1, an arginine mimetic side chain is attached to the benzodiazepinenucleus at 8 position. We also prepared an isomer of 1in which an arginine mimetic is attached to position 7 of thebenzodiazepine (Ku et al., 1995). Further optimisation of structurein the 7-series provided a potent $alpha$ _IIb $beta$ ₃ antagonist, SB-214857(Samanen et al., 1996). Molecular modeling studies suggest itis possible to superimpose the acid, the benzodiazepine nucleusand the arginine mimetic side chain of SB-214857 with those of1, and with SK&F-107260 (Samanen et al., 1995). Thus, modelingwould predict that SB-214857 binds to $alpha$ _IIb $beta$ ₃ in the same manneras SK&F-107260. To examine this hypothesis in more detail, ourstudy was performed to directly compare the receptor binding of[³H]-SK&F-107260 and [³H]-SB-214857.

Interactions of [³H]-SK&F-107260 and [³H]-SB-214857 with purified $alpha$ _IIb $beta$ ₃ were examined using radioligand binding assays. Twopreparations of purified $alpha$ _IIb $beta$ ₃ were used. The lentil lectin-purifiedmaterial contains the total receptor population, although RGDaffinity chromatography selectively enriches for receptor capableof binding ligands. Previous studies have shown that $alpha$ _IIb $beta$ ₃ canexist in at least two distinct conformational states once solubilized(Parise et al., 1987; Shattil et al., 1985; Honda et al., 1995).We compared the binding of our radioligands using both receptorpreparations to investigate their ability to distinguish multipleforms of the receptor. Our studies revealed that [³H]-SK&F-107260 and [³H]-SB-214857 shared many characteristics in binding to $alpha$ _IIb $beta$ ₃.Both radioligands bind $alpha$ _IIb $beta$ ₃ saturably, reversibly, with highaffinity and require divalent cations. The binding is monophasicfor each radioligand, indicating a single class of noncooperativebinding sites. The B_maxs of binding to two preparations of purified $alpha$ _IIb $beta$ ₃, determined by the [³H]-SK&F-107260 and the [³H]-SB-214857 binding assays are identical, suggesting that theybind to the same population of $alpha$ _IIb $beta$ ₃. Moreover the binding ofour radioligands was comparable to that observed with ¹²⁵I-echistatin (table 2). All three radioligands showed similarB_max values and a single class of binding sites.

Previous work has documented multiple binding sites for divalent cations on $alpha$ _IIb $beta$ ₃ (Gulino et al., 1992; Smith et al., 1994;Loftus et al., 1996). Studies with $alpha$ _IIb $beta$ ₃ and related integrins(Lampugnani et al., 1991; Suehiro et al., 1996) show that divalentcations can differentially regulate ligand binding selectivity.The very similar effects of Ca⁺⁺, Mg⁺⁺ and Mn⁺⁺ on the binding of [³H]-SK&F-107260 and [³H]-SB-214857 to $alpha$ _IIb $beta$ ₃ further support the notion that the radioligandsinteract with the receptor in a similar manner.

To examine whether the two ligands interact with a similar binding region on $alpha$ _IIb $beta$ ₃, competition binding experiments wereperformed with a number of $alpha$ _IIb $beta$ ₃ antagonists using both [³H]-SK&F-107260 and [³H]-SB-214857 as radioligands. These antagonists were selectedbecause of their wide diversity in structures. The K_is determinedfor these antagonists are very similar in each binding assay (table3), suggesting that SB 214857 and SK&F-107260 share a commonbinding site on $alpha$ _IIb $beta$ ₃. More importantly, direct binding studiesindicated that SB-214857 was a competitive inhibitor of SK&F-107260,causing a shift only in the K_d for [³H]-SK&F-107260 binding to $alpha$ _IIb $beta$ ₃ (fig. 8A). The binding of SK&F-107260and SB-214857 to a similar binding site on $alpha$ _IIb $beta$ ₃ suggests thatthe prerequisite for antagonist activity is a molecule that containsbasic and acidic residues spaced appropriately. This is consistentwith the wide structural diversity found in nonpeptide $alpha$ _IIb $beta$ ₃antagonists.

Many of the peptides and nonpeptides listed in table 3 have also been characterized for their ability to inhibit aggregationof human platelets activated with 10 µM ADP. The affinity of ligandsfrom the binding results and the rank order of potency for ligandsto inhibit aggregation are well correlated. Although the rankorder correlates, the absolute potency of ligands in the plateletaggregation assay is apparently lower than the determined bindingaffinity. This is likely due in large part to the presence ofmicromolar amounts of endogenous ligands for $alpha$ _IIb $beta$ ₃, i.e., fibrinogen,fibronectin, von Willebrands factor and thrombospondin found inplasma and released by platelets. However, the data support thehypothesis that RGD peptides and mimetic ligands inhibit plateletaggregation though competitive inhibition of fibrinogen bindingto platelet $alpha$ _IIb $beta$ ₃.

We have also directly examined the competition binding of the $gamma$ -dodecapeptide for [³H]-SK&F-107260 to $alpha$ _IIb $beta$ ₃. Photoaffinity studies demonstrated thatRGD peptides and the $gamma$ -dodecapeptide bind preferentially to the $beta$ ₃ and $alpha$ _IIb subunits, respectively, and therefore may have distinctbinding sites (D'Souza et al., 1988). Our data indicated thatthe $gamma$ -dodecapeptide is an apparent competitive inhibitor, suggestingthat the $gamma$ -dodecapeptide and SK&F-107260 interact with a mutuallyexclusive, or perhaps a common site on $alpha$ _IIb $beta$ ₃.

In summary, we have established radioligand binding assays for $alpha$ _IIb $beta$ ₃ using [³H]-SK&F-107260 and [³H]-SB-214857. Previously we proposed that the 1,4-benzodiazepine-basednonpeptide, SB 214857, is a mimetic of cyclic RGD peptide, SK&F107260, based on compositional and conformational similarities,and now we show that they behave in essentially an identical mannerpharmacologically. Moreover, both ligands display pharmacologicalprofiles similar to the binding of the natural ligand, fibrinogen.These results provide evidence that supports the hypothesis thatSK&F-107260 and SB-214857 bind to a common site on $alpha$ _IIb $beta$ ₃. Thisbinding site is mutually exclusive for the fibrinogen $gamma$ -dodecapeptidesuggesting that this ligand binds to a coupled or overlappingsite on the fibrinogen receptor. Given the quantitative and reproduciblenature of the [³H]-SK&F-107260 and [³H]-SB-214857 binding assays, these radioligands appear to be usefulfor both pharmacological and mechanistic studies of the $alpha$ _IIb $beta$ ₃integrin.

	Footnotes

Accepted for publication December 19, 1997.

Received for publication June 26, 1997.

Send reprint requests to: Dr. Jeffrey M. Stadel, SmithKline Beecham Pharmaceuticals, P.O. Box 1539, 709 Swedeland Road, King of Prussia, PA 19406.

	Abbreviations

$alpha$ _IIb $beta$ ₃, fibrinogen receptor; RGD, arginyl-glycinyl-aspartic acid; [³H]-SK&F-107260, cyclo(S, S)-N-2-mercaptobenzoyl-N-methylarginyl-glycyl-aspartyl-2-mercaptophenyl-amide; SB-214857, (S)-7-([4,4'-bipiperidin]-1-ylcarbonyl)-2,3,4,5-tetrahydro-4-methyl-3-oxo-1H-1,4-benzodiazepine-2-acetic acid; 1, SB-207448, 8-[[[4-(aminoiminomethyl)phenyl]amino]-carbonyl]-2,3,4,5-tetrahydro-3-oxo-4-(2-phenylethyl)-1H-1,4-benzodiazepine-2-aceticacid dihydrochloride; 2, N-[m-(p-amidinobenzamido)]-benzoyl- $beta$ -alanine; 3, [[4-(4-aminoimino-methyl-N-methylbenzamido)acetyl]-o-phenylene]dioxy]-diacetic acid; 4, MK383, N-(butylsulfonyl)-o-[4, (4-piperidinyl)butyl]-L-tyrosine, 5, N-acetyl-cyclo(S,S)-cysteinyl-N-methylarginyl-glycyl-aspartyl-penicillamine-amide; 6, cyclo(1,6)-Prolinyl-arginyl-glycyl-aspartyl-glycyl-D-proline.

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Binding of [3H]-SK&F 107260 and [3H]-SB 214857 to Purified Integrin IIb3: Evidence for a Common Binding Site for Cyclic Arginyl-Glycinyl-Aspartic Acid Peptides and Nonpeptides

Binding of [³H]-SK&F 107260 and [³H]-SB 214857 to Purified Integrin $alpha$ _IIb $beta$ ₃: Evidence for a Common Binding Site for Cyclic Arginyl-Glycinyl-Aspartic Acid Peptides and Nonpeptides