Arginine and cysteine residues in the ligand binding site of alpha 2-adrenergic receptors

alpha 2-Adrenergic receptors were identified in calf brain, human platelet and human uterus membranes by [3H]-rauwolscine binding. The reagents phenylglyoxal (selective for guanidino groups), p- hydroxy mercuribenzoate and N-ethylmaleimide (selective for sulfhydryl groups) caused a time- and dose- dependent decrease in the number of receptor sites. alpha 2-Adrenergic agonists and antagonists mediated efficient protection of the receptors against these reagents. These data suggest that essential arginine and cysteine residues are present at or near the alpha 2-adrenergic binding site.     

Purification and characterization of the human platelet alpha 2-adrenergic receptor

Human platelet alpha 2-adrenergic receptors have been purified approximately 80,000-fold to apparent homogeneity by a five-step chromatographic procedure. The overall yield starting from the membranes is approximately 2%. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis of radioiodinated protein from purified receptor preparations shows a single major band of Mr 64,000. The specific binding activity of the alpha 2-adrenergic receptor after four chromatographic steps is 14.5 nmol/mg protein. This value is consistent with the expected theoretical specific activity (15.6 nmol/mg) for a protein with a molecular mass of 64,000 daltons if it is assumed that there is one ligand-binding site/receptor molecule. The purified protein can be covalently labeled with the alkylating alpha-adrenergic ligand, [3H]phenoxybenzamine. This labeling is specific, and it shows that the Mr 64,000 protein contains the ligand binding site of the alpha 2-adrenergic receptor. In addition, the competitive binding of ligands to the purified receptor protein shows the proper alpha 2-adrenergic specificity. The alpha 2-adrenergic receptor contains an essential sulfhydryl residue. Thus, exposure of the purified receptor to the sulfhydryl-specific reagent, phenylmercuric chloride, resulted in an 80% loss of binding activity. This loss of binding activity was prevented when exposure to phenylmercuric chloride was done in the presence of alpha 2-adrenergic ligands, and it was reversed by subsequent exposure to dithiothreitol. Partial proteolysis of purified alpha 2-adrenergic receptors was obtained with Staphylococcus aureus V-8 protease, alpha-chymotrypsin, and papain. In a comparison with purified beta 2-adrenergic receptors, no common partial proteolytic products were found.     

The ligand binding site of the platelet integrin receptor GPIIb-IIIa is proximal to the second calcium binding domain of its alpha subunit

The extreme carboxyl-terminal amino acid sequence of the gamma chain of fibrinogen is involved in the binding of this adhesive protein to the platelet integrin glycoprotein (GP) IIb-IIIa, and synthetic peptides corresponding to this region inhibit fibrinogen as well as fibronectin and von Willebrand factor binding to platelets. A chemical cross-linking approach was used to characterize the interaction of a 16-amino acid fibrinogen gamma chain peptide with platelets and to localize the site of its binding to GPIIb-IIIa. This peptide became specifically cross-linked to GPIIb, and platelet stimulation selectively enhanced its cross-linking to this alpha subunit. The cross-linking reaction was specifically inhibited by fibrinogen and an Arg-Gly-Asp peptide but not by an unrelated protein or a substituted peptide. Utilizing a combination of immunochemical mapping, enzymatic and chemical digestions, and amino acid sequencing, the cross-linking site of the gamma chain peptide in GPIIb was localized to a stretch of 21 amino acids. The identified region, GPIIb 294-314, contains the second putative calcium binding domain within GPIIb. The primary structure of this region is highly conserved among alpha subunits of other integrin adhesion receptors. These results identify a discrete region of GPIIb that resides in close proximity to a ligand binding site within GPIIb-IIIa. The homologous region may be involved in the functions of other integrin receptors.     

Molecular size of the human platelet alpha 2-adrenergic receptor as determined by radiation inactivation

The size of the alpha 2-adrenergic receptor in human platelet membranes has been determined by radiation inactivation/target size analysis to be 160,000 daltons. The size of the platelet alpha 2-receptors is essentially identical to that of the alpha 1-adrenergic receptor of the rat liver membrane.     

Plasmon-waveguide resonance studies of ligand binding to the human beta 2-adrenergic receptor

Plasmon-waveguide resonance (PWR) spectroscopy is an optical technique that can be used to probe the molecular interactions occurring within anisotropic proteolipid membranes in real time without requiring molecular labeling. This method directly monitors mass density, conformation, and molecular orientation changes occurring in such systems and allows determination of protein-ligand binding constants and binding kinetics. In the present study, PWR has been used to monitor the incorporation of the human beta(2)-adrenergic receptor into a solid-supported egg phosphatidylcholine lipid bilayer and to follow the binding of full agonists (isoproterenol, epinephrine), a partial agonist (dobutamine), an antagonist (alprenolol), and an inverse agonist (ICI-118,551) to the receptor. The combination of differences in binding kinetics and the PWR spectral changes point to the occurrence of multiple conformations that are characteristic of the type of ligand, reflecting differences in the receptor structural states produced by the binding process. These results provide new evidence for the conformational heterogeneity of the liganded states formed by the beta(2)-adrenergic receptor.     

Localization of basic residues required for receptor binding to the single alpha-helix of the receptor binding domain of human alpha2-macroglobulin.

To better understand the structural basis for the binding of proteinase-transformed human alpha2-macroglobulin (alpha2M) to its receptor, we have used three-dimensional multinuclear NMR spectroscopy to determine the secondary structure of the receptor binding domain (RBD) of human alpha2M. Assignment of the backbone NMR resonances of RBD was made using 13C/15-N and 15N-enriched RBD expressed in Escherichia coli. The secondary structure of RBD was determined using 1H and 13C chemical shift indices and inter- and intrachain nuclear Overhauser enhancements. The secondary structure consists of eight strands in beta-conformation and one alpha-helix, which together comprise 44% of the protein. The beta-strands form three regions of antiparallel beta-sheet. The two lysines previously identified as being critical for receptor binding are located in (Lys1374), and immediately adjacent to (Lys1370) the alpha-helix, which also contains an (Arg1378). Secondary structure predictions of other alpha-macroglobulins show the conservation of this alpha-helix and suggest an important role for this helix and for basic residues within it for receptor binding.     

Coupling of the alpha 1-adrenergic receptor to a guanine nucleotide-binding regulatory protein by a discrete domain distinct from its ligand recognition site

At rat hepatic membrane alpha 1-adrenergic receptors, the nonhydrolyzable GTP analogue p[NH]ppG causes a rightward shift of agonist competition curves and a loss of high-affinity binding. This p[NH]ppG effect is consistent with the involvement of a guanine nucleotide-binding regulatory protein (G-protein) in alpha 1-adrenergic receptor signalling. Although readily apparent in membranes prepared to avoid retention of endogenous nucleotides and activation of Ca2+-sensitive proteinases (+pi), this p[NH]ppG effect is not observed in membranes prepared without proteinase inhibitors (-pi), or in -pi membranes treated with Ca2+ (-pi, +Ca2+). In these various membrane preparations, different Mr forms of the receptor are also identified by photoaffinity labeling with [125I]CP65526, an aryl azide analog of the alpha 1-selective antagonist, prazosin, followed by SDS-polyacrylamide gel electrophoresis and autoradiography. Whereas a predominant Mr = 80,000 subunit is identified in +pi membranes, in -pi membranes a proteolytic Mr = 59,000 fragment is also observed. In -pi, +Ca2+ membranes, only this latter peptide is detected. To evaluate the ability of each of these forms of the receptor to couple with a G-protein, the effect of p[NH]ppG on the agonist-inhibition of [125I]CP65526 labelling was determined by laser densitometry scanning and computer analysis. At the Mr = 80,000 subunit, p[NH]ppG causes a rightward shift of agonist competition curves and a loss of high-affinity binding, even in -pi membranes. By contrast, agonist-binding at the Mr = 59,000 subunit is of low-affinity and was not affected by p[NH]ppG. These data indicate that the cleaved Mr = 59,000 fragment, while retaining hormone binding activity is unable to undergo G-protein coupling. Thus, the alpha 1-adrenergic receptor appears to contain a discrete domain necessary for G-protein coupling that is distinct from its ligand recognition site.     

Ligand-induced conformational change in the alpha7 nicotinic receptor ligand binding domain

Molecular dynamics simulations of a homology model of the ligand binding domain of the alpha7 nicotinic receptor are conducted with a range of bound ligands to induce different conformational states. Four simulations of 15 ns each are run with no ligand, antagonist d-tubocurarine (dTC), agonist acetylcholine (ACh), and agonist ACh with potentiator Ca(2+), to give insight into the conformations of the active and inactive states of the receptor and suggest the mechanism for conformational change. The main structural factor distinguishing the active and inactive states is that a more open, symmetric arrangement of the five subunits arises for the two agonist simulations, whereas a more closed and asymmetric arrangement results for the apo and dTC cases. Most of the difference arises in the lower portion of the ligand binding domain near its connection to the adjacent transmembrane domain. The transfer of the more open state to the transmembrane domain could then promote ion flow through the channel. Variation in how subunits pack together with no ligand bound appears to give rise to asymmetry in the apo case. The presence of dTC expands the receptor but induces rotations in alternate directions in adjacent subunits that lead to an asymmetric arrangement as in the apo case. Ca(2+) appears to promote a slightly greater expansion in the subunits than ACh alone by stabilizing the C-loop and ACh positions. Although the simulations are unlikely to be long enough to view the full conformational changes between open and closed states, a collection of different motions at a range of length scales are observed that are likely to participate in the conformational change.     

Mammalian alpha 1-adrenergic receptor. Purification and characterization of the native receptor ligand binding subunit

alpha 1-Adrenergic receptors from a cultured smooth muscle cell line (DDT1 MF-2) have been solubilized with digitonin and purified to apparent homogeneity by sequential chromatography on a biospecific affinity support (Sepharose-A55453 (4-amino-6,7-dimethoxy-2-[4-[5-(4-amino-3-phenyl) pentanoyl]-1-piperazinyl]-quinazoline), an alpha 1 receptor-selective antagonist), a wheat germ agglutinin-agarose gel, and a high performance steric exclusion liquid chromatography column. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography of iodinated purified receptor preparations reveals a peptide with an apparent Mr = 80,000 that co-migrates with the peptide labeled by the specific alpha 1-adrenergic receptor photoaffinity probe 4-amino-6,7-dimethoxy-2-[4-[5-(4-azido-3-[125I]iodophenyl)pentanoyl] -1-piperazinyl] quinazoline. The specific activity (approximately 13,600 pmol of ligand binding/mg of protein) of purified receptor preparations is consistent with that expected for a pure peptide of Mr = 80,000 containing a single ligand binding site. Overall yields approximate 14% of initial crude particulate binding. The purified receptor preparations bind agonist and antagonist ligands with appropriate alpha 1-adrenergic specificity, stereoselectivity, and affinity. Peptide maps of the pure alpha 1-adrenergic receptor and the pure human platelet alpha 2-adrenergic receptor (Regan, J.W., Nakata, H., DeMarinis, R.M., Caron, M.G., and Lefkowitz, R.J. (1986) J. Biol. Chem. 261, 3894-3900) using several different proteases suggest that these two receptors show little if any structural homology.     

Conserved high affinity ligand binding and membrane association in the native and refolded extracellular domain of the human glycine receptor alpha1-subunit

The strychnine-sensitive glycine receptor (GlyR) is a ligand-gated chloride channel composed of ligand binding alpha- and gephyrin anchoring beta-subunits. To identify the secondary and quaternary structures of extramembraneous receptor domains, the N-terminal extracellular domain (alpha1-(1-219)) and the large intracellular TM3-4 loop (alpha1-(309-392)) of the human GlyR alpha1-subunit were individually expressed in HEK293 cells and in Escherichia coli. The extracellular domain obtained from E. coli expression was purified in its denatured form and refolding conditions were established. Circular dichroism and Fourier-transform-infrared spectroscopy suggested approximately 25% alpha-helix and approximately 48% beta-sheet for the extracellular domain, while no alpha-helices were detectable for the TM3-4 loop. Size exclusion chromatography and sucrose density centrifugation indicated that isolated glycine receptor domains assembled into multimers of distinct molecular weight. For the extracellular domain from E. coli, we found an apparent molecular weight compatible with a 15mer by gel filtration. The N-terminal domain from HEK293 cells, analyzed by sucrose gradient centrifugation, showed a bimodal distribution, suggesting oligomerization of approximately 5 and 15 subunits. Likewise, for the intracellular domain from E. coli, a single molecular mass peak of approximately 49 kDa indicated oligomerization in a defined native structure. As shown by [(3)H]strychnine binding, expression in HEK293 cells and refolding of the isolated extracellular domain reconstituted high affinity antagonist binding. Cell fractionation, alkaline extraction experiments, and immunocytochemistry showed a tight plasma membrane association of the isolated GlyR N-terminal protein. These findings indicate that distinct functional characteristics of the full-length GlyR are retained in the isolated N-terminal domain.     

Localization of ligand binding regions of the human formyl peptide receptor

The formyl peptide receptor is involved in the activation of human neutrophils (PMN) and their subsequent response to chemotactic peptides such as FMLP. The normal FMLP receptor has been reported to contain both high and low affinity states and to consist of several glycoprotein components, ranging in size from 40-94 kDa. However, little is known about the functional domains of the receptor. In this study we have constructed synthetic peptides corresponding to different portions of the reported receptor structure, and have tested their involvement in ligand binding. One of these peptides, corresponding to the first extracellular loop of the N-terminus end of the molecule, has been shown to specifically inhibit FMLP binding to PMN membranes. Concomitantly, this peptide exhibited the strongest direct binding to the ligand. We propose that this portion of the FMLP receptor molecule is important in receptor-ligand interactions.     

The multiple membrane spanning topography of the beta 2-adrenergic receptor. Localization of the sites of binding, glycosylation, and regulatory phosphorylation by limited proteolysis

The beta 2-adrenergic receptor (beta-AR) is an integral membrane glycoprotein of apparent Mr approximately equal to 64,000. The amino acid sequence deduced from the beta-AR gene reveals homology with the visual pigment rhodopsin of retinal rod outer segments. We have proposed a structural model of beta-AR which is similar to that elucidated for rhodopsin. In this paper we identify a number of structural and topographical characteristics of beta-AR consistent with the model through the use of limited proteolysis. Limited trypsinization of beta-AR reconstituted in lipid vesicles yields two insoluble (integral membrane) domains of Mr approximately equal to 38,000 and 26,000. Identical results were obtained in intact cells, indicating that the cleavage site of the receptor is accessible at the extracellular surface of the plasma membrane. The amino-terminal domain (38 kDa) contains the ligand binding site (as revealed by photoaffinity labeling) and the sites of glycosylation (as revealed by its sensitivity to endoglycosidase F), whereas the carboxyl-terminal domain (26 kDa) contains all the sites of in vitro phosphorylation by cAMP-dependent protein kinase and the beta-adrenergic receptor kinase. Of four canonical sites for N-linked glycosylation, two near the amino and two near the carboxyl terminus, only those in the amino-terminal domain (Asn6 and Asn15) are utilized and sensitive to endoglycosidase F. Carboxypeptidase Y treatment of reconstituted native beta-adrenergic receptor generates a truncated (approximately 57 kDa) glycopeptide that has lost most of the sites phosphorylated by beta-AR kinase and one of the sites phosphorylated by protein kinase A. The various features delineated, including the length of the carboxypeptidase Y-sensitive region, the extracellular location of the trypsin-sensitive site, the location of the sites of phosphorylation and glycosylation all constrain the receptor to a rhodopsin-like structure with multiple membrane spanning segments.     

Three-dimensional models of alpha(2A)-adrenergic receptor complexes provide a structural explanation for ligand binding.

We have compared bacteriorhodopsin-based (alpha(2A)-AR(BR)) and rhodopsin-based (alpha(2A)-AR(R)) models of the human alpha(2A)-adrenengic receptor (alpha(2A)-AR) using both docking simulations and experimental receptor alkylation studies with chloroethylclonidine and 2-aminoethyl methanethiosulfonate hydrobromide. The results indicate that the alpha(2A)-AR(R) model provides a better explanation for ligand binding than does our alpha(2A)-AR(BR) model. Thus, we have made an extensive analysis of ligand binding to alpha(2A)-AR(R) and engineered mutant receptors using clonidine, para-aminoclonidine, oxymetazoline, 5-bromo-N-(4, 5-dihydro-1H-imidazol-2-yl)-6-quinoxalinamine (UK14,304), and norepinephrine as ligands. The representative docked ligand conformation was chosen using extensive docking simulations coupled with the identification of favorable interaction sites for chemical groups in the receptor. These ligand-protein complex studies provide a rational explanation at the atomic level for the experimentally observed binding affinities of each of these ligands to the alpha(2A)-adrenergic receptor.     

Localization of the receptor binding site of IFN-alpha 2b

The receptor binding site of IFN-alpha is not precisely known. To further characterize this site, mAb against IFN-alpha 2b were selected that block the binding of radiolabeled IFN-alpha 2b to its cell surface receptor. These antibodies also neutralized the anti-viral and anti-proliferative properties of IFN-alpha 2b. A subset of these antibodies (group 1) do not recognize IFN-alpha 2a, either in solid-phase immunoassays or functional assays, whereas a second subset (group 2), with no cross-reactivity with group 1, recognizes both IFN-alpha subtypes. Because IFN-alpha 2b and IFN-alpha 2a differ by only alpha Arg23-Lys23 substitution, group 1 antibodies must recognize an epitope within the receptor binding region of IFN-alpha 2b that includes Arg23. Group 2 antibodies recognize a separate and distinct epitope within the binding site that does not include Arg23.     

Identification and sequence of a binding site peptide of the beta 2-adrenergic receptor

p-(Bromoacetamido)benzyl-1-[125I]iodocarazolol (125I-pBABC) is a potent derivative of the beta-adrenergic receptor antagonist p-aminobenzylcarazolol. Treatment of the receptor with 125I-pBABC results in efficient covalent incorporation of the ligand into the receptor binding site. Extensive degradation of 125I-pBABC-labeled beta 2-adrenergic receptor with either cyanogen bromide or Staphylococcus aureus V8 protease results in specifically labeled fragments having Mr's of about 1600 and 3500, respectively. Because the primary structure of the beta 2-adrenergic receptor is known, and these proteolytic reagents are highly sequence specific, the site of 125I-pBABC incorporation may be deduced from the sizes of the specifically labeled fragments. Thus the fragment generated by cyanogen bromide cleavage corresponds to residues 83-96, a region of 14 amino acids included in the second membrane spanning domain (helix II) of the beta 2-adrenergic receptor. This assignment was confirmed by direct amino acid sequencing of this labeled fragment, though the actual amino acid modified could not be determined. These data permit the assignment of a part of the hormone binding region of the beta 2-adrenergic receptor.     

Characterization of alpha 2-adrenergic receptors in human platelets by binding of a radioactive ligand [3H]yohimbine

[3H]Yohimbine, a potent alpha 2-adrenergic antagonist, was used to label the alpha-adrenergic receptors in membranes isolated from human platelets. Binding of [3H]yohimbine to platelet membranes appears to have all the characteristics of binding to alpha-adrenergic receptors. Binding reached a steady state in 2-3 min at 37 degrees C and was completely reversible upon the addition of excess phentolamine or yohimbine (both at 10(-5) M; t1/2 = 2.37 min). [3H]Yohimbine bound to a single class of noncooperative sites with a dissociation constant of 1.74 nM. At saturation, the total number of binding sites was calculated to be 191 fmol/mg protein. [3H]Yohimbine binding was stereo-specifically inhibited by epinephrine: the (-) isomer was 11-times more potent that the (+) isomer. Catecholamine agonists competed for the occupancy of the [3H]yohimbine-binding sites with an order of potency: clonidine greater than (-)-epinephrine greater than (-)-norepinephrine much greater than (-)-isoproterenol. The potent alpha-adrenergic antagonist, phentolamine, competed for the sites whereas the beta-antagonist, (+/-)-propranolol, was very weak inhibitor. 0.1 mM GTP reduced the binding affinity of the agonists, while producing no change in antagonist-binding affinity. Dopamine and serotonin competed only at very high concentrations. Similarly, muscarinic cholinergic ligands were also poor inhibitors of [3H]yohimbine binding. These results suggest that [3H]yohimbine binding to hunan platelet membranes is specific, rapid, saturable, reversible and, therefore, can be successfully used to label alpha 2-adrenergic receptors.     

Localization of pyrodoxal phosphate binding site on the mero-receptor domain of the glucocorticoid receptor

Previous studies have demonstrated that the vitamin pyridoxal phosphate can alter the physicochemical properties of glucocorticoid receptors. We now report the localization of a pyridoxal phosphate binding site within the mero-receptor domain of this glucocorticoid receptor. Mero-glucocorticoid receptors that are generated by trypsin (10 μg/ml) or chymotrypsin (100 μg/ml) digestion of intact receptors sediment as 2.6 S species on 5–20% sucrose gradients in the presence or absence of pyridoxal phosphate. Mero-glucocoritcoid receptors prepared by exogenous proteinases are hydrophobic and show no affinity for DEAE Bio-Gel A. Treating either trypsin-generated or chymotrypsin-generated mero-receptors with pyridoxal phosphate rapidly converts the proteins (60 and 35%, respectively) into forms that bind to DEAE Bio-Gel A. Induction of DEAE binding is specific to pyridoxal phosphate, for treating mero-receptors with pyridoxal, pyridoxamine or pyridoxine phosphate is ineffective. Furthermore, DEAE binding cannot be induced by adding other pyridoxal phosphate-treated cytosols to untreated mero-receptors. High-resolution polyacrylamide gel isoelectric focussing studies indicated that treating mero-receptor generated by either proteinase with pyridoxal phosphate shifted the isoelectric points of lower pH values. The conversion of the mero-receptor to a more acidic form also occurred when the intact glucocorticoid receptor was treated with the vitamin prior to proteolysis. These studies localize at least one pyridoxal phosphate binding site on the mero-receptor domain of the rat thymocyte glucocorticoid receptor.     

The N-terminal domain of annexin 2 serves as a secondary binding site during membrane bridging

Annexin A2 (AnxA2) is a Ca(2+)- and acidic phospholipid-binding protein involved in many cellular processes. It undergoes Ca(2+)-mediated membrane bridging at neutral pH and has been demonstrated to be involved in an H(+)-mediated mechanism leading to a novel AnxA2-membrane complex structure. We used fluorescence techniques to characterize this H(+)-dependent mechanism at the molecular level; in particular, the involvement of the AnxA2 N-terminal domain. This domain was labeled at Cys-8 either with acrylodan or pyrene-maleimide fluorescent probes. Steady-state and time-resolved fluorescence analysis for acrylodan and fluorescence quenching by doxyl-labeled phospholipids revealed direct interaction between the N-terminal domain and the membrane. The absence of pyrene excimer suggested that interactions between N termini are not involved in the H(+)-mediated mechanism. These findings differ from those previously observed for the Ca(2+)-mediated mechanism. Protein titration experiments showed that the protein concentration for half-maximal membrane aggregation was twice for Ca(2+)-mediated compared with H(+)-mediated aggregation, suggesting that AnxA2 was able to bridge membranes either as a dimer or as a monomer, respectively. An N-terminally deleted AnxA2 was 2-3 times less efficient than the wild-type protein for H(+)-mediated membrane aggregation. We propose a model of AnxA2-membrane assemblies, highlighting the different roles of the N-terminal domain in the H(+)- and Ca(2+)-mediated membrane bridging mechanisms.     

Human platelet alpha 2-adrenergic receptors: labeling with 3H-yohimbine, a selective antagonist ligand

³H-Yohimbine, a potent and selective pharmacological antagonist of α₂-adrenergic receptors, labeled human platelet membrane α₂-receptors with high affinity. Binding was rapid and reversible at 25°C. Both saturation and kinetic experiments indicated a single order of binding sites, with an equilibrium K_D value of 1.0–1.5 nM. Low Mg²⁺ concentrations increased the K_D for ³H-yohimbine without altering the B_max. The ³H-yohimbine site exhibited α₂-receptor specificity: (?)-norepinephrine and (?)-isoproterenol were 4.8 and 330 times less potent than (?)-epinephrine; (?)-catecholamines were 17–35 times more potent than corresponding (+)-catecholamines; the selective α₁-antagonist prazosin was 340 times less potent than yohimbine. Catecholamine agonists exhibited shallow curves in inhibiting ³H-yohimbine binding, with pseudo-Hill coefficients (n_H) of less than 1.0, whereas the n_H of antagonists was 1.0. No specific binding of ³H-prazosin to platelet membranes was observed, indicating the absence of α₁-receptors. ³H-Yohimbine labeled fewer platelet sites than did ³H-dihydroergocryptine under identical conditions (80 vs 130 receptors/ cell), and may be a more specific and useful antagonist probe of platelet α₂-receptors than ³H-dihydroergocryptine.