Minimal sequence requirement of thrombin receptor agonist peptide.

A site-specific proteolytically generated neoamino terminus of the thrombin receptor having a sequence SFLLRNPNDKYEPF- has been reported to be a functional ligand of the receptor. This discovery raises question on the precise structural requirements of the "tethered ligand" responsible for receptor activation and signal transduction. By examining the agonist activity of a panel of synthetic sequence analogues of thrombin receptor agonist peptides (TRAP) on human platelet aggregation, we determined that the minimal sequence of the human platelet thrombin receptor ligand is SFLL-amide (TRAP1-4, EC50 = 300 uM). An extension of TRAP1-4 by an additional Arg-Asn segment yielded the most potent agonist among the series (TRAP1-6, EC50 = 1.3 microM). Based on the structure-activity relationships, we hypothesized a model of the ligand-binding site of the human platelet thrombin receptor that accommodates a hexapeptide structure. TRAP1-6, when administered intravenously, induced marked intravascular platelet aggregation in the anesthetized guinea pigs.     

Tethered ligand agonist peptides. Structural requirements for thrombin receptor activation reveal mechanism of proteolytic unmasking of agonist function.

The human platelet thrombin receptor is activated when thrombin cleaves its receptor's amino-terminal extension to reveal a new amino terminus that functions as a tethered peptide ligand. Exactly how this "agonist peptide domain" remains cryptic within the uncleaved receptor and becomes functional after receptor cleavage is unknown. In this report we define the structural features of the thrombin receptor's agonist peptide domain important for receptor activation. Studies with mutant thrombin receptors have suggested that agonist peptide domain residues 2-6 contained determinants critical for receptor activation, and the synthetic peptide SFLLR-NH2 representing the 1st 5 amino-terminal residues of the agonist peptide domain was sufficient to specify agonist activity. Acetylating or removing the agonist peptide's amino-terminal ammonium group greatly attenuated agonist activity. Agonist peptide residue Phe2 was vital for agonist function; residues Leu4 and Arg5 individually played less important roles. These structure-function relationships held for both platelet activation and activation of the cloned receptor expressed in transfected mammalian cells. Our studies suggest that structures at the extreme amino terminus of the thrombin receptor's agonist peptide domain, in particular the free ammonium group of Ser1 and the phenyl ring of Phe2, are critical for receptor activation and that the agonist function of this domain is expressed when receptor proteolysis unmasks such determinants. In addition to revealing details of the thrombin receptor's proteolytic triggering mechanism, these studies open avenues to the development of drugs targeting the thrombin receptor and to further definition for the role of the thrombin receptor in cellular regulation.     

The thrombin high-affinity binding site on platelets is a negative regulator of thrombin-induced platelet activation. Structure-function studies using two mutant thrombins, Quick I and Quick II.

To elucidate the thrombin domains required for high-affinity binding and platelet activation, the platelet binding properties of thrombin and two mutant thrombins, thrombin Quick I and Quick II, were compared to their agonist effects in elevating intraplatelet [Ca2+]. In Quick I, a mutation within the fibrinogen binding groove results in decreased clotting and platelet aggregating activities, whereas in Quick II, a mutation in the primary substrate binding pocket abolishes both activities. Dysthrombin binding was decreased compared to thrombin. The fibrinogen binding groove appeared more important than the primary substrate pocket for high-affinity binding since Quick I showed drastically reduced, and Quick II only slightly reduced, binding affinity (Kd approximately 200 and approximately 10 nM, respectively). The deduced interaction of thrombin with its high-affinity binding site indicated that the thrombin catalytic site is directed toward the platelet surface and therefore, when bound, is proteolytically inactive. Quick I (0.5-5 nM) elicited intraplatelet [Ca2+] fluxes at concentrations where high-affinity binding was undetectable. Saturation of high-affinity binding sites with active-site-modified thrombin did not affect thrombin-induced (0.5 nM) or Quick I-induced (5 nM) responses. In contrast, addition of D-Phe-Pro-Arg chloromethyl ketone (FPRCK) subsequent to thrombin or Quick I stimulation of platelets abolished agonist-induced responses. Since Quick I was only 10-17% as effective as thrombin in increasing intraplatelet [Ca2+], our data support a model in which thrombin acts enzymatically on a platelet membrane "substrate", through an interaction mediated in part by the fibrinogen binding groove of thrombin. This conclusion is consistent with the inhibition observed with high concentrations (greater than 100 nM) of Quick II and FPRCK-modified thrombin (FPR-thrombin) in platelets stimulated with low concentrations of thrombin (less than 0.5 nM) or Quick I (less than 2 nM), consistent with inhibition by substrate depletion. In contrast, concentrations of FPR-thrombin or Quick II (less than 100 nM), which saturated predominantly the high-affinity binding sites, enhanced the platelet responses induced by thrombin (less than 0.5 nM). Thus, occupation of the high-affinity sites with inactive thrombin increased the concentration of active thrombin available for substrate interaction. Quick I-induced responses were not enhanced, consistent with its inability to interact with the high-affinity site. Since thrombin bound to the high-affinity site is proteolytically inactive, we hypothesize that the thrombin high-affinity binding site on platelets functions to alter thrombin activity and platelet activation.     

Thrombin-induced events in non-platelet cells are mediated by the unique proteolytic mechanism established for the cloned platelet thrombin receptor

We recently isolated a cDNA clone encoding a functional platelet thrombin receptor that defined a unique mechanism of receptor activation. Thrombin cleaves its receptor''s extracellular amino terminal extension, unmasking a new amino terminus that functions as a tethered peptide ligand and activates the receptor. A novel peptide mimicking this new amino terminus was a full agonist for platelet secretion and aggregation, suggesting that this unusual mechanism accounts for platelet activation by thrombin. Does this mechanism also mediate thrombin''s assorted actions on non-platelet cells? We now report that the novel thrombin receptor agonist peptide reproduces thrombin-induced events (specifically, phosphoinositide hydrolysis and mitogenesis) in CCL-39 hamster lung fibroblasts, a naturally thrombin- responsive cell line. Moreover, these thrombin-induced events could be recapitulated in CV-1 cells, normally poorly responsive to thrombin, after transfection with human platelet thrombin receptor cDNA. Our data show that important thrombin-induced cellular events are mediated by the same unusual mechanism of receptor activation in both platelets and fibroblasts, very likely via the same or very similar receptors.     

Activation of platelets by alpha-thrombin is a receptor-mediated event. D-phenylalanyl-L-prolyl-L-arginine chloromethyl ketone-thrombin, but not N alpha-tosyl-L-lysine chloromethyl ketone-thrombin, binds to the high affinity thrombin receptor

Competition binding studies have been carried out to evaluate the antagonism of TLCK-thrombin (N alpha-tosyl-L-lysine chloromethyl ketone-treated thrombin) and PPACK-thrombin (D-phenylalanyl-L-prolyl-L-arginine chloromethyl ketone-treated thrombin) with alpha-thrombin using computer-assisted analysis of the binding isotherms (LIGAND). alpha-Thrombin bound to high, moderate, and low affinity sites as previously described (Harmon, J. T., and Jamieson, G. A. (1985) Biochemistry 24, 58-64). PPACK-thrombin bound to all three sites accessible to alpha-thrombin (K1, 7 nM; R1, 20 sites/platelet; K2, 3 nM; R2, 1800 sites/platelet; K3, 510 nM; R3, 84,000 sites/platelet) as well as to a separate fourth site (Kx, 0.4 nM; Rx, 20 sites/platelet) for PPACK-thrombin that was not accessible to alpha-thrombin. In contrast, TLCK-thrombin did not bind to the high affinity site for alpha-thrombin but bound to the moderate and low affinity sites for alpha-thrombin with similar affinity (K2, 2 nM; R2, 890 sites/platelet; K3, 900 nM; R3, 100,000 sites/platelet) and to another site (Ky, 0.03 nM; Ry, 10 sites/platelet) which was not accessible to alpha-thrombin. As predicted from these binding studies, TLCK-thrombin did not compete with alpha-thrombin for platelet activation at concentrations as high as 1000 nM (500-fold excess). In contrast a 300-fold excess of PPACK-thrombin (670 nM) totally inhibited platelet activation by 2 nM thrombin. These results demonstrate that the high affinity binding site for thrombin on human platelets is a classical receptor, occupancy of which is necessary for platelet activation by low concentrations of thrombin; that TLCK-thrombin does not occupy this high affinity site and hence cannot inhibit platelet activation by alpha-thrombin; and that PPACK-thrombin does compete with alpha-thrombin at the high affinity site and is an antagonist of alpha-thrombin induced activation.     

Effect of thrombin on survival of hippocampal neurons

The effect of thrombin on the rat hippocampal neurons death in model of neurotoxicity induced by hemoglobin or glutamate, was studied. Thrombin (10 nM) was shown to inhibit 100-mkM glutamate--or 10-mkM hemoglobin-induced apoptosis of the rat hippocampal neurons. With the aid of PAR1 (protease-activated receptor1) agonist peptide and PAR1 antagonist, the PAR1 was found to be necessary for protective action of thrombin in hippocampal neurons in models of neurotoxicity induced by hemoglobin or glutamate. Because the prolonged elevation [Ca2+] ib neurons is a critical part of neurodestructive processes in CNS, the effect of thrombin on Ca2+-homeostatis of neurons after its injury by the inducer of neuronal apoptosis: a synthetic agonist of the NMDA receptors N-methyl-D-aspartate (NMDA), was studied. We hypothesized that thrombin via receptors PAR may prove to be neuroprotective for the hippocampus. Thrombin was shown to stimulate via PAR1 a transient increase in [Ca2+] in neurons in a concentration-dependent manner. Thrombin (1 nM) decreased the [Ca2+] signal induced by activation of the NMDA-subtype of glutamate receptors. This thrombin effect may be one of the reasons of the protective action of thrombin in hippocampal neurons.     

Binding of Biotinylated Thrombin Receptor Peptide to Cloned Human Thrombin Receptor Overexpressed in Baby Hamster Kidney Cells

Abstract

Baby hamster kidney (BHK) cells transfected with an expression vector for the human thrombin receptor, and then treated with basic fibroblast growth factor, were found to express specific and saturable binding sites for biotinylated thrombin receptor peptide (SFLLRNPNDKYEPF). Analysis of the binding to live BHK cells yielded an equilibrium dissociation constant (Kd) of 3.0±0.3 μmol/l and a maximal binding capacity (Bmax) of 31.0±0.5 nmol/mg of protein. In competitive binding experiments, the thrombin receptor agonist peptide (SFLLRN), which is a strong inducer of human platelet aggregation, was the most potent competitor. In contrast, position 1 to 2 inverted peptides such as FSLLRNPNDKYEPF and FSLLRNP, which fail to induce for the platelet aggregation, were less potent. This simple and convenient binding assay system using the biotinylated thrombin receptor peptide as a labeled ligand and the cloned thrombin receptor overexpressed in BHK cells may be useful for exploring specific antagonists of the receptor.     

Discovery and initial structure-activity relationships of trisubstituted ureas as thrombin receptor (PAR-1) antagonists

Thrombin is the most potent agonist of platelet activation, and its effects are predominantly mediated by platelet thrombin receptors. Therefore, antagonists of the thrombin receptor have potential utility for the treatment of thrombotic disorders. Screening of combinatorial libraries revealed 2 to be a potent antagonist of the thrombin receptor. Modifications of this structure produced 11k, which inhibits thrombin receptor stimulated secretion and aggregation of platelets.     

The glycocalicin portion of platelet glycoprotein Ib expresses both high and moderate affinity receptor sites for thrombin. A soluble radioreceptor assay for the interaction of thrombin with platelets

A soluble radioreceptor assay has been developed to characterize thrombin receptor activities of the human platelet membrane. 125I-Thrombin was added to platelet membranes solubilized in 1% Triton X-100, and thrombin bound to platelet receptors was separated from free thrombin by precipitation with wheat germ agglutinin (WGA) in the presence of alpha 1-acid glycoprotein as carrier. Both high affinity binding (Ki, 0.09 nM; R1, 0.30 pmol/mg protein) and moderate affinity binding (K2, 38 nM; R2, 72 pmol/mg protein) were detected in the detergent-solubilized membrane preparations and these binding parameters were in excellent agreement with values previously determined using intact platelets (Harmon, J. T., and Jamieson, G. A. (1985) Biochemistry 24, 58-64). Using the soluble radioreceptor assay, both high and moderate affinity binding was detected in highly purified preparations of glycoprotein Ib (GPIb) and glycocalicin, and the binding isotherms were identical with those of the crude detergent-solubilized membrane preparation. Treatment of detergent-solubilized membranes with increasing concentrations of a monospecific polyclonal antibody to glycocalicin resulted in the stepwise depletion of GPIb and concomitant reductions of thrombin binding activity. These results demonstrate that both high and moderate affinity binding of thrombin to platelets is completely expressed in the glycocalicin portion of GPIb.     

A comparative SAR study of thrombin receptor derived non peptide mimetics: Importance of phenyl/guanidino proximity for activity

Summary Thrombin, the most potent physiological platelet agonist interacts with cells through a specific G protein-coupled receptor which has been cloned and sequenced. Synthetic thrombin receptor peptides (TRAPS) comprising the first 5 amino acids (SFLLR and SFLLR-NH₂) of the new N-terminus tethered ligand of the thrombin receptor that is generated by thrombin's proteolytic activity were found to cause full platelet aggregation. During the screening of novel thrombin receptor derived non-peptide mimetics in the platelet aggregation assay we found that 1-phenylacetyl-4-(6-guanidohexanoyl)-piperazine (1) and 1-(6-guanidohexanoyl)-4-(phenylacetylamidomethyl)-piperidine (2) exertedin vitro antagonist activities (56% and 40% correspondingly) as it is depicted by the platelet aggregation assay. Using Molecular Modeling, the synthetic compounds were overlayed with SFFLR. All three superimposed low energy structures had Phe and Arg aminoacids in spatial close proximity. The superimposition results revealed that1 resembled more the stereoelectronic environment of SFLLR than2. This difference may be related to their different antagonist efficacy.     

Potentiation of platelet aggregation by atrial natriuretic peptide

Atrial natriuretic peptide (ANP) has binding sites on a variety of tissues, including human platelets. We have used a new, quenched-flow approach coupled to single-particle counting to investigate the effects of ANP (rat, 1-28) on the initial events (within the first several seconds) following human platelet activation. While ANP alone (1 pM-100 nM) had no effect, ANP significantly potentiated thrombin (0.4 units/ml)-, epinephrine (15 microM)- and ADP (2 or 10 microM)-induced aggregation. Maximum stimulation occurred between 10 to 100 pM. ANP had no influence on the thrombin or ADP-induced increase in platelet volume associated with the "shape change." Since ANP receptors are coupled to a particulate guanylate cyclase and some ANP-induced effects may be mediated through cyclic GMP, we studied how another activator of platelet guanylate cyclase, sodium nitroprusside, affected platelet activation and cyclic nucleotide levels. Sodium nitroprusside (1 microM) inhibited ADP, but not thrombin or epinephrine-induced aggregation. Both sodium nitroprusside (1 microM) and ANP (10 nM) increased cyclic GMP levels by 80% and 37%, respectively, within 60 sec in washed platelets. ANP had no effect on platelet cyclic AMP, while sodium nitroprusside induced a 77% increase. These data suggest that the platelet ANP receptor may be coupled to guanylate cyclase and the rise in cyclic GMP may potentiate platelet function.     

Thromboxane-induced phosphatidate formation in human platelets. Relationship to receptor occupancy and to changes in cytosolic free calcium.

The inter-relationships between receptor occupancy, inositol phospholipid metabolism and elevation of cytosolic free Ca2+ in thromboxane A2-induced human platelet activation were investigated by using the stable thromboxane A2 mimetic, 9,11-epoxymethanoprostaglandin H2, and the thromboxane A2 receptor antagonist, EPO45. 9,11-Epoxymethanoprostaglandin H2 stimulated platelet phosphatidylinositol metabolism as indicated by the rapid accumulation of [32P]phosphatidate and later accumulation of [32P]phosphatidylinositol in platelets pre-labelled with [32P]Pi. These effects of 9,11-epoxymethanoprostaglandin H2 were concentration-dependent and half-maximal [32P]phosphatidate formation occurred at an agonist concentration of 54 +/- 8 nM. With platelets labelled with the fluorescent Ca2+ indicator quin 2, resting cytosolic free Ca2+ was 86 +/- 12 nM. 9,11-Epoxymethanoprostaglandin H2 induced a rapid, concentration-dependent elevation of cytosolic free Ca2+ to a maximum of 300-700 nM. Half-maximal stimulation was observed at an agonist concentration of 80 +/- 23 nM. The thromboxane A2 receptor antagonist EPO45 selectively inhibited 9,11-epoxymethanoprostaglandin H2-induced [32P]phosphatidate formation and elevation of cytosolic free Ca2+, indicating that both events are sequelae of receptor occupancy. Human platelets contain a single class of stereospecific, saturable, high affinity (KD = 70 +/- 13 nM) binding sites for 9,11-epoxymethano[3H]prostaglandin H2. The concentration-response curve for receptor occupancy (9,11-epoxymethano-[3H]prostaglandin H2 binding) is similar to that for 9,11-epoxymethanoprostaglandin H2-induced [32P]phosphatidate formation and for elevation of cytosolic free Ca2+. These observations indicate that human platelet thromboxane A2 receptor occupation is closely linked to inositol phospholipid metabolism and to elevation of cytosolic free Ca2+. Both such events may be necessary for thromboxane A2-induced human platelet activation.     

Tyrosine phosphorylation and association of FcgammaRII and p72(Syk) are not limited to the FcgammaRII signalling pathway

The tyrosine kinase p72(Syk) plays a critical role in platelet signal transduction. It associates with the platelet receptor for the Fc domain of IgGs, FcgammaRII, following stimulation by FcgammaRII cross-linking. Here, we show that p72(Syk) and FcgammaRII tyrosine phosphorylation and association occured following platelet stimulation by: (1) two monoclonal antibodies, which form a bridge between a target antigen and FcgammaRII, and (2) the G-protein-coupled receptor agonist thrombin. The kinetics of the p72(Syk)/FcgammaRII association depended on the signalling pathway (i.e., the antigen targeted or the thrombin receptor). We established a direct relationship between the level of FcgammaRII phosphorylation and the detection of its association with p72(Syk). Inhibition of p72(Syk) by piceatannol resulted in partial or total inhibition of FcgammaRII phosphorylation, after immunological activation or addition of thrombin, respectively, suggesting that p72(Syk) participates in FcgammaRII phosphorylation. The results provide evidence that p72(Syk)/FcgammaRII association is not restricted to immunological activation.     

Boophilus microplus anticoagulant protein: an antithrombin inhibitor isolated from the cattle tick saliva

An anticoagulant was isolated from saliva of the cattle tick Boophilus microplus. Crude saliva prolonged both recalcification time and prothrombin time in assays with bovine plasma. It also inhibited thrombin, but not fXa, amidolytic activity. We purified the antithrombin activity by a combination of gel filtration, anion exchange, and affinity chromatography. The purified inhibitor has a molecular weight of 60,000 Da, determined by SDS-PAGE. The anticoagulant IC50 varied from 100 nM to 1.1 microM, depending on the thrombin concentration and substrate used (fibrinogen or platelet receptor). The excess of inhibitor in relation to thrombin indicates that it is not a tight-binding inhibitor. Chromogenic assays using a panel of five serine-proteinases suggest that the inhibitor is specific against thrombin.     

PAR4, but not PAR1, signals human platelet aggregation via Ca2+ mobilization and synergistic P2Y12 receptor activation

Regulation of platelet activation plays a central role in hemostasis and pathophysiological processes such as coronary artery disease. Thrombin is the most potent activator of platelets. Human platelets express two thrombin receptors, PAR1 and PAR4, both of which signal platelet activation. Evidence is lacking on the mechanism by which PAR1 and PAR4 may differentially signal platelet aggregation. Here we show that at the relatively high concentration of agonist most likely found at the site of a local thrombus, dual inhibition of the P2Y12 receptor and calcium mobilization result in a complete inhibition of PAR4-induced aggregation, while having no effect on either thrombin or PAR1-mediated platelet aggregation. Both PAR1- and PAR4mediated aggregation are independent of calcium mobilization. Furthermore, we show that P2Y12 receptor activation is not required for protease-activated receptor-mediated aggregation at higher agonist concentrations and is only partially required for Rap1 as well as GPIIbIIIa activation. P2Y12 receptor inhibitors clinically in use such as clopidogrel are postulated to decrease platelet aggregation through partial inhibition of PAR1 signaling. Our data, however, indicate that at high local concentrations of thrombin, it is the signaling through PAR4 rather than PAR1 that may be regulated through purinergic feedback. Thus, our data identify an intra-platelet mechanism that may function as a future site for therapeutic intervention.     

Structure and function of the human platelet thrombin receptor. Studies using monoclonal antibodies directed against a defined domain within the receptor N terminus.

Based upon its recently cloned nucleotide sequence, the human platelet thrombin receptor is thought to be formed by a single polypeptide chain with seven transmembrane domains and an extracellular N terminus that can be cleaved by thrombin. As yet, however, little is known from studies of the receptor protein itself. To obtain such information, we have prepared monoclonal antibodies against a peptide corresponding to receptor residues Ser42 through Phe55, the domain immediately distal to the site of cleavage by thrombin. By flow cytometry, all of the antibodies reacted with the thrombin-responsive megakaryoblastic CHRF-288 and HEL cell lines, but not with the T-lymphoid Sup-T1 cell line. Functionally, the antibodies inhibited platelet responses to alpha-thrombin, gamma-thrombin, and trypsin, but had no effect on platelet activation by ADP, epinephrine, or the thromboxane analog U46619. Radioiodinated antibody bound to approximately 1,800 sites/platelet, a value similar to the reported number of moderate affinity thrombin binding sites per platelet. On Western blots, the antibodies recognized a 66-kDa protein in platelet, HEL, and CHRF-288 membranes. The discrepancy between this apparent size and the predicted mass of the receptor suggests that, as with other G protein-coupled receptors, one or more of the potential sites for N-linked glycosylation have been utilized. Therefore, these results suggest that: 1) the cloned thrombin receptor is involved in a broad range of platelet responses to thrombin, as well as gamma-thrombin and trypsin; 2) as predicted, the N terminus of the receptor is accessible on the platelet surface; 3) the moderate affinity thrombin binding site noted in earlier studies may be the receptor; 4) potentially as much as one third of the mass of the receptor is carbohydrate.     

Thrombin receptor-activating peptides (TRAPs): investigation of bioactive conformations via structure-activity, spectroscopic, and computational studies

The thrombin receptor (PAR-1) is an unusual transmembrane G-protein coupled receptor in that it is activated by serine protease cleavage of its extracellular N-terminus to expose an agonist peptide ligand, which is tethered to the receptor itself. Synthetic peptides containing the agonist motif, such as SFLLRN for human PAR-1, are capable of causing full receptor activation. We have probed the possible bioactive conformations of thrombin receptor-activating peptides (TRAPs) by systematic introduction of certain conformational perturbations, involving alpha-methyl, ester psi(COO), and reduced-amide psi(CH2N) scans, into the minimum-essential agonist sequence (SFLLR) to probe the importance of the backbone conformation and amide NH hydrogen bonding. We performed extensive conformational searches of representative pentapeptides to derive families of putative bioactive structures. In addition, we employed 1H NMR and circular dichroism (CD) to characterize the conformational disposition of certain pentapeptide analogues experimentally. Activation of platelet aggregation by our pentapeptide analogues afforded a structure-function correlation for PAR-1 agonist activity. This correlation was assisted by PAR-1 receptor binding data, which gauged the affinity of peptide ligands for the thrombin receptor independent of a functional cellular response derived from receptor activation (i.e. a pure molecular recognition event). Series of alanine-, proline-, and N-methyl-scan peptides were also evaluated for comparison. Along with the known structural features for PAR-1 agonist peptides, our work adds to the understanding of peptide topography relative to platelet functional activity and PAR-1 binding. The absolute requirement of a positively charged N-terminus for strong agonist activity was contradicted by the N-terminal hydroxyl peptide psi(HO)S-FLLR-NH2. The amide nitrogen between residues 1 and 2 was found to be a determinant of receptor recognition and the carbonyl groups along the backbone may be involved in hydrogen bonding with the receptor. Position 3 (P3) of TRAP-5 is known to tolerate a wide variety of side chains, but we also found that the amide nitrogen at this position can be substituted by an oxygen, as in SF-psi(COO)-LLR-NH2, without diminishing activity. However, this peptide bond is sensitive to conformational changes in that SFPLR-NH2 was active, whereas SF-NMeL-LR-NH2 was not. Additionally, we found that position 3 does not tolerate rigid spacers, such as 3-aminocyclohexane-1-carboxylic acid and 2-aminocycloalkane-1-carboxylic acid, as analogues 1A, 1B, 2A, 2B, 3, 4, 5A and 5B lack agonist activity. On the basis of our results, we suggest that an extended structure of the agonist peptide is principally responsible for receptor recognition (i.e. binding) and that hydrophobic contact may occur between the side chains of the second (Phe) and fourth (Leu) residues (i.e. P2-P4 interaction).     

The kinetics of thrombin- and SFLLRN-induced aggregation of human platelets in flow through tubes

The kinetics of aggregation of human platelets activated by alpha-thrombin (0.17-0.35 nM) and the hexapeptide SFLLRN (2-10 microM) was studied in plasma-free washed cell suspensions undergoing Poiseuille flow at 37 degrees C using a previously described double infusion technique. Platelet-rich Tyrodes, prepared from venous blood by multiple centrifugation, and agonist were rapidly mixed in a small chamber and the suspension flowed through various lengths of 1.19 and 0.76 mm diameter polyethylene tubing at mean transit times t from 0.2 to 43 s and mean tube shear rates = 41.9, 335, and 1335 s-1. Effluent was collected in 0.5% glutaraldehyde and single cells and aggregates in the volume range 1-10(5) micron 3 counted and sized using an aperture impedance counter. The rate and extent of aggregation with thrombin increased with increasing [thrombin] and , and although characterized by a small initial lag time, exhibited a very rapid growth of aggregates to macroscopic size, > 10(5) micron 3, at low and moderate shear rates. With SFLLRN, the initial lag times were appreciably longer, but subsequently aggregates also rapidly grew to macroscopic size. We hypothesize that the initial lag time is due to the time required for sufficient secretion and surface organization of ligands such as vWF (known to be released by the platelet) to occur, in order for cross-bridging of the GPIIb-IIIa receptors on adjacent platelets to take place. It appears that thrombin, which, at the low concentrations used, primarily activates the platelet via binding to the GPIb alpha receptor, can more rapidly facilitate secretion of the ligand than SFLLRN, which activates the cell via binding to the seven transmembrane domain receptor.     

Induction of vascular smooth muscle cell growth by selective activation of the thrombin receptor. Effect of heparin.

The synthetic peptide, SFLLRNPNDKYEPF, has been recently described as a peptide mimicking the new amino-terminus created by cleavage of the thrombin receptor, therefore acting as an agonist of the thrombin receptor. This peptide was a potent mitogen for rabbit arterial smooth muscle cells (SMC) and exhibited the same activity as that of native alpha-thrombin. Both compounds stimulated the proliferation of growth-arrested SMCs with half-maximum mitogenic responses at 1 nM. NAPAP, a synthetic inhibitor of the enzymatic activity of thrombin, specifically inhibited thrombin-induced SMC growth (IC50 = 0.35 +/- 0.04 microM) but was without effect on the mitogenic effect of the agonist peptide. These results therefore demonstrate that the mitogenic effect of alpha-thrombin for SMCs is intimately linked to its esterolytic activity. Heparin, which inhibited fetal calf serum-induced SMC growth, was without effect on thrombin-induced SMC growth but strongly reduced the mitogenic effect of the agonist peptide (IC50 = 32 +/- 5 micrograms/ml). This effect was not related to the anti-coagulant activity of heparin but was highly dependent on molecular mass and on the global charge of the molecule and was also observed for other sulphated polysaccharides such as pentosan polysulphate.     

Molecular cloning of a functional thrombin receptor reveals a novel proteolytic mechanism of receptor activation.

We isolated a cDNA encoding a functional human thrombin receptor by direct expression cloning in Xenopus oocytes. mRNA encoding this receptor was detected in human platelets and vascular endothelial cells. The deduced amino acid sequence revealed a new member of the seven transmembrane domain receptor family with a large amino-terminal extracellular extension containing a remarkable feature. A putative thrombin cleavage site (LDPR/S) resembling the activation cleavage site in the zymogen protein C (LDPR/I) was noted 41 amino acids carboxyl to the receptor's start methionine. A peptide mimicking the new amino terminus created by cleavage at R41 was a potent agonist for both thrombin receptor activation and platelet activation. "Uncleavable" mutant thrombin receptors failed to respond to thrombin but were responsive to the new amino-terminal peptide. These data reveal a novel signaling mechanism in which thrombin cleaves its receptor's amino-terminal extension to create a new receptor amino terminus that functions as a tethered ligand and activates the receptor.