A. Defining Proteinase-Activated Receptor Subtypes Using Enzyme and Peptide Agonists

A traditional pharmacological approach to receptor classification (e.g., Ahlquist, 1948) did indeed point to the existence of PAR subtypes (Hollenberg et al., 1993) well before the cloning of all four currently known family members listed in Table 1. As mentioned above, the use of PAR₁APs, and thrombin itself, as receptor probes pointed to a unique set of PARs present on rodent platelets before the successful cloning of PAR₃and PAR₄. Furthermore, upon discovery of PAR₂, it became clear that although trypsin at appropriate concentrations could activate both PAR₂ (<10 U/ml; approximately 20 nM) and PAR₁ (≥50 U/ml; >100 nM), thrombin could not activate PAR₂. Thus, pharmacologically, the PARs can be distinguished on the basis of their relative susceptibility to activation by serine proteinases (principally, thrombin and trypsin), and there is every reason to expect that the use of distinct proteinase families as probes may lead to the discovery of novel proteinase-activated receptor systems that may or may not use a tethered ligand mechanism for activation. Apart from proteinase susceptibility, the most clear-cut molecular characteristic that distinguishes one PAR from another is the sequence of the proteolytically revealed tethered ligand (Table 1). As alluded to above, studies with peptide analogs of the PAR₁APs pointed clearly to the presence of a distinct receptor system in rat gastric and vascular tissues that turned out to be PAR₂ (Hollenberg et al., 1993;Al-Ani et al., 1995). Thus, the PAR-APs have proved to be particularly useful receptor agonist probes. It has been possible to develop peptide agonists that readily distinguish among the four receptor subtypes (Table 1) and can be used as agonists to assess the potential physiological roles that each of the four receptor systems may play in vivo (see below). That said, although such peptides can be shown to be receptor-selective in cell and tissue expression systems (e.g., seeBlackhart et al., 1996; Hollenberg et al., 1999; Kawabata et al., 1999), the comparatively low potency of the PAR-APs (active in the 1–400 μM range), especially for some of the low-potency PAR₄APs (active in the 100–400 μM range), should sound a cautionary note. It is entirely feasible that such PAR-APs could, at elevated concentrations in vivo, activate receptors other than the PARs (e.g., see Roy et al., 1998). Notwithstanding, the use of selected proteinases and selective PAR-APs can serve to distinguish among the PAR subtypes cloned to date.

B. Receptor Antagonists and Receptor Subtypes

The development of receptor-selective antagonists for the PAR family has proved to be an enormous challenge. Initially, the search for antagonists was based on structure-activity studies using the sequence of human PAR₁ (SFLLRN) as a point of departure (Scarborough et al., 1992; Vassallo et al., 1992; Rasmussen et al., 1993; Ceruso et al., 1999), without any knowledge of the existence of receptor subtypes. One of the first such antagonists to be reported (Seiler et al., 1995) based on the SFLLRN motif, 3-mercaptopropionyl-Phe-Cha-Cha-Arg-Lys Pro-Asn-Asp-Lys-amide, was found to block thrombin action on human platelets at low (e.g., <0.05 U/ml) but not high concentrations, possibly because of the then unknown presence of PAR₄ on human platelets. This same compound can act as a PAR₂ agonist. A second PAR₁ peptide antagonist,trans-cinnamoyl-parafluoro-Phe-paraguanidino-Phe-Leu-Arg-amide (BMS 200261, also based on the PAR₁ SFLLRN… sequence), has also been described (Bernatowicz et al., 1996), which will very likely also act as a PAR₂ agonist, since the peptide trans-cinnamoyl-Leu-Ile-Gly Arg-Leu-Orn-amide acts as a relatively potent activator of PAR₂ (Vergnolle et al., 1998). Interestingly, the peptide trans-cinnamoyl-Tyr-Pro-Gly Lys-Phe-amide, based on the murine PAR₄ tethered ligand sequence, can act as a thrombin antagonist in rat platelets (Hollenberg and Saifeddine, 2001; Ma et al., 2001), but the ability of this peptide to block PAR₄ in other species remains to be verified.

Nonpeptide PAR₁ antagonists have also been developed based on an analysis of the molecular conformation of the PAR₁-activating peptide, SFLLRN (Ceruso et al., 1999). The screens for developing PAR₁antagonists have used either functional assays (e.g., thrombin or PAR₁AP-mediated platelet aggregation or calcium signaling) (e.g., Andrade-Gordon et al., 1999; Barrow et al., 2001) or a ligand-binding assay (Ahn et al., 1997, 2000). Surprisingly, the functional inhibition of PAR₁ by an antagonist depends on whether a peptide or thrombin itself is used as an agonist (see below). The use of a peptide modeling approach along with a calcium signaling assay employing thrombin as an agonist led to the synthesis of the PAR₁ antagonist, RWJ56110, based on a 1,3,6-trisubstituted indole template (Andrade-Gordon et al., 1999). This compound behaves as a pure PAR₁antagonist and blocks activation of the receptor by both thrombin and PAR₁APs. This work has led to the development of a second generation antagonist, RWJ58259, based on an indazole rather than an indole template, that has proved more favorable for use in vivo in a balloon angioplasty model of restenosis (Andrade-Gordon et al., 2001; Zhang et al., 2001). Preliminary information [summarized byRotella (2001) and Chackalamannil (2001)] indicates that a number of other groups are also developing PAR₁antagonists; one based on derivatives of 2-amino-4-(3,5-difluorophenyl) isoxazole, which blocks both peptide- and thrombin-induced receptor activation with IC₅₀ values in the 0.1 μM range, and another based on the natural product, himbacine, which exhibits IC₅₀ values in the 10-nM range in a ligand-binding assay. One looks forward to the complete characterization of these new PAR₁ antagonists. Thus, on the whole, it can be said that the development of selective nonpeptide antagonists for PAR₁ is still in its infancy, and it may be some time before such compounds are readily available for the routine evaluation of the role of PAR₁ in physiological processes. The development of effective antagonists for PAR₂ and PAR₄ is still just on the horizon (Hollenberg and Saifeddine, 2001). Notwithstanding, one can predict that PAR antagonists will play a key role in defining the physiological processes that the PARs subserve in vivo.

C. Molecular Definition of Receptor Subtypes

As outlined above (Section III.A.), the best pharmacological distinction among the four known receptor subtypes can be made using receptor-selective PAR-APs, based on the distinct sequences of the revealed tethered ligands. However, the definitive identification of the four PAR subtypes (Table 1) has come from the cloning and sequencing of the four distinct receptors and from studies of mice in which one or other of the receptors has been genetically eliminated. Northern blot analysis has revealed the presence of all four receptor subtypes in a wide range of tissues and cells in which their physiological roles are largely unknown (Table3). PAR₃, as mentioned above, appears to be an unusual puzzle in that murine PAR₃ does not generate a signal on its own but appears to act as a cofactor for the activation of PAR₄(Nakanishi-Matsui et al., 2000; Sambrano et al., 2001). Whether the distinct receptor subtypes cleaved by thrombin (PAR₁, PAR₃, and PAR₄) can play independent physiological roles remains to be determined. PAR₂, activated by trypsin, tryptase, and other serine proteinases, very likely plays a role complementary to the one(s) subserved by PAR₁, PAR₃, and PAR₄ (Nystedt et al., 1994; Böhm et al., 1996b; see below). Now that the receptor subtypes can be identified by molecular probe analysis (in situ hybridization, reverse transcription-polymerase chain reaction, and site-targeted antisera), their presence and actions in a variety of tissues can be explored using both a biochemical and pharmacological approach.

A. The Tethered Ligand Mechanism

One of the first challenges upon discovery of the PAR₁ prototype of this receptor family (Rasmussen et al., 1991; Vu et al., 1991a) was to determine its mechanism of activation. Noting the homology of the N-terminal PAR₁ sequence, LDPR⁴¹S, with the LDPRI sequence responsible for thrombin-mediated activation of protein C, Vu et al. (1991a) established arginine-41 as the main target on PAR₁ for thrombin cleavage, revealing the sequence S⁴²FLLRNPNDKYEPF… upstream of a hirudin-like negatively charged sequence (WEDEEKNES) that serves to increase the binding affinity of thrombin for PAR₁ via the anion-binding exosite domain of thrombin (Vu et al., 1991b). This negatively charged sequence distal to the cleavage/activation site, to which the anion-binding exosite domain of thrombin can interact, is also present in PAR₃but is absent from either PAR₄ or PAR₂. The presence of such a negatively charged sequence may rationalize in part the selectivity of thrombin for cleaving PAR₁ and PAR₃. Vu et al. (1991a) hypothesized that the revealed sequence, SFLLR… , might act as an activator of the receptor. Support of this tethered ligand hypothesis, involving an intramolecular mechanism for the activation of PAR₁ by thrombin, was provided not only by discovering the platelet-activating ability of the putative revealed sequence (SFLLRNPNDKYEPF) as a soluble peptide (Vu et al., 1991a) but also by experiments showing that substitution of the putative thrombin cleavage/activation site (LPDR/S… ) with a cleavage target sequence for enterokinase (DDDDK/S), just upstream from the postulated tethered ligand receptor-activation sequence, resulted in a receptor that could be activated by enterokinase rather than thrombin (Vu et al., 1991b). Moreover, mutating the cleavage/activation site to make it resistant to thrombin proteolysis blocked thrombin-induced receptor activation. Furthermore, in confirming the intramolecular tethered ligand mechanism, it has been demonstrated that a proteolytically revealed ligand on PAR₁ can potentially activate a neighboring PAR (Chen et al., 1994; O'Brien et al., 2000) via an intermolecular mechanism, albeit with lesser efficiency. A thoughtful summary of these intermolecular activation mechanisms for the PARs is found in the review by O'Brien et al. (2001). The tethered ligand mechanism is presumed to activate PAR₂ and PAR₄ since the synthetic peptides based on the revealed sequences are able to activate the two receptors and since for PAR₂, rendering the activation sequence resistant to trypsin cleavage blocked receptor activation (Nystedt et al., 1994). As emphasized above, this tethered ligand mechanism has become the hallmark characteristic of the receptor family. The lack of signal generation by murine PAR₃ itself, which can also be cleaved to reveal a tethered ligand, remains to be explained. It can be suggested that the revealed tethered ligand on PAR₃ may activate other PARs via an intermolecular process.

B. Structure-Activity Relationships for Receptor Activation by the Tethered Ligand Sequences

As already mentioned (Section III.A.), considerable work has been done to explore the structure-activity relationships for the synthetic PAR-APs, based on the distinct tethered ligand sequences of PAR₁, PAR₂, and PAR₄ (Hollenberg et al., 1992, 1993; Scarborough et al., 1992; Vassallo et al., 1992; Natarajan et al., 1995; Faruqi et al., 2000; Maryanoff et al., 2001) (see also Table 1). Surprisingly, very short peptide sequences, only five or six amino acids in length, are sufficient to activate the PARs. Taken together, the structure-activity data obtained with PAR-APs for all of the PARs point to the key importance of the first two amino acid residues of the revealed tethered ligand sequence. For instance, an aromatic residue at position 2, e.g., phenylalanine, is required for the activity of PAR₁APs (e.g., see Natarajan et al., 1995), and a hydrophobic side chain (e.g., leucine or phenylalanine) appears to be required for the activation of PAR₂ by its tethered ligand sequence (Blackhart et al., 1996; Hollenberg et al., 1996; Maryanoff et al., 2001). Furthermore, acylating the N-terminal amino acid of a PAR-AP or merely reversing the order of the first two amino acids [e.g., FSLLR (inactive) versus SFLLR (active) for PAR₁; or LSIGRL (inactive) versus SLGRL (active) for PAR₂] abolishes the ability of the peptides to activate the receptor but does not lead to antagonist activity. Interestingly, substituting a trans-cinnamoyl group for the first amino acid (serine) of either the PAR₁- or PAR₄-activating peptides (but not for PAR₂APs) leads to peptides with antagonist activity for PAR₁ and PAR₄(Bernatowicz et al., 1996; Hollenberg and Saifeddine, 2001; Ma et al., 2001). For the PARs, one can thus envision an interaction between complementary groups on the receptor with the positively charged N-terminal amino group, along with the hydrophobic side chain of the amino acid in the second position of the revealed tethered ligand sequence. Other residues, such as a positively charged lysine or arginine group, found at position 5 of all but one (human PAR₄) of the tethered ligand sequences for mammalian PARs 1, 2, and 4 have also been found to be important for the activity of PAR-APs. That said, the tethered ligands ofXenopus PAR₁ (TFRIFD… ) and human PAR₄ (GYPGQV… ) exhibit a key hydrophobic side chain at position 2 but do not possess a positively charged side chain at position 5. Yet, these peptides are capable of activating human PAR₁ and PAR₄ (albeit with very low potency) (Gerszten et al., 1994; Nanevicz et al., 1995;Faruqi et al., 2000). In this regard, it is interesting to note that a peptide, AFLARAA, which has the hydrophobic and basic side chains of a PAR₁AP as its main features, is a PAR₁ antagonist (Pakala et al., 2000). This peptide might also affect the other PARs.

To make matters more complex, it now appears that the structural requirements for the synthetic peptide sequences acting as free peptides to activate the receptor may differ somewhat from the structure-activity relationships for comparable peptide sequences acting as receptor-tethered ligands. As one example of this situation, Oksenberg and colleagues (Blackhart et al., 2000) found that a mutation in an extracellular domain of human PAR₁ that abrogated the ability of the PAR₁AP, SFLLRNP-amide, to activate the receptor (without abolishing the ability of the receptor to bind the peptide) surprisingly did not affect the ability of thrombin to activate the mutated receptor by revealing the same peptide sequence (SFLLRNP… ) as a tethered ligand. A complementary approach with PAR₂ has shown that a mutation introducing a positive charge into extracellular loop 2 of PAR₂ (see below) markedly reduced the potency of PAR₂ agonists acting as free peptides (e.g., SLIGRL-amide) but had little effect on the potency of trypsin to activate the receptor by unmasking the same sequence as a tethered ligand (Al-Ani et al., 1999). Thus, the conventional thinking about structure-activity relationships in the setting of G-protein-coupled receptors that respond to blood-borne agonists or neurotransmitters (e.g., muscarinic or adrenoreceptor systems) may have to be modified for the analysis of the tethered ligand proteolytically activated PAR family. The differences between the tethered ligand receptor docking mechanism and that of soluble agonists may have important implications for the design of nonpeptide PAR antagonists. In this respect, it is of interest that the PAR₁ antagonist RWJ56110 blocks receptor activation by both thrombin and PAR₁APs (Andrade-Gordon et al., 1999).

C. Receptor Domains Involved in Ligand Activation

Like all other pharmacological receptors, the PARs must perform the dual function of: 1) recognizing the activating ligand (in this case, recognition of both the activating proteinase and the revealed tethered ligand) and 2) triggering an intracellular response. Additionally, since PARs are activated by a tethered ligand that cannot diffuse away, this receptor family must also provide for a rapid shut-off/desensitization mechanism. Insight about the PAR domains involved in ligand activation have come from studies of PAR₁ chimeras (XenopusPAR₁/human PAR₁ and human PAR₁/murine PAR₂) in which the sequence of extracellular loop 2 was found to confer peptide specificity for the activation of the receptor (Fig.2). Thus, substitution of the human PAR₁ extracellular loop 2 (see Fig. 2) intoXenopus PAR₁ conferred on the chimeric receptor a sensitivity toward the human PAR₁AP, SFLLRN-amide, which was otherwise essentially inactive in the wild-typeXenopus PAR₁ (Gerszten et al., 1994;Nanevicz et al., 1995); and substitution of the extracellular loop 2 sequence of murine PAR₂ into human PAR₁ conferred on the chimeric receptor sensitivity to the PAR₂-AP, SLIGRL-amide, which does not activate human PAR₁ (Lerner et al., 1996). In addition, the data of Lerner et al. (1996) point to a possible interaction between the N-terminal extracellular domain of PAR₂ and extracellular loop 3 (see Fig. 2). Furthermore, site mutations in extracellular loop 2 have indicated the importance of the acidic residues, Glu-260 in human PAR₁ and Glu-232/Glu-233 of rat PAR₂, for receptor activation by PAR-APs (Nanevicz et al., 1995; Al-Ani et al., 1999). It has been suggested that there may be an electrostatic interaction between these acidic groups in extracellular loop 2 and the basic arginine side chain at position 5 of the synthetic PAR-APs, providing for a “gating” or direct interaction for receptor activation (Nanevicz et al., 1995;Al-Ani et al., 1999). Other acidic groups in the extracellular domain of human PAR₁, one in loop 2 (Asp-256) and another in the third extracellular loop (Glu-347), have also been found to play a role in receptor activation by synthetic PAR-APs (Blackhart et al., 2000). Furthermore, a short amino-terminal sequence (residues 83 to 93) in human PAR₁ (but not in PAR₂) has been found to play a role in receptor activation by peptide agonists (Bahou et al., 1994; Nanevicz et al., 1995; Lerner et al., 1996). An important role for other nonacidic residues in extracellular loop 2 of PAR₂ has been heralded by the discovery of a dysfunctional polymorphic form of human PAR₂ with a phenylalanine to serine mutation at position 240 of loop 2 (Compton et al., 2000). This polymorphic receptor exhibits a reduced sensitivity to trypsin activation and an altered responsiveness to PAR-APs (Compton et al., 2000). In summary, much evidence points to a key role for extracellular loop 2 of PAR₁ and PAR₂ (and by extension, probably PAR₄) in the action of synthetic receptor-activating peptides. Whether the structural determinants for activation of this interesting extracellular domain of the PARs by synthetic peptides will be the same for activation of the receptor by the proteolytically revealed tethered ligand remains to be explored in depth. This aspect of PAR function, which is unique in comparison to other G-protein-coupled receptors, is an area that merits an extensive evaluation in the future.

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Figure 2

Schematic diagram of a PAR with domains thought to play a role in receptor signaling shown by checkering. The diagram is an amalgamation of the data obtained to date with PAR₁ and PAR₂. There is limited information on PAR₃ and PAR₄. For all of the PARs, with the exception of PAR₃, the tethered ligand (TL) is central to receptor activation following proteinase unmasking. Each tethered ligand exhibits specificity for its cognate receptor, except for PAR₁, where its TL peptide sequence also shows agonist activity toward PAR₂. For PAR₁ and PAR₂, extracellular loop 2 (ECL2) has been shown to confer PAR-AP specificity for the receptor, although the role of ECL2 for activation by the proteinase-revealed tethered ligand remains to be confirmed. For PAR₂, there is believed to be an important interaction between the N terminus (NT) and extracellular loop 3 (ECL3) in that substitution of the PAR₂ domains with comparable sequences for PAR₁ results in a loss of receptor function (Lerner et al., 1996). For PAR₁, a short region of the NT (residues 83–93), in addition to an acidic residue on extracellular loop 3, have been demonstrated to play a role in PAR-AP activation (Bahou et al., 1994; Blackhart et al., 2000). Intracellular loop 2 (ICL2) has been proposed to play a role in G-protein coupling for PAR₁ (Verrall et al., 1997), whereas the cytoplasmic tail contains phosphorylation sites that are involved in signal termination and internalization of the receptor (Trejo and Coughlin, 1999; DeFea et al., 2000). PARs possess potential N-linked glycosylation sequons (61) on their NT and ECL2. Not all potential sites of glycosylation are shown. In PAR₂, NT glycosylation has been demonstrated to regulate the ability of mast cell tryptase to activate the receptor (Compton et al., 2001).

D. Signaling, Desensitization, and Receptor Internalization

Once activated by their tethered ligands, the PARs produce a transient signal [e.g., a pulse of elevated intracellular calcium lasting less than 2 min or a transient effect on vascular tension (contraction or relaxation) lasting from 5 to 10 min]. This type of transient response elicited by the PARs differs from responses triggered by many other G-protein-coupled receptor systems, such as the sustained elevation of vascular tension caused by phenylephrine acting via the α-adrenoreceptor. Since, unlike other G-protein-coupled receptors, PARs are continuously exposed to the tethered ligand that cannot diffuse away, these questions arise: 1) how is the receptor rapidly desensitized? and 2) how does the cell recover its cell-surface complement of intact PARs to respond again efficiently to proteinases over time? The answer to these questions, at least insofar as PAR₁ and PAR₂ are concerned (and by extension one may include PAR₄), resides in the sequences of the intracellular receptor domains responsible for G-protein coupling (Verrall et al., 1997), receptor desensitization (Ishii et al., 1994; DeFea et al., 2000), and receptor internalization (Dery et al., 1999; Trejo and Coughlin, 1999; DeFea et al., 2000). All three of the PARs that activate an intracellular signal (PAR₁, PAR₂, and PAR₄) can cause an elevation of intracellular calcium via a presumed G_q/11-mediated process. For PAR₁, a role for intracellular loop 2 has been shown for G_q coupling (Verrall et al., 1997). PAR₁ (but not PAR₄;Faruqi et al., 2000) can couple not only to the G_q family, but also to the pertussis toxin-sensitive G_i (Hung et al., 1992; Swift et al., 2000) resulting in: 1) an inhibition of adenylyl cyclase and 2) presumably other processes, such as ion channel regulation and phospholipase Cβ and cSrc activation triggered by the G_iα/G_βγ subunits (reviewed by Macfarlane et al., 2001). The coupling of PAR₁ to G_q, G_i, or both very likely depends on the cell type and the relative abundance of the two G-proteins. Evidence also suggests that PAR₁ can couple to members of the G_12/13 family (Offermanns et al., 1994). One difficulty in interpreting some of the data in the literature obtained before the discovery of PAR₄ is that thrombin, which can activate both PAR₁ and PAR₄ (e.g., in human platelets, where both receptors are present), was often used as an agonist rather than the receptor-selective PAR-APs. Thus, although it is clear that both PAR₁ and PAR₄ can elevate intracellular calcium, the coupling of the different PARs to other specific members of the G-protein family remains to be established unequivocally. It should be noted further that PAR₁ and PAR₄ can exhibit distinct signaling shut-off and internalization kinetics, due to distinct potential phosphorylation sites in the C-terminal domains of the two receptors (see below and Shapiro et al., 2000). Thus, the kinetics as well as the G-protein-coupling specificity among PAR₁, PAR₂, and PAR₄ will very likely be found to differ. Many of the downstream signal pathway targets that can be activated, including members of the extracellular signal-regulated kinase/mitogen-activated protein kinase/stress-activated protein kinase/c-Jun NH₂-terminal kinase family, Src-family, other tyrosine kinases, and phosphatidylinositol-3 kinase, have been well summarized in a recent review (Macfarlane et al., 2001).

The signal termination and internalization processes have so far been studied primarily for human PAR₁ and PAR₂. For both PAR₁ and PAR₂, site-targeted phosphorylation in the receptor C-terminal domain by either the G-protein-coupled receptor kinases (Krupnick and Benovic, 1998) for PAR₁(Ishii et al., 1994; Shapiro et al., 1996; Hammes et al., 1999; reviewed by Macfarlane et al., 2001) or protein kinase C for PAR₂ (Böhm et al., 1996a), involving subsequent interactions with β-arrestin and dynamin (Dery et al., 1999; DeFea et al., 2000) plays a key role for both signal down-regulation/desensitization and receptor internalization.

The characteristics of PAR trafficking [movement from an intracellular store (in the Golgi) to the plasma membrane, and internalization and recycling] differ in a number of unique respects from the dynamics of other members of the G-protein-coupled receptor family. Unlike the β-adrenoreceptor, PAR₁ in selected cell types appears to have an intracellular reservoir from which the cell-surface receptor can be efficiently replenished via a mechanism regulated by the signaling/internalization process itself (Hein et al., 1994). This “reservoir” of PAR₁ does not appear to be present in all cell types (e.g., platelets; discussed by O'Brien et al., 2001). Furthermore, rather than being recycled to the plasma membrane after activation and internalization, as is the G-protein-coupled receptor for substance P, PAR₁is selectively targeted to the lysosome (Trejo and Coughlin, 1999). Notwithstanding, in some cell environments, a proportion of PAR₁, cleaved and activated by thrombin, appears to become available again at the cell surface in order to still be sensitive to activation by the PAR₁AP, SFLLRN-amide (Hoxie et al., 1993; Hammes and Coughlin, 1999). These data suggest that following activation of PAR₁, the exposed tethered ligand can subsequently become sequestered from activating the receptor further, but the receptor at the cell surface is not desensitized to PAR₁AP activation. Such a mechanism would yet in another way distinguish PAR₁, and very likely, other active members of the PAR family, from most of the other G-protein-coupled receptor families known to date. The subtle distinctions for the desensitization/internalization and trafficking properties among PARs 1, 2, and 4 remain to be determined in detail.

E. Receptor Activation and Proteinase Susceptibility: What Are the Endogenous Proteinase-Activated Receptor Regulators?

Because of its unique “hirudin-like” thrombin-binding domain downstream of the cleavage/activation site, PAR₁is unusually sensitive to thrombin activation compared with PAR₄. Lacking a key proline residue at the P₂ position of the cleavage/activation site, PAR₂ is not activated by thrombin at all. Nonetheless, trypsin, depending on its concentration, is able to activate signaling by all of PAR₁, PAR₂, and PAR₄, indicating susceptibility to serine proteinase cleavage at the R/S (PAR₁ and PAR₂) or G/S (PAR₄) tethered ligand activation site in the three PARs. Since there are also other basic (Lys and Arg) amino acid residues carboxy-terminal to the cleavage/activation sites of the PARs, it is not surprising that other serine proteinases can either activate [e.g., cathepsin G activation of PAR₄ (Sambrano et al., 2000); streptokinase-plasminogen activation of PAR₁ (McRedmond et al., 2000); and granzyme A activation of PAR₁/PAR₄(Suidan et al., 1994)] or disarm the PARs by cleaving the tethered ligand domain from the receptor [e.g., cathepsin G and plasmin disarming of PAR₁ (Kuliopulos et al., 1999;Molino et al., 1995)]. In this regard, trypsin has been found both to activate and disarm PAR₁ (Kawabata et al., 1999), and a small activation of PAR₁ by plasmin can be observed (Vouret-Craviari et al., 1995; Ishihara et al., 1997) as opposed to the main disarming action of plasmin on PAR₁ (above and Kimura et al., 1996). Conceptually, the proteinases, depending on their PAR cleavage targets, can act as either functional agonists or antagonists. A further level of regulation can occur in the setting of proteinase-inhibitor production (e.g., the serpins). Therefore, an additional singular feature of the PARs, among the G-protein-coupled receptor superfamily, is that the PARs can be seen as having their own endogenous set of functional agonists and antagonists. Like PAR₁, PAR₂ can be activated by serine proteinases other than trypsin [e.g., tryptase (Molino et al., 1997), mite-derived proteinases (der p3/p9; Sun et al., 2001), and factors Xa/VIIa (Bono et al., 2000; Camerer et al., 2000)]. In principle, PAR₂, like PAR₁, could also be silenced by cleavage at a point downstream from its tethered ligand (Loew et al., 2000). The restricted activation of PAR₂ by human tryptase, which cannot fully activate glycosylated PAR₂ as does trypsin (Compton et al., 2001), illustrates a novel glycosylation-dependent “control mechanism” for receptor activation that has not been observed for members of other G-protein-coupled receptor families. Whether or not glycosylation of the N-terminal domains of PAR₁ and PAR₄ will alter their susceptibility to selective activation or silencing by other proteinases remains to be determined.

For PAR₁ and PAR₄, it is clear that thrombin can play a key role as the “physiological” receptor activator. In the digestive tract, trypsin is present at concentrations sufficient for it to act as an endogenous PAR activator, depending on the local abundance of tissue-derived trypsin inhibitors (Kong et al., 1997). Furthermore, mast cell tryptase has been suggested as a potential endogenous activator of PAR₂ in humans, although the susceptibility of PAR₂ to tryptase activation in vivo may be restricted. That said, it is known that other members of the trypsin family capable of activating PAR₂ can be detected as proenzymes in a variety of settings [e.g., endothelial trypsinogen 2 (Koshikawa et al., 1997) that could potentially activate PAR₂ (Alm et al., 2000) and a cell-surface serine proteinase termed matriptase (Oberst et al., 2001) or membrane-type serine proteinase-1 (Takeuchi et al., 2000) that can also activate PAR₂]. Thus, as opposed to classical G-protein-coupled receptors that are activated by a select number of endogenous hormones or neurotransmitters, the PARs may be subject to both activation and inhibition (i.e., disarming) by a variety of proteinases, quite apart from the key enzymes (thrombin, trypsins, and tryptase) that are presently considered to be endogenous PAR regulators (see Table 1).

A. Thrombin Targets: Proteinase-Activated Receptors 1, 3, and 4

Quite apart from the its function in the coagulation cascade, the actions of thrombin on a variety of target cells are recognized as key factors in the hemostatic and inflammatory responses to injury. Thus, many of the physiological functions of thrombin are due in large part to the actions of thrombin on platelets, endothelial cells, and leukocytes (Cirino et al., 2000; summarized by Coughlin, 2000;Macfarlane et al., 2001). Many, if not most, of these cellular responses may result from the activation of one or both PAR₁ and PAR₄. However, as pointed out above, thrombin can potentially affect cells via a noncatalytic mechanism involving its chemotactic/mitogenic peptide domains; and thrombin can also activate enzymes, such as pro-matrix metalloproteinase-2 (Lafleur et al., 2001), to affect cell behavior. Furthermore, thrombin can modulate platelet function via a glycoprotein Ib-mediated signaling mechanism that appears to act synergistically with PAR₁ and PAR₄ (Soslau et al., 2001). To distinguish between the ability of thrombin to act via the PARs as opposed to other mechanisms, it has been of enormous value 1) to use PAR-specific agonists (e.g., TFLLR-NH₂ for PAR₁, SLIGRL-NH₂ for PAR₂, or AYPGKF-NH₂ for PAR₄); 2) to evaluate responses in PAR-deficient mice; and 3) to employ selective PAR antagonists that do not exhibit intrinsic activity (Andrade-Gordon et al., 1999; Ahn et al., 2000; Hollenberg and Saifeddine, 2001). This same kind of approach has yielded much information about the potential physiological role(s) that may be subserved by PAR₂ (see below), although a PAR₂ antagonist is not yet available. Stemming from such studies, it is clear that, as anticipated, PAR₁ plays an aggretory and secretory role in human platelets and a role as a regulator of endothelial cell function. What might not have been predicted is that PAR₁can also play an important role in embryonic development via its impact on endothelial cell function (Griffin et al., 2001) and in the process of restenosis after vascular injury (Andrade-Gordon et al., 2001), very likely due to PAR₁-mediated actions on vascular endothelial and smooth muscle cells. The widespread tissue distribution of PAR₁, ranging from the vasculature to the brain, lung, and gastrointestinal tract (Table 3), predicts a multifactorial role for PAR₁, including neurogenic inflammatory responses as well as cardiovascular effects (Cocks and Moffatt, 2000; de Garavilla et al., 2001; summarized byMacfarlane et al., 2001; Vergnolle et al., 2001b). That PAR₁ has been found to be an “oncoprotein” in the sense of conferring a “transformed” phenotype on NIH 3T3 cells (focus formation and anchorage- and serum-independent growth; Martin et al., 2001) and in its ability to modulate cellular invasion (Even-Ram et al., 1998, 2001; Henrikson et al., 1999; Kamath et al., 2001) adds another dimension to the potential roles that PAR₁ may play in the setting of pathophysiology.

The physiological actions of thrombin that are due to PAR₄ activation have yet to be clarified, except as a key for thrombin-mediated aggregation of human and rodent platelets (Kahn et al., 1998, 1999). Experiments with both platelets from PAR₄ −/− mice (Sambrano et al., 2001) and a PAR₄ antagonist in a rat platelet preparation (Hollenberg and Saifeddine, 2001) have unequivocally established this essential role for PAR₄ in the activation of murine and rat platelets by thrombin. That cathepsin G and trypsin (and presumably, other members of the trypsin family) can also efficiently activate PAR₄ indicates that the pathophysiology of PAR₄ may well be broader than the effects of thrombin indicate. Messenger RNA for human PAR₄has been detected in a variety of tissues, with comparatively higher amounts present in human small intestine, liver pancreas, lung, thyroid, and testis, and smaller amounts of message detected in a number of human organs, including the prostate, adrenal gland, and trachea (Xu et al., 1998; see also Table 3). The tissue distribution of PAR₄ mRNA in the mouse appears to differ from that in the human, with larger amounts found in spleen and bone marrow but relatively low expression in liver or testis (Kahn et al., 1998). There may, therefore, be marked differences between species in the distribution of PAR₄, which will need to be taken into consideration when exploring the pharmacology of the PAR₄APs in different animals and generalizing findings obtained from one species to another. To date, the expression of PAR₄ in different tissues has not been compared with using an immunohistochemical approach. Thus, apart from its function in platelets, the diverse physiological role that PAR₄ may play represents a most interesting topic for further investigation.

The ability of thrombin to cleave PAR₃ with high efficiency and potency because of the putative interaction of the anion exosite binding domain of thrombin with the negatively charged postcleavage sequence in PAR₃ presents a puzzle, since on its own, murine PAR₃ appears not to generate an intracellular signal but rather acts as a cofactor for PAR₄ activation (Nakanishi-Matsui et al., 2000;Sambrano et al., 2001). It will be of interest to determine whether the lack of PAR₃ signaling can be attributed to special features of its intracellular domains (e.g., see Fig. 2). The wide tissue distribution (Table 3) of PAR₃ mRNA in humans, with large amounts in stomach, small intestine, and trachea, as well as in bone marrow, along with the more restricted distribution in murine tissues (splenic megakaryocytes) (Ishihara et al., 1997), presents a puzzle in terms of what the potential physiological role for PAR₃ may be.

B. Proteinase-Activated Receptor 2, a Trypsin Target

Like PAR₁, mRNA for PAR₂ can be detected in quite a number of tissues (Table 3), with strong signals observed in the gastrointestinal tract (stomach, small intestine, and colon) as well as in the kidney, with a comparable distribution in murine and human tissues (Nystedt et al., 1994; Böhm et al., 1996b). The availability of antisera that react with PAR₂ has confirmed the presence of the receptor in a large number of tissues, in parallel with the detection of receptor mRNA and, in addition, has served to localize the receptor on enteric nerves (D'Andrea et al., 1998; Corvera et al., 1999). In the absence of effective PAR₂ antagonists, it has been the use of receptor-selective PAR₂APs (e.g., SLIGRL-NH₂), along with experiments done with PAR₂ −/− mice, that has provided insight as to the potential physiological role the receptor may play. To date, although the PAR₂-deficient mouse does not exhibit a distinct phenotype, the actions of the PAR₂APs suggest roles in the cardiovascular, pulmonary, and gastrointestinal systems (summarized in reviews by Cocks and Moffatt, 2000; Macfarlane et al., 2001; Vergnolle et al., 2001b), with an added intriguing impact in the setting of inflammation and nociception that involves the activation of PAR₂on sensory nerves (Steinhoff et al., 2000; Vergnolle et al., 2001a). Evidence for a role for PAR₁ in triggering neurogenic inflammation has also been obtained (de Garavilla et al., 2001). If there is an overriding principle that can be put forward for the physiological function of PAR₁, PAR₂, and PAR₄, one can point to their potential role in the settings of tissue injury, repair, and remodeling, including processes that take place during embryo development. In such a context, locally produced tissue proteinases, including thrombin, other enzymes in the coagulation and complement cascades, trypsin(ogens), as well as many other proteinases will undoubtedly be found to exert a key impact on tissue signaling via the PARs.