Thomas J. Girard

Tissue factor pathway inhibitor: structure-function.

TFPI is a multivalent, Kunitz-type proteinase inhibitor, which, due to alternative mRNA splicing, is transcribed in three isoforms: TFPIalpha, TFPIdelta, and glycosyl phosphatidyl inositol (GPI)-anchored TFPIbeta. The microvascular endothelium is thought to be the principal source of TFPI and TFPIalpha is the predominant isoform expressed in humans. TFPIalpha, apparently attached to the surface of the endothelium in an indirect GPI-anchor-dependent fashion, represents the greatest in vivo reservoir of TFPI. The Kunitz-2 domain of TFPI is responsible for factor Xa inhibition and the Kunitz-1 domain is responsible for factor Xa-dependent inhibition of the factor VIIa/tissue factor catalytic complex. The anticoagulant activity of TFPI in one-stage coagulation assays is due mainly to its inhibition of factor Xa through a process that is enhanced by protein S and dependent upon the Kunitz-3 and carboxyterminal domains of full-length TFPIalpha. Carboxyterminal truncated forms of TFPI as well as TFPIalpha in plasma, however, inhibit factor VIIa/tissue factor in two-stage assay systems. Studies in gene-disrupted mice demonstrate the physiological importance of TFPI.

Tissue factor pathway inhibitor

Publisher Summary This chapter describes several assays useful for studying the various facets of tissue factor pathway inhibitor (TFPI) function, discusses procedures for the purification of TFPI from mammalian cell culture, and summarizes the properties of the TFPI molecule. A unique feature of TFPI is its factor Xa-dependent inhibition of factor VIIa-tissue factor activity, and the most reliable assays for identifying TFPI are assays that measure this inhibition. The generation of polyclonal and monoclonal antibodies to TFPI has allowed for the identification of TFPI using immunoassays and Western blot analysis. TFPI functions as a multivalent protease inhibitor; it inhibits activated factor X (Xa) directly and inhibits factor VIIa-tissue factor activity in a factor Xa-dependent fashion by forming an inhibitory complex consisting of factor Xa, TFPI, factor VIIa, and tissue factor. These activities suggest that TFPI serves a regulatory role in hemostasis. The chapter also describes the purification and characterization of the tissue factor pathway inhibitor.

Piperazinyl Glutamate Pyridines as Potent Orally Bioavailable P2Y12 Antagonists for Inhibition of Platelet Aggregation

Polymer-assisted solution-phase (PASP) parallel library synthesis was used to discover a piperazinyl glutamate pyridine as a P2Y(12) antagonist. Exploitation of this lead provided compounds with excellent inhibition of platelet aggregation as measured in a human platelet rich plasma (PRP) assay. Pharmacokinetic and physiochemical properties were optimized through modifications at the 4-position of the pyridine ring and the terminal nitrogen of the piperazine ring, leading to compound (4S)-4-[({4-[4-(methoxymethyl)piperidin-1-yl]-6-phenylpyridin-2-yl}carbonyl)amino]-5-oxo-5-{4-[(pentyloxy)carbonyl]piperazin-1-yl}pentanoic acid 47s with good human PRP potency, selectivity, in vivo efficacy, and oral bioavailability. Compound 47s was selected for further preclinical evaluations.

TFPIβ is the GPI-anchored TFPI isoform on human endothelial cells and placental microsomes

Tissue factor pathway inhibitor (TFPI) produces factor Xa-dependent feedback inhibition of factor VIIa/tissue factor-induced coagulation. Messages for 2 isoforms of TFPI have been identified. TFPIα mRNA encodes a protein with an acidic N-terminus, 3 Kunitz-type protease inhibitor domains and a basic C-terminus that has been purified from plasma and culture media. TFPIβ mRNA encodes a form in which the Kunitz-3 and C-terminal domains of TFPIα are replaced with an alternative C-terminus that directs the attachment of a glycosylphosphatidylinositol (GPI) anchor, but whether TFPIβ protein is actually expressed is not clear. Moreover, previous studies have suggested that the predominant form of TFPI released from cells by phosphatidylinositol-specific phospholipase C (PIPLC) treatment is TFPIα, implying it is bound at cell surfaces to a separate GPI-anchored coreceptor. Our studies show that the form of TFPI released by PIPLC treatment of cultured endothelial cells and placental microsomes is actually TFPIβ based on (1) migration on SDS-PAGE before and after deglycosylation, (2) the lack of a Kunitz-3 domain, and (3) it contains a GPI anchor. Immunoassays demonstrate that, although endothelial cells secrete TFPIα, greater than 95% of the TFPI released by PIPLC treatment from the surface of endothelial cells and from placental microsomes is TFPIβ.

Structure-based drug design of pyrazinone antithrombotics as selective inhibitors of the tissue factor VIIa complex

Structure-based drug design coupled with polymer-assisted solution-phase library synthesis was utilized to develop a series of pyrazinone inhibitors of the tissue factor/Factor VIIa complex. The crystal structure of a tri-peptide ketothiazole complexed with TF/VIIa was utilized in a docking experiment that identified a benzyl-substituted pyrazinone as a P(2) surrogate for the tri-peptide. A 5-step PASP library synthesis of these aryl-substituted pyrazinones was developed. The sequence allows for attachment of a variety of P(1) and P(3) moieties, which led to synthesis pyrazinone 23. Compound 23 exhibited 16 nM IC(50) against TF/VIIa with >6250x selectivity versus Factor Xa and thrombin. This potent and highly selective inhibitor of TF/VIIa was chosen for pre-clinical intravenous proof-of-concept studies to demonstrate the separation between antithrombotic efficacy and bleeding side effects in a primate model of thrombosis.

The role of tissue factor/factor VIIa in the pathophysiology of acute thrombotic formation.

Tissue factor (TF) is the essential cofactor for the coagulation protease factor VIIa (FVIIa), initiating the coagulation cascade. The role of TF in thrombotic diseases is becoming increasingly evident. Recent findings suggest that inhibition of TF/FVIIa activity could be important in the prevention of clinical sequelae associated with plaque rupture or vessel damage that exposes TF to blood. Furthermore, selective inhibitors of TF/FVIIa may be associated with less bleeding risk than other antithrombotic agents. Several TF/FVIIa inhibitors are in development, including the protein-based inhibitors (such as NAPc2, Corsevin M, FFR-FVIIa, and Tifacogin). Research into the development of small molecule inhibitors is on-going, but is at a less advanced stage.

Pharmacological intervention at disparate sites in the coagulation cascade: Comparison of anti-thrombotic efficacy vs. bleeding propensity in a rat model of acute arterial thrombosis

The Tissue Factor/Factor VIIa (TF/FVIIa) complex is an attractive target for pharmacological interruption of thrombin generation and hence blood coagulation, as this complex is the initiation point of the extrinsic pathway of coagulation. TF is a cell membrane-associated protein that interacts with soluble FVIIa to activate factors IX and X resulting in a cascade of events that leads to thrombin generation and eventual fibrin deposition. The goal of this non-randomized study was to evaluate XK1, a specific protein inhibitor of TF/FVIIa, and compare antithrombotic efficacy and bleeding propensity to a previously described Factor Xa (FXa) inhibitor (SC-83157/SN429) and a direct-acting thrombin inhibitor (SC-79407/L-374087) in an acute rat model of arterial thrombosis. All saline-treated animals experienced occlusion of the carotid artery due to acute thrombus formation within 20 minutes. Rats treated with XK1 exhibited a dose-dependent inhibition of thrombus formation with full antithrombotic efficacy and no change in bleeding time or total blood loss at a dose of 4.5 mg/kg, i.v. administered over a 60 minute period. FXa inhibition with SC-83157 resulted in complete inhibition of thrombus formation at a dose of 1.2 mg/kg, i.v.; however, this effect was associated with substantial blood loss. Thrombin inhibition with SC-79407 also afforded complete protection from thrombus formation and occlusion at a dose of 2.58 mg/kg, i.v., and like SC-83157, was associated with substantial blood loss. These data imply that TF/FVIIa inhibition confers protection from acute thrombosis without concomitant changes in bleeding, indicating that this target (TF/FVIIa) may provide improved separation of efficacy vs. bleeding side-effects than interruption of coagulation by directly inhibiting either FXa or thrombin.

Structural Requirements for TFPI-Mediated Inhibition of Neointimal Thickening After Balloon Injury in the Rat

The intimal thickening that follows vascular injury is inhibited by periprocedural tissue factor pathway inhibitor (TFPI) treatment in animal models. TFPI is a multivalent Kunitz-type protease inhibitor that inhibits factor Xa via its second Kunitz domain and the factor VIIa/tissue factor (TF) complex via its first Kunitz domain. The basic C-terminus of TFPI is required for the binding of TFPI to cell surfaces and cell-bound TFPI mediates the internalization and degradation of factor X and the down regulation of surface factor VIIa/TF activity. The C-terminus of TFPI is also required for its reported direct inhibition of smooth muscle cell proliferation in vitro. To examine the structural requirements for the inhibition of neointimal formation by TFPI, several TFPI-related proteins were tested in the rat carotid angioplasty model: 1) XK(1), a hybrid protein containing the N-terminal portion of factor X and the first Kunitz domain of TFPI that directly inhibits factor VIIa/TF; 2) TFPI(WT), the full-length TFPI molecule that inhibits factor Xa and factor VIIa/TF and binds cell surfaces; 3) TFPI(K36I), an altered form of TFPI that inhibits factor Xa, but not factor VIIa/TF, and binds cell surfaces; 4) TFPI(13-161), a truncated form of TFPI that inhibits factor VIIa/TF but interacts with factor Xa poorly and does not bind to cell surfaces. Seven day infusions of XK(1), TFPI(WT), and high levels of TFPI(K36I) begun the day before balloon-induced vascular injury produced a significant reduction in the intimal hyperplasia measured 28 days after angioplasty. The infusion of high concentrations of TFPI(13-161) was ineffective in this model. These in vivo results directly mirror the ability of each TFPI-related protein to inhibit tissue thromboplastin-induced coagulation in rat plasma: XK(1) approximately TFPI(WT)>TFPI(K36I)>>TFPI(13-161). The studies confirm the important role of TF-mediated coagulation in the smooth muscle proliferation and neointimal thickening that follows vascular injury and suggest that the anticoagulant effect alone of TFPI and TFPI-related proteins is sufficient to explain their therapeutic action.

Piperazinyl-glutamate-pyridines as potent orally bioavailable P2Y12 antagonists for inhibition of platelet aggregation.

Polymer-assisted solution-phase (PASP) parallel library synthesis was used to discover a piperazinyl-glutamate-pyridine as a P2Y(12) antagonist. Exploitation of this lead provided compounds with excellent inhibition of platelet aggregation as measured in a human platelet rich plasma (PRP) assay. Pharmacokinetic and physiochemical properties were optimized leading to compound (4S)-4-[({4-[4-(methoxymethyl)piperidin-1-yl]-6-phenylpyridin-2-yl}carbonyl)amino]-5-oxo-5-{4-[(pentyloxy)carbonyl]piperazin-1-yl}pentanoic acid 22J with good human PRP potency, selectivity, in vivo efficacy and oral bioavailability.

Piperazinyl-glutamate-pyrimidines as potent P2Y12 antagonists for inhibition of platelet aggregation.

Piperazinyl-glutamate-pyrimidines were prepared with oxygen, nitrogen, and sulfur substitution at the 4-position of the pyrimidine leading to highly potent P2Y12 antagonists. In particular, 4-substituted piperidine-4-pyrimidines provided compounds with exceptional potency. Pharmacokinetic and physicochemical properties were fine-tuned through modifications at the 4-position of the piperidine ring leading to compounds with good human PRP potency, selectivity, clearance and oral bioavailability.