Matthias Riewald

Mechanistic coupling of protease signaling and initiation of coagulation by tissue factor

The crucial role of cell signaling in hemostasis is clearly established by the action of the downstream coagulation protease thrombin that cleaves platelet-expressed G-protein-coupled protease activated receptors (PARs). Certain PARs are cleaved by the upstream coagulation proteases factor Xa (Xa) and the tissue factor (TF)–factor VIIa (VIIa) complex, but these enzymes are required at high nonphysiological concentrations and show limited recognition specificity for the scissile bond of target PARs. However, defining a physiological mechanism of PAR activation by upstream proteases is highly relevant because of the potent anti-inflammatory in vivo effects of inhibitors of the TF initiation complex. Activation of substrate factor X (X) by the TF–VIIa complex is here shown to produce enhanced cell signaling in comparison to the TF–VIIa complex alone, free Xa, or Xa that is generated in situ by the intrinsic activation complex. Macromolecular assembly of X into a ternary complex of TF–VIIa–X is required for proteolytic conversion to Xa, and product Xa remains transiently associated in a TF–VIIa–Xa complex. By trapping this complex with a unique inhibitor that preserves Xa activity, we directly show that Xa in this ternary complex efficiently activates PAR-1 and -2. These experiments support the concept that proinflammatory upstream coagulation protease signaling is mechanistically coupled and thus an integrated part of the TF–VIIa-initiated coagulation pathway, rather than a late event during excessive activation of coagulation and systemic generation of proteolytic activity.

Specificity of coagulation factor signaling

Summary.  Coagulation serine proteases signal through protease‐activated receptors (PARs). Thrombin‐dependent PAR signaling on platelets is essential for the hemostatic response and vascular thrombosis, but regulation of inflammation by PAR signaling is now recognized as an important aspect of the pro‐ and anti‐coagulant pathways. In tissue factor (TF)‐dependent initiation of coagulation, factor (F) Xa is the PAR‐1 or PAR‐2‐activating protease when associated with the transient TF–FVIIa–FXa complex. In the anticoagulant protein C (PC) pathway, the thrombin–thrombomodulin complex activates PC bound to the endothelial cell PC receptor (EPCR), which functions as a required coreceptor for activated PC‐mediated signaling through endothelial cell PAR‐1. Thus, the pro‐ and anti‐inflammatory receptor cascades are mechanistically coupled to immediate cell signaling, which precedes systemic coagulant or anticoagulant effects. In contrast to the substrate‐like recognition of PARs by thrombin, TF‐ or EPCR‐targeted activation of PARs generates cell‐type specificity, PAR selectivity and protease receptor cosignaling with the G‐protein‐coupled PAR response. Protease receptors are thus major determinants of the biological outcome of coagulation factor signaling on vascular cells.

Protective Signaling by Activated Protein C Is Mechanistically Linked to Protein C Activation on Endothelial Cells

Activated protein C (APC) has endothelial barrier protective effects that require binding to endothelial protein C receptor (EPCR) and cleavage of protease activated receptor-1 (PAR1) and that may play a role in the anti-inflammatory action of APC. In this study we investigated whether protein C (PC) activation by thrombin on the endothelial cell surface may be linked to efficient protective signaling. To minimize direct thrombin effects on endothelial permeability we used the anticoagulant double mutant thrombin W215A/E217A (WE). Activation of PC by WE on the endothelial cell surface generated APC with high barrier protective activity. Comparable barrier protective effects by exogenous APC required a 4-fold higher concentration of APC. To demonstrate conclusively that protective effects in the presence of WE are mediated by APC generation and not direct signaling by WE, we used a PC variant with a substitution of the active site serine with alanine (PC S360A). Barrier protective effects of a low concentration of exogenous APC were blocked by both wildtype PC and PC S360A, consistent with their expected role as competitive inhibitors for APC binding to EPCR. WE induced protective signaling only in the presence of wild type PC but not PC S360A and PAR1 cleavage was required for these protective effects. These data demonstrate that the endogenous PC activation pathway on the endothelial cell surface is mechanistically linked to PAR1-dependent autocrine barrier protective signaling by the generated APC. WE may have powerful protective effects in systemic inflammation through signaling by the endogenously generated APC.

Science review: Role of coagulation protease cascades in sepsis

Cellular signaling by proteases of the blood coagulation cascade through members of the protease-activated receptor (PAR) family can profoundly impact on the inflammatory balance in sepsis. The coagulation initiation reaction on tissue factor expressing cells signals through PAR1 and PAR2, leading to enhanced inflammation. The anticoagulant protein C pathway has potent anti-inflammatory effects, and activated protein C signals through PAR1 upon binding to the endothelial protein C receptor. Activation of the coagulation cascade and the downstream endothelial cell localized anticoagulant pathway thus have opposing effects on systemic inflammation. This dichotomy is of relevance for the interpretation of preclinical and clinical data that document nonuniform responses to anticoagulant strategies in sepsis therapy.

Tumor cell adhesion and migration supported by interaction of a receptor-protease complex with its inhibitor

Tissue factor (TF), the cell-surface receptor for coagulation factor VIIa, supports metastasis. Equally important for this process are (a) interactions of the TF cytoplasmic domain, which binds the mobility-enhancing actin-binding protein 280, and (b) the formation of a proteolytically active TF-VIIa complex on the tumor cell surface. In primary bladder carcinoma cells, we find that this complex localizes to the invasive edge, in proximity to tumor-infiltrating vessels that stain intensely for TF pathway inhibitor (TFPI-1), the major inhibitor of the protease activity of the complex. In culture, binding of VIIa to TF-expressing tumor cells is sufficient to allow cell adhesion, migration, and intracellular signaling on immobilized TFPI-1. Immobilized heparin, a mimic for extracellular matrix-associated proteoglycans, binds physiological concentrations of TFPI-1 in a conformation that supports TF-VIIa-dependent cell adhesion. Consistent with a functional role of TFPI-1 in complex extracellular matrices, we show that TF cooperates with integrin-mediated adhesion and migration on composite matrices that contain ligands for both integrins and the TF-VIIa complex. This study thus provides evidence for a novel mechanism of protease-supported migration that is independent of proteolytic matrix degradation but rather involves protease-dependent bridging of TFs extracellular domain to an ECM-associated inhibitor.

Orchestration of Coagulation Protease Signaling by Tissue Factor

Protease-activated receptors (PARs) are vascular sensors for signaling of the trypsinlike coagulation serine proteases that play key roles in cardiovascular medicine. In the initiation phase of coagulation, tissue factor (TF) orchestrates the assembly of VIIa with substrate X, forming a ternary complex in which product Xa is generated. The resulting TF-VIIa-Xa complex is an efficient activator of PAR1 and PAR2. TF initiation of the coagulation cascade is thus intimately linked to inflammatory cell signaling. Inflammation is an increasingly appreciated component of the vulnerable atherosclerotic plaque. Targeting inflammatory cell signaling events of the coagulation system may become an important aspect of efforts to improve antithrombotic therapy.

Activated protein C signals through the thrombin receptor PAR1 in endothelial cells

The anti-inflammatory effects of activated protein C (APC) have lead to its recent approval for the treatment of sepsis. Although the endothelial cell protein C receptor (EPCR) plays a crucial role in APCs protective roles in septicemia, the precise signaling mechanism of the protease APC remains unclear. In fibroblast overexpression systems, we find that APC activates protease activated receptors (PAR) 1 and 2 in an EPCR-dependent manner. Human endothelial cells (HUVECs) express PAR1, PAR2 and EPCR. Stimulation of HUVECs with either APC, or specific receptor activating peptides for PAR1 or PAR2, show that all three agonists induce a very similar set of early response genes as assessed by high density microarray analysis. Only the transcript for monocyte chemo-attractant protein-1 (MCP-1) was selectively induced by APC and the PAR1 agonist, but not by the PAR2 agonist. APC-mediated MAP kinase phosphorylation and gene induction were inhibited by cleavage blocking antibodies to PAR1, demonstrating that APC signals exclusively through PAR1 in endothelial cells. MCP-1 is protective in animal models of endotoxemia, suggesting that APC may prevent lethality in sepsis by inducing MCP-1 expression through EPCR-dependent activation of endothelial cell PAR1. These data demonstrate unexpected protective functions of the major thrombin receptor PAR1 in endothelial cells.

Protease-activated receptors-1 and -2 can mediate endothelial barrier protection: role in factor Xa signaling

Summary.  Coagulation and inflammation are intimately linked and cellular signaling by coagulation proteases through protease‐activated receptors (PARs) may affect pro‐ and anti‐inflammatory responses. Permeability of the endothelial cell barrier at the blood–tissue interface plays a key role in inflammatory disorders such as sepsis. We have recently shown that PAR1 signaling by activated protein C or low concentrations of thrombin can enhance endothelial barrier integrity. In the present study, we analyzed effects of coagulation factor Xa (FXa), which is known to activate both endothelial cell PAR1 and PAR2, on monolayer integrity using a transformed human umbilical vein endothelial cell (HUVEC) line in a dual‐chamber system. Preincubation with FXa potently reduced high‐dose thrombin‐mediated hyperpermeability and basal permeability. FXa was protective at concentrations of 5 nm or higher and proteolytic activity was required. Barrier protective FXa signaling was not affected by cleavage‐blocking anti‐PAR1 antibodies or by a PAR1 antagonist. Similarly, cleavage‐blocking anti‐PAR2 alone had no effect, but blocking both PAR1 and PAR2 inhibited barrier protection by FXa. Incubation of the cell layer with a PAR2‐specific agonist peptide reduced thrombin‐mediated hyperpermeability and basal permeability similar to FXa. In conclusion, not only PAR1, but also PAR2 can mediate barrier protection in endothelial cells and FXa can use either receptor to enhance barrier integrity. Although it is currently unknown whether PAR signaling by FXa has a physiological role, the results suggest a potential protective effect of FXa and other agonists of endothelial PAR2, which should be explored in models of local and systemic inflammation in vivo.

Hyperantithrombotic, noncytoprotective Glu149Ala-activated protein C mutant

Activated protein C (APC) reduces mortality in severe sepsis patients. APC exerts anticoagulant activities via inactivation of factors Va and VIIIa and cytoprotective activities via endothelial protein C receptor and protease-activated receptor-1. APC mutants with selectively altered and opposite activity profiles, that is, greatly reduced anticoagulant activity or greatly reduced cytoprotective activities, are compared here. Glu149Ala-APC exhibited enhanced in vitro anticoagulant and in vivo antithrombotic activity, but greatly diminished in vitro cytoprotective effects and in vivo reduction of endotoxin-induced murine mortality. Thus, residue Glu149 and the C-terminal region of APCs light chain are identified as functionally important for expression of multiple APC activities. In contrast to Glu149Ala-APC, 5A-APC (Lys191-193Ala + Arg229/230Ala) with protease domain mutations lacked in vivo antithrombotic activity, although it was potent in reducing endotoxin-induced mortality, as previously shown. These data imply that APC molecular species with potent antithrombotic activity, but without robust cytoprotective activity, are not sufficient to reduce mortality in endotoxemia, emphasizing the need for APCs cytoprotective actions, but not anticoagulant actions, to reduce endotoxin-induced mortality. Protein engineering can provide APC mutants that permit definitive mechanism of action studies for APCs multiple activities, and may also provide safer and more effective second-generation APC mutants with reduced bleeding risk.

Protection of vascular barrier integrity by activated protein C in murine models depends on protease-activated receptor-1

Protease activated receptor-1 (PAR1) mediates barrier protective signalling of activated protein C (APC) in human endothelial cells in vitro and may contribute to APCs beneficial effects in patients with severe sepsis. Mouse models are of key importance for translational research but species differences may limit conclusions for the human system. We analysed whether mouse APC can cleave, activate and induce signalling through murine PAR1 and tested in newly established mouse models if long-term infusion of APC prevents from vascular leakage. Cell surface immunoassays demonstrated efficient cleavage of endogenous murine endothelial PAR1 by either murine or human APC. Pharmacological concentrations of APC of either species had powerful barrier protective effects on cultured murine endothelial cells that required PAR1 cleavage. Vascular endothelial growth factor-mediated hyperpermeability in the skin was reduced by either endogenously generated as well as directly infused recombinant mouse APC in wild-type mice. However APC did not significantly alter the vascular barrier function in PAR1-deficient mice. In endotoxin-challenged mice, infused APC significantly prevented from pulmonary fluid accumulation in the wild-type mice but not in mice lacking PAR1. Our results directly show that murine APC cleaves and signals through PAR1 in mouse endothelial cells. APC reduces vascular permeability in mouse models and PAR1 plays a major role in mediating these effects. Our data in vitro and in vivo support the paradigm that PAR1 contributes to protective effects of APC on vascular barrier integrity in sepsis.