Physiological responses to protein aggregates: fibrinolysis, coagulation and inflammation (new roles for old factors).

Misfolding is an inherent and potentially problematic propensity of proteins. Misfolded proteins tend to aggregate and the deposition of aggregated proteins is associated with a variety of highly debilitating diseases known as amyloidoses. Protein misfolding and aggregation is also increasingly recognized as the underlying cause of other health problems, including atherosclerosis and immunogenicity of biopharmaceuticals. This raises the question how nature deals with the removal of obsolete proteins in order to avoid their accumulation and disease. In recent years two proteases, tPA and factor XII, have been identified that specifically recognize aggregates of misfolded proteins. We here review these discoveries that have uncovered new roles for the fibrinolytic system and the contact activation system beyond haemostasis.

Plasma protein S contains zinc essential for efficient activated protein C-independent anticoagulant activity and binding to factor Xa, but not for efficient binding to tissue factor pathway inhibitor.

Protein S (PS) is a cofactor for activated protein C (APC), which inactivates coagulation factors (F) Va and VIIIa. Deficiency of protein C or PS is associated with risk of thrombosis. We found that PS also has APC-independent anticoagulant activity (PS-direct) and directly inhibits thrombin generated by FXa/FVa (prothrombinase complex). Here we report that PS contains Zn(2+) that is required for PS-direct and that is lost during certain purification procedures. Immunoaffinity-purified PS contained 1.4 +/- 0.6 Zn(2+)/mol, whereas MonoQ-purified and commercial PS contained 0.15 +/- 0.15 Zn(2+)/mol. This may explain the controversy regarding the validity of PS-direct. Zn(2+) content correlated positively with PS-direct in prothrombinase assays and clotting assays, but APC-cofactor activity of PS was independent of Zn(2+) content. PS-direct and Zn(2+) were restored to inactive PS under mildly denaturing conditions. Conversely, o-phenanthroline reversibly impaired the PS-direct of active PS. Zn(2+)-containing PS bound FXa more efficiently (K(d)(app)=9.3 nM) than Zn(2+)-deficient PS (K(d)(app)=110 nM). PS bound TFPI efficiently, independently of Zn(2+) content (K(d)(app)=21 nM). Antibodies that block PS-direct preferentially recognized Zn(2+)-containing PS, suggesting conformation differences at or near the interface of 2 laminin G-like domains near the PS C terminus. Thus, Zn(2+) is required for PS-direct and efficient FXa binding and may play a role in stabilizing PS conformation.

Identification of fibronectin type I domains as amyloid-binding modules on tissue-type plasminogen activator and three homologs.

The serine protease tissue-type plasminogen activator (tPA), a key enzyme in hemostasis, is activated by protein aggregates with amyloid-like properties. tPA is implicated in various pathologies, including amyloidoses. A major task is to further elucidate the mechanisms of amyloid pathology. We here show that the fibronectin type I domain of tPA mediates the interaction with amyloid protein aggregates. We found that in contrast to full-length tPA, a deletion-mutant of tPA, lacking the first three N-terminal domains (including the fibronectin type I domain), fails to activate in response to amyloid protein aggregates. Using recombinantly produced domains of tPA in direct binding assays, we subsequently mapped the amyloid-binding region to the fibronectin type I domain. This domain co-localized with congophilic plaques in brain sections from patients with Alzheimer's disease. Fibronectin type I domains from homologous proteases factor XII, hepatocyte growth factor activator and from the extracellular matrix protein fibronectin also bound to aggregated amyloidogenic peptides. Finally, we demonstrated that the isolated fibronectin type I domain inhibits amyloid-induced aggregation of blood platelets. The identification of the fibronectin type I domain as an amyloid-binding module provides new insights into the (patho-) physiological role of tPA and the homologous proteins which may offer new targets for intervention in amyloid pathology.

Misfolded proteins activate factor XII in humans, leading to kallikrein formation without initiating coagulation.

When blood is exposed to negatively charged surface materials such as glass, an enzymatic cascade known as the contact system becomes activated. This cascade is initiated by autoactivation of Factor XII and leads to both coagulation (via Factor XI) and an inflammatory response (via the kallikrein-kinin system). However, while Factor XII is important for coagulation in vitro, it is not important for physiological hemostasis, so the physiological role of the contact system remains elusive. Using patient blood samples and isolated proteins, we identified a novel class of Factor XII activators. Factor XII was activated by misfolded protein aggregates that formed by denaturation or by surface adsorption, which specifically led to the activation of the kallikrein-kinin system without inducing coagulation. Consistent with this, we found that Factor XII, but not Factor XI, was activated and kallikrein was formed in blood from patients with systemic amyloidosis, a disease marked by the accumulation and deposition of misfolded plasma proteins. These results show that the kallikrein-kinin system can be activated by Factor XII, in a process separate from the coagulation cascade, and point to a protective role for Factor XII following activation by misfolded protein aggregates.

Regulation of fibrinolysis by thrombin activatable fibrinolysis inhibitor, an unstable carboxypeptidase B that unites the pathways of coagulation and fibrinolysis.

The coagulation and fibrinolytic systems safeguard the patency of the vasculature and surrounding tissue. Cross regulation of coagulation and fibrinolysis plays an important role in preserving a balanced hemostatic process. Identification of Thrombin Activatable Fibrinolysis Inhibitor (TAFI) as an inhibitor of fibrinolysis and one of the main intermediates between coagulation and fibrinolysis, greatly improved our understanding of cross regulation of coagulation and fibrinolysis. As TAFI is an enzyme that is activated by thrombin generated by the coagulation system, its activation is sensitive to the dynamics of the coagulation system. Defects in coagulation, such as in thrombosis or hemophilia, resonate in TAFI-mediated regulation of fibrinolysis and imply that clinical symptoms of coagulation defects are amplified by unbalanced fibrinolysis. Thrombomodulin promotes the generation of both antithrombotic activated protein C (APC) and prothrombotic (antifibrinolytic) activated TAFI, illustrating the paradoxical effects of thrombomodulin on the regulation of coagulation and fibrinolysis. This review will discuss the role of TAFI in the regulation of fibrinolysis and detail its regulation of activation and its potential therapeutic applications in thrombotic disease and bleeding disorders.

Thrombin activatable fibrinolysis inhibitor (TAFI)--how does thrombin regulate fibrinolysis?

The thrombin-catalysed conversion of plasma fibrinogen into fibrin and the development of an insoluble fibrin clot are the final steps of the coagulation cascade during haemostasis. A delicate balance between coagulation and fibrinolysis determines the stability of the fibrin clot. Thrombin plays a central role in this process, it not only forms the clot but it is also involved in stabilizing the clot by activating thrombin activatable fibrinolysis inhibitor (TAFI). Activated TAFI protects the fibrin clot against lysis. Here we will discuss the mechanisms for regulation of fibrinolysis by thrombin. The role of the coagulation system for the generation of thrombin and for the activation of TAFI implies that defects in thrombin generation will directly affect the protection of clots against lysis. Thus, defects in activation of TAFI might contribute to the severity of bleeding disorders. Vice versa an increased activation of TAFI due to an increased rate of thrombin generation might lead to thrombotic disorders. Specific inhibitors of activated TAFI or inhibitors that interfere with the generation of thrombin might provide novel therapeutic strategies for thrombolytic therapy. Besides having a role in the regulation of fibrinolysis, TAFI may also have an important function in the regulation of inflammation, wound healing and blood pressure.

Factor XI enhances fibrin generation and inhibits fibrinolysis in a coagulation model initiated by surface-coated tissue factor.

In-vitro studies have shown that thrombin-mediated factor XI activation enhances thrombin and fibrin formation, rendering the clot more thrombogenic and protecting it from lysis by activation of thrombin activatable fibrinolysis inhibitor. These effects of factor XI are only observed when coagulation is initiated by a low concentration of soluble tissue factor. At high concentrations of soluble tissue factor no effects of factor XI are seen on coagulation and fibrinolysis. In vivo, tissue factor is present in large amounts in the vascular wall. This makes it difficult to extrapolate these in-vitro findings on factor XI to the in-vivo situation. To address the question of whether factor XI could play a role in coagulation initiated on a tissue factor-containing surface we devised a static in-vitro coagulation model in which clotting is initiated in recalcified citrated plasma by tissue factor coated on the bottom of microtiter plates. The effect of factor XI was studied with an antibody that blocked the activation of factor IX by activated factor XI. The tissue factor coating strategy produced clotting times similar to those obtained with cultured tissue factor-expressing vessel wall cells (smooth muscle cells, fibroblasts and activated endothelial cells) grown to confluence in the same wells. A factor XI-dependent effect on clot formation and clot lysis was observed depending on the plasma volume used. In clots formed from small amounts of plasma (100 microl) no effect of factor XI was detected. In larger clots (200-300 microl) factor XI not only increased prothrombin activation and the fibrin formation rate but also inhibited fibrinolysis. Effects of factor XI were observed at short clotting times (3-4 min) similar to the clotting times found on cultured tissue factor-expressing vessel wall cells. This is in contrast with earlier studies using soluble tissue factor, in which effects of factor XI were only observed at much longer clotting times using low soluble tissue factor concentrations. We conclude that factor XI not only enhances coagulation initiated by surface bound tissue factor but also protects the clot against lysis once it is formed. On the basis of these results, we propose a coagulation model in which initial clot formation in the proximity of the tissue factor surface is not factor XI dependent. Clot formation becomes dependent on factor XI in the propagation phase when the clot is increasing in size. These findings support a role for factor XI in the propagation of clot growth after tissue factor-dependent initiation.

New insights into factors affecting clot stability: A role for thrombin activatable fibrinolysis inhibitor (TAFI; plasma procarboxypeptidase B, plasma procarboxypeptidase U, procarboxypeptidase R).

The thrombin-catalyzed conversion of plasma fibrinogen into fibrin and the development of an insoluble fibrin clot are the final steps in the coagulation cascade during hemostasis. The delicate balance between clot formation and fibrinolysis, which determines clot stability, is controlled by a complex interplay between fibrin and other molecular and cellular components of the hemostatic system, including thrombin activatable fibrinolysis inhibitor (TAFI). TAFI is activated by thrombin and has an important role in the stability of the fibrin clot, which is reviewed here. In particular, the role of TAFI in fibrinolysis and those characteristics of the protein that affect clot stability are described. In addition, the importance of TAFI in the coagulation process and how changes in its availability may contribute to bleeding or thrombotic disorders are discussed.

Effect of second- and third-generation oral contraceptives on the protein C system in the absence or presence of the factor VLeiden mutation: a randomized trial.

A plausible mechanism to explain thrombotic risk differences associated with the use of second- and third-generation oral contraceptives (OCs), particularly in carriers of factor V(Leiden), is still lacking. In a double-blind trial, 51 women without and 35 women with factor V(Leiden) were randomized to either a second- (30 microg ethinylestradiol/150 microg levonorgestrel) or third- (30 microg ethinylestradiol/150 microg desogestrel) generation OC. After 2 cycles of use and a wash-out of 2 cycles, the participants continued with the corresponding progestagen-only preparation. Hemostatic variables that probe the activity of the anticoagulant protein C system were determined. Compared with levonorgestrel, desogestrel-containing OCs significantly decreased protein S and increased activated protein C (APC) resistance in both groups. OCs with desogestrel had the most pronounced effects in carriers of factor V(Leiden). Progestagen-only preparations caused changes of anticoagulant parameters opposite to those of combined OCs, which in a number of cases were more pronounced with levonorgestrel. Our data show that progestagens in combined OCs counteract the thrombotic effect of the estrogen component. The higher thrombotic risk associated with third-generation OCs compared with second-generation OCs may be explained by the fact that desogestrel appeared less antithrombotic than levonorgestrel, especially in women with factor V(Leiden).

Characteristics of piraltin, a polyphenol concentrate, produced by freeze-drying of red wine.

Moderate consumption of red wine is associated with a decreased risk for coronary heart disease. Apart from alcohol, an additive role for wine polyphenols has been suggested. However, the real contribution of these compounds can only be studied when available without the alcohol component. The objective of the study was to prepare a wine polyphenol concentrate not containing alcohol and to compare the quantitative and qualitative properties of this concentrate with those of the original wine from which the concentrate is made. This polyphenol concentrate, called piraltin, was made out of red wine by a freeze-drying technique. Both piraltin and the original red wine were analyzed quantitatively for the main polyphenols present: gallic acid, catechin, epicatechin and quercetin. The qualitative comparison comprised the inhibitory effect of the two products on LDL oxidation in vitro. In the process of freeze-drying recovery of the four determined flavonoids of red wine is fairly constant (average 68 +/- 7%). In a copper induced LDL oxidation assay both red wine and piraltin prolonged lag-times over 300% compared to controls without a significant difference between the two products. The freeze-dried polyphenol concentrate piraltin contains about 70% of the total polyphenol content of the original wine. This preparation technique does not cause a loss of antioxidative properties of the phenols. Piraltin creates the possibility to study the effects of wine polyphenols separately without the influence of alcohol both in vitro and in vivo.

Generation and characterization of a highly stable form of activated thrombin-activable fibrinolysis inhibitor.

Activated thrombin-activable fibrinolysis inhibitor (TAFIa) is a carboxypeptidase B that can down-regulate fibrinolysis. TAFIa is a labile enzyme that can be inactivated by conformational instability or proteolysis. TAFI is approximately 40% identical to pancreatic carboxypeptidase B (CPB). In contrast to TAFIa, pancreatic CPB is a stable protease. We hypothesized that regions or residues that are not conserved in TAFIa compared with pancreatic CPB play a role in the conformational instability of TAFIa and that replacement of these non-conserved residues with residues of pancreatic CPB would lead to a TAFIa molecule with an increased stability. Therefore, we have expressed, purified, and characterized two TAFI-CPB chimeras: TAFI-CPB-(293-333) and TAFI-CPB-(293-401). TAFI-CPB-(293-333) could be activated by thrombin-thrombomodulin, but not as efficiently as wild-type TAFI. After activation, this mutant was unstable and was hardly able to prolong clot lysis of TAFI-deficient plasma. Binding of TAFI-CPB-(293-333) to both plasminogen and fibrinogen was normal compared with wild-type TAFI. TAFI-CPB-(293-401) could be activated by thrombin-thrombomodulin, although at a lower rate compared with wild-type TAFI. The activated mutant displayed a markedly prolonged half-life of 1.5 h. Plasmin could both activate and inactivate this chimera. Interestingly, this chimera did not bind to plasminogen or fibrinogen. TAFI-CPB-(293-401) could prolong the clot lysis time in TAFI-deficient plasma, although not as efficiently as wild-type TAFI. In conclusion, by replacing a region in TAFI with the corresponding region in pancreatic CPB, we were able to generate a TAFIa form with a highly stable activity.

Amyloid endostatin induces endothelial cell detachment by stimulation of the plasminogen activation system.

Endostatin is a fragment of collagen XVIII that acts as an inhibitor of tumor angiogenesis and tumor growth. Anti-tumor effects have been described using both soluble and insoluble recombinant endostatin. However, differences in endostatin structure are likely to cause differences in bioactivity. In the present study, we have investigated the cellular effects of insoluble endostatin. We previously found that insoluble endostatin shows all the hallmarks of amyloid aggregates and potently stimulates tissue plasminogen activator-mediated formation of the serine protease plasmin. We here show that amyloid endostatin induces plasminogen activation by endothelial cells, resulting in vitronectin degradation and plasmin-dependent endothelial cell detachment. Endostatin-mediated stimulation of plasminogen activation, vitronectin degradation, and endothelial cell detachment is inhibited by carboxypeptidase B, indicating an essential role for carboxyl-terminal lysines. Our results suggest that amyloid endostatin may inhibit angiogenesis and tumor growth by stimulating the fibrinolytic system.

No acute effect of red wine on the coagulation pathway in healthy men.

Binge drinking is associated with an increased risk of cardiovascular events. Those events often happen within hours after alcohol is consumed. Apart from arrhythmias and changes in blood pressure, these events may be caused by an acute (i.e., occurring within a 24-h period) shift of the hemostatic balance in a thrombogenic direction. Alcohol can influence platelet aggregation and inhibit fibrinolysis, but little is known about its direct effect on coagulation. In the current study, parameters of coagulation, reflecting either stimulation or inhibition, were measured 5 and 15 h after the consumption of four (62.5 g of alcohol) and eight (125 g of alcohol) glasses of red wine. Both doses had no direct effect on activated cephalin time, thrombin-antithrombin complexes, factors VII and VIII, and von Willebrand factor. In contrast with the observed effects on thrombocytes and fibrinolysis, the consumption of large amounts of wine does not influence the coagulation pathway.

Identification of thrombin activatable fibrinolysis inhibitor (TAFI) in human platelets.

Thrombin activatable fibrinolysis inhibitor (TAFI) is a carboxypeptidase B-like proenzyme that after activation down-regulates fibrinolysis. Platelets are known to contain antifibrinolytic factors that are secreted during platelet activation. Therefore, the presence of TAFI in platelets was analyzed. TAFI was identified in platelets in a concentration of about 50 ng/1 x 109 platelets and was secreted on platelet activation. Thrombin-mediated activation of platelet-derived TAFI resembled that of plasma-derived TAFI with respect to stimulation by thrombomodulin and spontaneous loss of activity at 37 degrees C. The different glycosylation of platelet-derived TAFI compared with plasma-derived TAFI suggests that platelet-derived TAFI is synthesized in the megakaryocyte. This suggestion was substantiated by the detection of mRNA in the megakaryocytic cell lines DAMI and CHRF, representing the intermediate and late stages of megakaryocyte development. These results establish the presence of TAFI in platelets and suggest a role for platelet-derived TAFI in the protection of the clot against fibrinolysis.

Changes of hemostatic variables during oral contraceptive use.

The use of oral contraceptives (OCs) has been known for many years to affect significantly almost all hemostatic parameters, but the challenge to relate these changes in a meaningful way to OC-induced increased venous thrombotic risk has not been met. New insights indicate that at least part of the answer can be found in the net effect of OC use on the efficacy with which the protein C pathway down-regulates thrombin formation. During OC use the (blood) plasma of a woman becomes resistant to the anticoagulant action of activated protein C (APC). The extent of this so-called acquired APC resistance as determined in a thrombin generation-based assay correlates remarkably well with the risk increases observed in clinical studies. Recent evidence indicates that the prothrombotic effect of the estrogen component ethinylestradiol in combined OC is counteracted by the progestagen component present in these preparations and that third-generation progestagens such as desogestrel or gestodene are less efficient with respect to this than the second-generation progestagen levonorgestrel.

Thrombin activatable fibrinolysis inhibitor (TAFI) at the interface between coagulation and fibrinolysis.

The thrombin-catalysed conversion of plasma fibrinogen into fibrin and the development of an insoluble fibrin clot are the final steps of the coagulation cascade during haemostasis. A delicate balance between coagulation and fibrinolysis determines the stability of the fibrin clot. Thrombin Activatable Fibrinolysis Inhibitor (TAFI) plays an important role in this process. TAFI is activated by thrombin and protects the fibrin clot against lysis. The role of TAFI in bleeding and thrombotic disorders is discussed as well as its novel emerging role in wound healing and inflammation.

Protein C inhibitor (plasminogen activator inhibitor-3) and the risk of venous thrombosis.

Protein C inhibitor (PCI), also known as plasminogen activator inhibitor-3, is a serine proteinase inhibitor that can inhibit enzymes in blood coagulation, fibrinolysis and fertility. The role of PCI in regulating the blood coagulation mechanism is not known, as it can inhibit both procoagulant (thrombin, factor Xa, factor XIa) and anticoagulant (activated protein C, thrombin-thrombomodulin, urokinase) enzymes. To determine the relevance of this inhibitor in thrombosis, PCI levels were assessed in the Leiden Thrombophilia Study, a case-control study of venous thrombosis in 473 patients with a first deep-vein thrombosis and 474 age- and sex-matched control subjects. PCI levels above the 95th percentile of the controls (136.1%) increased the risk 1.6-fold compared with PCI levels below the 95th percentile (95% confidence interval 0.9-2.8). There was a gradual increase in risk of thrombosis with further increasing levels of PCI. Adjustment for a number of possible confounders led to a reduction of the risk estimates associated with PCI. However, it is unclear whether adjustment for such factors in the risk models is justified. These results indicate that high levels of PCI may constitute a mild risk factor for venous thrombosis.

Plasmin-mediated activation and inactivation of thrombin-activatable fibrinolysis inhibitor.

Activated thrombin-activatable fibrinolysis inhibitor (TAFIa) attenuates the fibrin cofactor function of tissue-type plasminogen activator-mediated plasmin formation and subsequently fibrin degradation. In the present study, we focused on the role of plasmin in the regulation of TAFIa activity. Upon incubation with plasmin, TAFIa activity was generated, which was unstable at 37 degrees C. Analysis of the cleavage pattern showed that TAFI was cleaved at Arg(92), releasing the activation peptide from the 35.8-kDa catalytic domain. The presence of the 35.8-kDa fragment paralleled the time course of generation and loss of TAFIa activity. This suggested that, in the presence of plasmin, TAFIa is probably inactivated by proteolysis rather than by conformational instability. TAFI was also cleaved at Arg(302), Lys(327), and Arg(330), resulting in a approximately 44.3-kDa fragment and several smaller fragments. The 44.3-kDa fragment is no longer activatable since it lacks part of the catalytic center. We concluded that plasmin can cleave at several sites in TAFI and that this contributes to the regulation of TAFI and TAFIa.

Role of zinc ions in activation and inactivation of thrombin-activatable fibrinolysis inhibitor.

Thrombin-activatable fibrinolysis inhibitor (TAFI) circulates as an inactive proenzyme of a carboxypeptidase B-like enzyme (TAFIa). It functions by removing C-terminal lysine residues from partially degraded fibrin that are important in tissue-type plasminogen activator mediated plasmin formation. TAFI was classified as a metallocarboxypeptidase, which contains a Zn(2+), since its amino acid sequence shows approximately 40% identity with pancreatic carboxypeptidases, the Zn(2+) pocket is conserved, and the Zn(2+) chelator o-phenanthroline inhibited TAFIa activity. In this study we showed that TAFI contained Zn(2+) in a 1:1 molar ratio. o-Phenanthroline inhibited TAFIa activity and increased the susceptibility of TAFI to trypsin digestion. TAFIa is spontaneously inactivated (TAFIai) by a temperature-dependent intrinsic mechanism. The lysine analogue epsilon-ACA, which stabilizes TAFIa, delayed the o-phenanthroline mediated inhibition of TAFIa. We investigated if inactivation of TAFIa involves the release of Zn(2+). However, the zinc ion was still incorporated in TAFIai, indicating that inactivation is not caused by Zn(2+) release. After TAFIa was converted to TAFIai, it was more susceptible to proteolytic degradation by thrombin, which cleaved TAFIai at Arg(302). Proteolysis may make the process of inactivation by a conformational change irreversible. Although epsilon-ACA stabilizes TAFIa, it was unable to reverse inactivation of TAFIa or R302Q-rTAFIa, in which Arg(302) was changed into a glutamine residue and could therefore not be inactivated by proteolysis, suggesting that conversion to TAFIai is irreversible.

The alpha -chains of C4b-binding protein mediate complex formation with low density lipoprotein receptor-related protein.

C4b-binding protein (C4BP) is a heparin-binding protein that participates in both the complement and hemostatic system. We investigated the interaction between C4BP and low density lipoprotein receptor-related protein (LRP), an endocytic receptor involved in the catabolism of various heparin-binding proteins. Both plasma-derived C4BP and recombinant C4BP consisting of only its alpha-chains (rC4BPalpha) bound efficiently to immobilized LRP, as determined by surface plasmon resonance analysis. Complementary, two distinct fragments of LRP, i.e. clusters II and IV, both associated to immobilized rC4BPalpha, and binding could be inhibited by the LRP antagonist receptor-associated protein. Further analysis showed that association of rC4BPalpha to LRP was inhibited by heparin or by anti-C4BP antibody RU-3B9, which recognizes the heparin-binding region of the C4BP alpha-chains. In cellular degradation experiments, LRP-expressing fibroblasts effectively degraded (125)I-labeled rC4BPalpha, whereas their LRP-deficient counterparts displayed a 4-fold diminished capacity of degrading (125)I-rC4BPalpha. Finally, initial clearance of C4BP in mice was significantly delayed upon co-injection with receptor-associated protein. In conclusion, our data demonstrate that the alpha-chains of C4BP comprise a binding site for LRP. We propose that LRP mediates at least in part the catabolism of C4BP and, as such, may regulate C4BP participation in complement and hemostatic processes.