The role of activated coagulation factor XII in overall clot stability and fibrinolysis

Activated coagulation factor XII (α-FXIIa) is able to bind to fibrin(ogen) and increases the density and stiffness of the fibrin clot. Conversely, proteins of the contact system and the fibrinolytic system show a high degree of homology and α-FXIIa can convert plasminogen into plasmin resulting in fibrin degradation. Therefore, we studied the contribution of α-FXIIa to overall clot stability and plasmin driven fibrinolysis in the absence and presence of tissue plasminogen activator (tPA). We observed that α-FXIIa directly converted plasminogen into plasmin and reduced clot lysis time at all tPA concentrations tested (15–1500 pM). Simultaneous assessment of plasmin generation (chromogenic substrate S-2251) and fibrin formation and degradation (absorbance at 405 nm), showed an earlier onset of fibrinolysis and plasmin formation in the presence of α-FXIIa. Fibrinolysis of clots formed under flow conditions, revealed that incorporation of α-FXIIa accelerated clot breakdown (fluorescence release of labeled fibrin) by additional plasmin generation on top of formation by tPA. Scanning electron microscopy (SEM) revealed that the surface area pore size increased in the presence compared with the absence of α-FXIIa when fibrinolysis was initiated by the conversion of plasminogen with tPA during clot formation. α-FXIIa enhances fibrinolysis in the presence of plasminogen, irrespective of whether tPA was present during clot formation or was added afterwards to initiate fibrinolysis. We postulate that FXIIa first strengthens the clot structure during clot formation and thereafter contributes towards fibrinolysis

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