Factor IXa variants resistant to plasma inhibitors enhance clot formation in vivo.

Factor IXa (FIXa) plays a pivotal role in coagulation by contributing to FX activation via the intrinsic pathway. Although antithrombin (AT) and other plasma inhibitors are thought to regulate FIXa procoagulant function, the impact of FIXa inhibition on thrombin generation and clot formation in vivo remains unclear. Here, we generated FIXa variants with altered reactivity to plasma inhibitors that target the FIXa active site but maintain procoagulant function when bound to its cofactor, FVIIIa. We found that selected FIXa variants (eg, FIXa-V16L) have a prolonged activity half-life in the plasma due, in part, to AT resistance. Studies using hemophilia B mice have shown that delayed FIXa inhibition has a major impact on reducing the bleeding phenotype and promoting thrombus formation following administration of FIX protein. Overall, these results demonstrate that the regulation of FIXa inhibition contributes in a major way to the spatial and temporal control of coagulation at the site of vascular injury. Our findings provide novel insights into the physiological regulation of FIXa, enhance our understanding of thrombus formation in vivo via the intrinsic pathway, and suggest that altering FIXa inhibition could have therapeutic benefits.

Nitrophorin 2, a factor IX(a)-directed anticoagulant, inhibits arterial thrombosis without impairing haemostasis.

Nitrophorin 2 (NP2) is a 20 kDa lipocalin identified in the salivary gland of the blood sucking insect, Rhodnius prolixus. It functions as a potent inhibitor of the intrinsic pathway of coagulation upon binding to factor IX (FIX) or FIXa. Herein we have investigated the in vivo antithrombotic properties of NP2. Surface plasmon resonance assays demonstrated that NP2 binds to rat FIX and FIXa with high affinities (KD = 43 and 47 nM, respectively), and prolongs the aPTT without affecting the PT. In order to evaluate NP2 antithrombotic effects in vivo two distinct models of thrombosis in rats were carried out. In the rose Bengal/laser induced injury model of arterial thrombosis, NP2 increased the carotid artery occlusion time by ≍35 and ≍155%, at doses of 8 and 80 µg/kg, respectively. NP2 also inhibited thrombus formation in an arterio-venous shunt model, showing ≍60% reduction at 400 µg/kg (i.v. administration). The antithrombotic effect lasted for up to 48 hours after a single i.v. dose. Notably, effective doses of NP2 did not increase the blood loss as evaluated by tail-transection model. In conclusion, NP2 is a potent and long-lasting inhibitor of arterial thrombosis with minor effects on haemostasis. It might be regarded as a potential agent for the treatment of human cardiovascular diseases.

The Na+ binding channel of human coagulation proteases: novel insights on the structure and allosteric modulation revealed by molecular surface analysis.

Thrombovascular diseases result from imbalanced haemostasis and comprise important health problems in the aging population worldwide. The activity of enzymes pertaining to the coagulation cascade of mammalians exhibit several control mechanisms in order to maintain a proper balance between bleeding and thrombosis. For instance, human coagulation serine proteases carrying a F225 or Y225 are allosteric modulated by the binding of Na+ in a water-filled channel connected to the primary specificity pocket (S1 subsite) of these enzymes. We have characterized the structure, topography and lipophilicity of this channel in the ligand-free fast (sodium-bound) and slow (sodium-free) forms of thrombin, in the sole available structure of activated protein C and in several structures of the coagulation factors VIIa, IXa and Xa, differing in the nature of the bound inhibitor and in the occupancy of exosite-I as well as the Ca2+ and Na+ binding sites. Opposite to thrombin, the aqueous channels in all other coagulation enzymes sheltering a Na+ binding site do not have an aperture on the enzyme surface opposite to the S1 subsite entrance. In these enzymes, the lack of the three-residue insertion in loop 1 (183-189) as found in thrombin allied to compensatory mutations in the positions 187-185 and 222 effects a constriction in the water-filled channel that ends up by segregating the ion binding site from the S1 subsite. We also disclosed major topographical changes on the thrombin's surface upon sodium release and transition to the slow form that culminate in the narrowing of the S1 subsite entrance and, strikingly, in the loss of communication between the primary specificity pocket and the exosite-I. Such observation is in accordance with existing experimental data demonstrating thermodynamic linkage between these distant regions on the thrombin surface. Conformational changes in F34, L40, R73 and T74 were the main responsible for this effect. A path by which these changes in the vicinity of exosite-I could be transmitted to the S1 subsite and, consequently, to the sodium binding site is proposed.