Qiufang Cheng

Effects of factor IX or factor XI deficiency on ferric chloride‐induced carotid artery occlusion in mice

Summary.  Factor XI (FXI) and factor IX (FIX) are zymogens of plasma serine proteases required for normal hemostasis. The purpose of this work was to evaluate FXI and FIX as potential therapeutic targets by means of a refined ferric chloride (FeCl3)‐induced arterial injury model in factor‐deficient mice. Various concentrations of FeCl3 were used to establish the arterial thrombosis model in C57BL/6 mice. Carotid artery blood flow was completely blocked within 10 min in C57BL/6 mice by application of 3.5% FeCl3. In contrast, FXI‐ and FIX‐deficient mice were fully protected from occlusion induced by 5% FeCl3, and were partially protected against the effect of 7.5% FeCl3. The protective effect was comparable to very high doses of heparin (1000 units kg−1) and substantially more effective than aspirin. While FXI and FIX deficiencies were indistinguishable in the carotid artery injury model, there was a marked difference in a tail‐bleeding‐time assay. FXI‐deficient and wild‐type mice have similar bleeding times, while FIX deficiency was associated with severely prolonged bleeding times (>5.8‐fold increase, P < 0.01). Given the relatively mild bleeding diathesis associated with FXI deficiency, therapeutic inhibition of FXI may be a reasonable strategy for treating or preventing thrombus formation.

A role for factor XIIa–mediated factor XI activation in thrombus formation in vivo

Mice lacking factor XII (fXII) or factor XI (fXI) are resistant to experimentally-induced thrombosis, suggesting fXIIa activation of fXI contributes to thrombus formation in vivo. It is not clear whether this reaction has relevance for thrombosis in pri mates. In 2 carotid artery injury models (FeCl(3) and Rose Bengal/laser), fXII-deficient mice are more resistant to thrombosis than fXI- or factor IX (fIX)-deficient mice, raising the possibility that fXII and fXI function in distinct pathways. Antibody 14E11 binds fXI from a variety of mammals and interferes with fXI activation by fXIIa in vitro. In mice, 14E11 prevented arterial occlusion induced by FeCl(3) to a similar degree to total fXI deficiency. 14E11 also had a modest beneficial effect in a tissue factor-induced pulmonary embolism model, indicating fXI and fXII contribute to thrombus formation even when factor VIIa/tissue factor initiates thrombosis. In baboons, 14E11 reduced platelet-rich thrombus growth in collagen-coated grafts inserted into an arteriovenous shunt. These data support the hypothesis that fXIIa-mediated fXI activation contributes to thrombus formation in rodents and primates. Since fXII deficiency does not impair hemostasis, targeted inhibition of fXI activation by fXIIa may be a useful antithrombotic strategy associated with a low risk of bleeding complications.

Factor XII inhibition reduces thrombus formation in a primate thrombosis model

The plasma zymogens factor XII (fXII) and factor XI (fXI) contribute to thrombosis in a variety of mouse models. These proteins serve a limited role in hemostasis, suggesting that antithrombotic therapies targeting them may be associated with low bleeding risks. Although there is substantial epidemiologic evidence supporting a role for fXI in human thrombosis, the situation is not as clear for fXII. We generated monoclonal antibodies (9A2 and 15H8) against the human fXII heavy chain that interfere with fXII conversion to the protease factor XIIa (fXIIa). The anti-fXII antibodies were tested in models in which anti-fXI antibodies are known to have antithrombotic effects. Both anti-fXII antibodies reduced fibrin formation in human blood perfused through collagen-coated tubes. fXII-deficient mice are resistant to ferric chloride-induced arterial thrombosis, and this resistance can be reversed by infusion of human fXII. 9A2 partially blocks, and 15H8 completely blocks, the prothrombotic effect of fXII in this model. 15H8 prolonged the activated partial thromboplastin time of baboon and human plasmas. 15H8 reduced fibrin formation in collagen-coated vascular grafts inserted into arteriovenous shunts in baboons, and reduced fibrin and platelet accumulation downstream of the graft. These findings support a role for fXII in thrombus formation in primates.

Evidence for factor IX-independent roles for factor XIa in blood coagulation

Factor XIa is traditionally assigned a role in FIX activation during coagulation. However, recent evidence suggests this protease may have additional plasma substrates.

Activated factor XI increases the procoagulant activity of the extrinsic pathway by inactivating tissue factor pathway inhibitor

Activation of coagulation factor XI (FXI) may play a role in hemostasis. The primary substrate of activated FXI (FXIa) is FIX, leading to FX activation (FXa) and thrombin generation. However, recent studies suggest the hemostatic role of FXI may not be restricted to the activation of FIX. We explored whether FXI could interact with and inhibit the activity of tissue factor pathway inhibitor (TFPI). TFPI is an essential reversible inhibitor of activated factor X (FXa) and also inhibits the FVIIa-TF complex. We found that FXIa neutralized both endothelium- and platelet-derived TFPI by cleaving the protein between the Kunitz (K) 1 and K2 domains (Lys86/Thr87) and at the active sites of the K2 (Arg107/Gly108) and K3 (Arg199/Ala200) domains. Addition of FXIa to plasma was able to reverse the ability of TFPI to prolong TF-initiated clotting times in FXI- or FIX-deficient plasma, as well as FXa-initiated clotting times in FX-deficient plasma. Treatment of cultured endothelial cells with FXIa increased the generation of FXa and promoted TF-dependent fibrin formation in recalcified plasma. Together, these results suggest that the hemostatic role of FXIa may be attributed not only to activation of FIX but also to promoting the extrinsic pathway of thrombin generation through inactivation of TFPI.

The dimeric structure of factor XI and zymogen activation.

Factor XI (fXI) is a homodimeric zymogen that is converted to a protease with 1 (1/2-fXIa) or 2 (fXIa) active subunits by factor XIIa (fXIIa) or thrombin. It has been proposed that the dimeric structure is required for normal fXI activation. Consistent with this premise, fXI monomers do not reconstitute fXI-deficient mice in a fXIIa-dependent thrombosis model. FXI activation by fXIIa or thrombin is a slow reaction that can be accelerated by polyanions. Phosphate polymers released from platelets (poly-P) can enhance fXI activation by thrombin and promote fXI autoactivation. Poly-P increased initial rates of fXI activation 30- and 3000-fold for fXIIa and thrombin, respectively. FXI monomers were activated more slowly than dimers by fXIIa in the presence of poly-P. However, this defect was not observed when thrombin was the activating protease, nor during fXI autoactivation. The data suggest that fXIIa and thrombin activate fXI by different mechanisms. FXIIa may activate fXI through a trans-activation mechanism in which the protease binds to 1 subunit of the dimer, while activating the other subunit. For activation by thrombin, or during autoactivation, the data support a cis-activation mechanism in which the activating protease binds to and activates the same fXI subunit.

Factor XI apple domains and protein dimerization

Summary.  The coagulation protease zymogen factor (F)XI is a disulfide bond‐linked homodimer, a configuration that is necessary for protein secretion and function. The non‐catalytic portion of the FXI polypeptide contains four repeats called apple domains (A1–A4). It is clear that FXI A4 plays a key role in dimer formation, however, the importance of other apple domains to this process has not been examined. We prepared recombinant FXI molecules in which apple domains were exchanged with those of the structurally homologous monomeric protein prekallikrein (PK). As expected, FXI/PK chimeras containing FXI A4 are dimers, while those with PK A4 are monomers. FXI A4 contains cysteine at position 321 that forms the interchain disulfide bond, while Cys321 in PK is unavailable for interchain bond formation because it is paired with Cys326. FXI/PK chimeras containing PK A4 were modified by changing Cys326 to glycine, leaving Cys321 unpaired (PKA4‐Gly326). FXI with a PK A4 domain is a monomer, however, introducing PKA4‐Gly326 results in a disulfide bond‐linked dimer. This indicates that dimer formation can occur in the absence of FXI A4. In proteins containing PKA4‐Gly326, replacing FXI A3 with PK A3 partially interferes with dimer formation, while substitution of A2, or A2 and A3 prevents dimer formation. PKA4‐Gly326 cannot induce the native PK molecule to dimerize. The data indicate that FXI A2 and A3 make contributions to dimer formation. As these domains are involved in activities that require dimeric protein, it seems reasonable that they stabilize this conformation.

Factor XI anion-binding sites are required for productive interactions with polyphosphate

Conversion of factor XI (FXI) to FXIa is enhanced by polymers of inorganic phosphate (polyP). This process requires FXI to bind to polyP. Each FXIa subunit contains anion‐binding sites (ABSs) on the apple 3 (A3) and catalytic domains that are required for normal heparin‐mediated enhancement of FXIa inhibition by antithrombin.

Factor XI Deficiency Alters the Cytokine Response and Activation of Contact Proteases during Polymicrobial Sepsis in Mice.

Sepsis, a systemic inflammatory response to infection, is often accompanied by abnormalities of blood coagulation. Prior work with a mouse model of sepsis induced by cecal ligation and puncture (CLP) suggested that the protease factor XIa contributed to disseminated intravascular coagulation (DIC) and to the cytokine response during sepsis. We investigated the importance of factor XI to cytokine and coagulation responses during the first 24 hours after CLP. Compared to wild type littermates, factor XI-deficient (FXI-/-) mice had a survival advantage after CLP, with smaller increases in plasma levels of TNF-α and IL-10 and delayed IL-1β and IL-6 responses. Plasma levels of serum amyloid P, an acute phase protein, were increased in wild type mice 24 hours post-CLP, but not in FXI-/- mice, supporting the impression of a reduced inflammatory response in the absence of factor XI. Surprisingly, there was little evidence of DIC in mice of either genotype. Plasma levels of the contact factors factor XII and prekallikrein were reduced in WT mice after CLP, consistent with induction of contact activation. However, factor XII and PK levels were not reduced in FXI-/- animals, indicating factor XI deficiency blunted contact activation. Intravenous infusion of polyphosphate into WT mice also induced changes in factor XII, but had much less effect in FXI deficient mice. In vitro analysis revealed that factor XIa activates factor XII, and that this reaction is enhanced by polyanions such polyphosphate and nucleic acids. These data suggest that factor XI deficiency confers a survival advantage in the CLP sepsis model by altering the cytokine response to infection and blunting activation of the contact (kallikrein-kinin) system. The findings support the hypothesis that factor XI functions as a bidirectional interface between contact activation and thrombin generation, allowing the two processes to influence each other.

A comparison of the effects of factor XII deficiency and prekallikrein deficiency on thrombus formation

Studies with animal models implicate the plasma proteases factor XIIa (FXIIa) and α-kallikrein in arterial and venous thrombosis. As congenital deficiencies of factor XII (FXII) or prekallikrein (PK), the zymogens of FXIIa and α-kallikrein respectively, do not cause bleeding disorders, inhibition of these enzymes may have therapeutic benefit without compromising hemostasis. The relative contributions of FXIIa and α-kallikrein to thrombosis in animal models are not clear. We compared mice lacking FXII or PK to wild type mice in established models of arterial thrombosis. Wild type mice developed carotid artery occlusion when the vessel was exposed to a 3.5% solution of ferric chloride (FeCl3). FXII-deficient mice were resistant to occlusion at 5% FeCl3 and partially resistant at 10% FeCl3. PK-deficient mice were resistant at 3.5% FeCl3 and partially resistant at 5% FeCl3. Mice lacking high molecular weight kininogen, a cofactor for PK activation and activity, were also partially resistant to thrombosis at 5% FeCl3. Induction of carotid artery thrombosis with Rose Bengal was delayed in FXII-deficient mice compared to wild type or PK-deficient animals. In human plasma supplemented with silica, DNA or collagen to induce contact activation, an antibody to the FXIIa active site was more effective at preventing thrombin generation than an antibody to the α-kallikrein active site. Similarly, the FXIIa antibody was more effective at reducing fibrin formation in human blood flowing through collagen coated-tubes. The findings suggest that inhibitors of FXIIa will have more potent anti-thrombotic effects than inhibitors of α-kallikrein.