FX Activation Research Articles

Abstract 3096: Role Of Circulating Phosphatidylserine In The Procoagulant Activity Of Amniotic Fluid

Background: Amniotic fluid (AF) embolism is one of the most catastrophic complications during pregnancy. While studies primarily attributed the procoagulability of AF to circulating tissue factor (TF), the exact mechanism remains unclear. Aims: Define the procoagulant mechanisms of AF. Methods: Clotting time assays were performed using normal human plasma or plasma depleted of factor (F)XII, XI, X, IX, VII, V, or prekallikrein (PK). Chromogenic substrate assays were used to quantify FX activation by the TF/FVIIa complex and prothrombin activation by FXa. Phosphatidylserine (PS) levels were quantified using a fluorometric kit. Results: AF shortened the clotting time of normal plasma from 572±83 to 160±2 seconds; AF-induced clotting times were equivalent for FXII, PK, FXI, FX, FIX, or FV-depleted plasma or in the presence of contact pathway inhibitors as compared to normal plasma. In contrast, the procoagulant effects of AF were diminished or absent for FVII-depleted plasma or in the presence of a blocking anti-TF antibody or low-molecular-weight heparin. In a purified system, AF reduced FX activation by the TF/FVIIa complex. The addition of a blocking anti-tissue factor pathway inhibitor (TFPI) antibody reversed the effect of AF on FX activation. Western blotting confirmed the existence of both TF and TFPI in AF. AF enhanced prothrombin activation by FXa. The addition of annexin V, or lactadherin, which bind to PS, or the use of Gla-domainless prothrombin mitigated the effect of AF on prothrombin activation. PS levels in AF and normal plasma were 811±376 and 10.4±3.8 μM, respectively. Conclusions: The procoagulability of AF is independent of the contact pathway while being sensitive to both TF and TFPI levels. Furthermore, PS in AF significantly contributes to its procoagulability. This knowledge is important when developing strategies to lessen the procoagulability of AF without compromising hemostasis in the setting of AF embolism-associated coagulopathy.

Fitusiran reduces bleeding in factor X–deficient mice

AbstractFactor X (FX) deficiency is a rare bleeding disorder manifesting a bleeding tendency caused by low FX activity levels. We aim to explore the use of fitusiran (an investigational small interfering RNA that silences antithrombin expression) to increase thrombin generation and the in vivo hemostatic potential under conditions of FX deficiency. We therefore developed a novel model of inducible FX deficiency, generating mice expressing <1% FX activity and antigen (f10low mice). Compared with control f10WT mice, f10low mice had sixfold and fourfold prolonged clotting times in prothrombin time and activated partial prothrombin time assays, respectively (P < .001). Thrombin generation was severely reduced, irrespective of whether tissue factor or factor XIa was used as an initiator. In vivo analysis revealed near-absent thrombus formation in a laser-induced vessel injury model. Furthermore, in 2 distinct bleeding models, f10low mice displayed an increased bleeding tendency compared with f10WT mice. In the tail-clip assay, blood loss was increased from 12 ± 16 μL to 590 ± 335 μL (P < .0001). In the saphenous vein puncture (SVP) model, the number of clots generated was reduced from 19 ± 5 clots every 30 minutes for f10WT mice to 2 ± 2 clots every 30 minutes (P < .0001) for f10low mice. In both models, bleeding was corrected upon infusion of purified FX. Treatment of f10low mice with fitusiran (2 × 10 mg/kg at 1 week interval) resulted in 17 ± 6% residual antithrombin activity and increased thrombin generation (fourfold and twofold to threefold increase in endogenous thrombin potential and thrombin peak, respectively). In the SVP model, the number of clots was increased to 8 ± 6 clots every 30 minutes (P = .0029). Altogether, we demonstrate that reduction in antithrombin levels is associated with improved hemostatic activity under conditions of FX deficiency.

Emicizumab promotes factor Xa generation on endothelial cells

BackgroundUntil recently, the treatment of hemophilia A relied on factor (F)VIII replacement. However, up to one-third of patients with severe hemophilia A develop neutralizing alloantibodies that render replacement therapies ineffective. The development of emicizumab, a bispecific antibody that partially mimics FVIIIa, has revolutionized the treatment of these patients. However, the use of an activated prothrombin complex concentrate [FEIBA (Takeda)] to treat breakthrough bleeding in patients on emicizumab has been associated with thrombotic complications including a unique microangiopathy. ObjectivesWe hypothesized that the thrombotic complications observed with the combination of emicizumab and FEIBA might be due to excessive expression of procoagulant activity on the surface of endothelial cells. MethodsWe examined the ability of emicizumab to promote FX activation on endothelial cells using 2 cell culture models. ResultsWe found that endothelial cells readily support emicizumab-mediated activation of FX by FIXa. The level of FXa generation depends on the concentration of available FIXa. The addition of FEIBA to emicizumab increased FXa generation in a dose-dependent manner on endothelial cells in both models. The rate of FXa generation was further enhanced by endothelial cell activation. However, unlike emicizumab, we found limited FXa generation in the presence of FVIII(a), which followed a significant lag time and was not dependent on FIXa concentration under these conditions. ConclusionEmicizumab promotes FXa generation on the surface of endothelial cells, which is markedly enhanced in the presence of FEIBA. These findings demonstrate a potential mechanism for the thrombotic complications seen with the combined use of emicizumab and FEIBA.

Site-directed mutagenesis of tissue factor pathway inhibitor–binding exosite D60A on factor VII results in a new factor VII variant with lower coagulant activity

BackgroundRecombinant factor (F)VIIa (rFVIIa) has been approved by the US Food and Drug Administration for the treatment of hemophilia A and B with inhibitors and congenital FVII deficiency. Moreover, the investigational uses of rFVIIa are becoming of interest since it can be used to treat various clinical bleeding conditions. However, there is evidence showing that rFVIIa is a potent procoagulant agent that potentially leads to an increased risk of thrombotic complications. ObjectivesTo design a new rFVII with lower coagulant activity that could potentially be used as an alternative hemostatic agent aiming to minimize the risk of thrombogenicity. MethodsD60A was introduced into the F7 sequence by polymerase chain reaction–based mutagenesis. Wild type (WT) and D60A were generated in human embryonic kidney 293T cells by stable transfection. FVII coagulant activities were determined by amidolytic cleavage of the FVIIa-specific substrate, 2-step FXa generation, thrombin generation (TG), and clot-based assays. ResultsWT and D60A demonstrated similar FVIIa amidolytic activity. However, D60A showed approximately 50% activity on FX activation and significantly longer lag time in the TG assay than that shown by WT. The clotting time produced by D60A spiked in FVII-deficient plasma was significantly prolonged than that of WT. Additionally, the ex vivo plasma half-lives of WT and D60A were comparable. ConclusionD60A demonstrated lower coagulant activities, most likely due to the weakening of FX binding, leading to impaired FX activation and delayed TG and fibrin formation. Considering that a plasma FVII level of 15% to 25% is adequate for normal hemostasis, D60A is a molecule of interest for future development of an rFVII with a lesser extent of thrombogenicity.

A Compound Heterozygosis of Two Novel Mutations in vWF Exacerbates vWD in a Chinese Pedigree.

von Willebrand disease (vWD), caused by mutations in the von Willebrand factor (vWF) coding gene, is a disease characterized by abnormal coagulation activity and a severe tendency for hemorrhage. Therefore, identifying mutations in vWF is important for diagnosing congenital vWD. We studied a 23-year-old male vWD patient and his parents. Clotting methods were used to determine activated partial thromboplastin time (aPTT), prothrombin time (PT), fibrinogen (FIB) levels, FVIII activity. Chromogenic substrate method was used to determine vWF antigen and activity. The platelet count was determined. Mutations were searched using whole-exome sequencing and certified by Sanger sequencing. Clinical data, including activated partial thromboplastin time (APTT), prothrombin time (PT), thrombin time (TT), fibrinogen levels, FX activity, FX antigen levels, and the platelet count were collected. A mixing study was performed to eliminate the presence of coagulation factor inhibitors and lupus anticoagulants. Mutations were screened by using whole-exome sequencing (WES) and were verified by using Sanger sequencing. The proband showed severely decreased vWF antigen, vWF activity, and FVIII activity. RIPA (RISTO-CETIN-induced platelet aggregation) was 0%. Data from WES showed that the proband carried compound heterozygous variants vWF: NM_000552.5 (c.3213C>A p.Cys1071Ter) and vWF: NM_000552.5 (c.6598+2T>C). The proband's mother carried variant vWF: NM_000552.5 (c.3213C>A p.Cys1071Ter) while the proband's father carried variant vWF: NM_000552.5 (c.6598+2T>C). All laboratory test indexes of the proband's parents, including vWF antigen, vWF activity, and FVIII activity, were within the normal ranges. We identified a compound heterozygosis with two novel mutations in vWF (c.3213C>A, c.6598+2T >C) in a family pedigree, and our results demonstrate that the compound heterozygous mutations probably exacerbate vWD.

Thrombosis Caused By a Novel Coagulation Factor IX Mutation (FIX Shanghai II)

Most thrombophilia patients are caused by insufficient suppression of coagulation reactions, which could be either mediated by deficiencies of protein C, protein S,antithrombin, or inhibition-resistant coagulation factor mutants, such as Factor V Leiden and prothrombin Yukuhashi. The thrombosis caused by coagulation factor mutants with increased procoagulant activity is very rare and so far only two Factor IX (FIX) variants involving residue Arg384, FIX Padua (p.Arg384Leu) and Shanghai (p.Arg384Gln), which increased FIX activity by up to 8 folds, had been reported to be associated with the incidence of thrombosis. In a young male venous thrombosis patient we had identified a novel F9 gene missense mutation c.1018G&amp;gt;A, resulting in p. Glu340Lys substitution (designated as FIX Shanghai II). The patient's APTT time was 28.9 seconds (normal reference 22.3~38.7s), and his PT was also within the normal reference range (11.5 seconds, normal reference 10.0~16.0s). Although the patient had the FIX: Ag comparable to the normal reference, 128.20±6.07%, the his FIX:C was around 201.69±10.38% of normal control (normal reference 50~150%). Thrombin generation assay (TGA) showed that compared with normal control, the patient had a shorter Lag time (2.67 vs 3.33 min), elevated ETP (1649.43 vs 1311.62 nM*min), and higher Peak value (387.34 vs 200.86 nM), indicating increased global coagulation activity of the patient. The activity of protein C, protein S, and antithrombin were all within the normal reference ranges and the patient was negative for antiphospholipid antibodies. Consistent with the patient's coagulation laboratory manifestations, the purified recombinant FIX Glu340Lys mutant showed 1.82 folds higher procoagulant activity than wild type FIX as determined by FIX:C/FIX:Ag ratio. The recombinant FIX Shanghai II mutant can be converted into FIXa by activated factor XI (FXIa) in a similar fashion as FIX WT. The kinetic study of FIXa-catalyzed FX activation showed that p. Glu340Lys mutation led to accelerated FX activation by FIXa. The p.Glu340Lys mutation also enhanced the procoagulant activity of previously reported thrombosis-causing FIX mutants, FIX Shanghai and Padua, in a similar fashion as it did on FIX WT. The FIX:C/FIX:Ag ratio of double mutants containing Glu340Lys and Arg384Gln (FIX Shanghai) or Arg384Leu (FIX Padua) was about twice of FIX Shanghai or Padua alone, 11.48- and 22.53-folds vs 6.16- and 8.13- folds higher than FIX WT respectively.

Survival Advantage Associated with Heterozygous Factor V Leiden Mutation in Sars-Cov-2-Infected K18-hACE2 Mice

The pathogenesis of coronavirus disease 2019 (COVID-19) complications in critically ill patients involves virus-mediated cellular damage in infected tissue and secondary organ damage associated with a hyperinflammatory response. The proinflammatory milieu can result in endothelial dysfunction, predisposing patients to thrombosis leading to a life-threatening condition known as COVID-19-associated coagulopathy (CAC) which is driven by cellular and molecular mechanisms that are still unclear. We developed a mouse model based on the K18-hACE2 transgenic mouse recapitulating many of the CAC-associated pathological findings observed in human patients offering a reliable animal model for the study of SARS-CoV-2 pathogenesis. Plasma analysis revealed virus-induced upregulation of endothelial activation markers and alterations of all the measured coagulation factors' activities, resulting first in increased vascular leakage in the lung on day 5 post-infection, followed by the appearance of focal hemorrhagic lesions potentially associated with local thrombotic events on day 7. The infection-associated procoagulant phenotype appeared as early as day 3 post-infection (p.i.). Prothrombin time showed a 1/3 reduction in the normal clotting time in males. The overall procoagulant state was also reflected in the alteration of Factor(F) VIII and FX activity increasing to ~150% compared to uninfected controls. FIX showed the most significant alteration and was ~200% of the normal activity on day 3 p.i. and gradually increased over time, reaching ~350%. We also observed an increase in the activity of FV starting 3 days p.i. at ~210% of the normal level and persisting unchanged up to day 7 p.i. As reported during human infections, FV activity increased without significant changes in protein concentration or FVa levels. Natural anticoagulant and fibrinolytic mechanisms were dysregulated during virus infection resulting in a profound imbalance in thrombus formation and resolution. Infected K18-hACE2 mice showed downregulation of plasma protein C concentration which was not associated with any alteration of liver function, while plasma protein S concentration remained unaltered. Given the procoagulant environment generated after SARS-CoV-2 infection, reducing activated protein C (APC) anticoagulant and cytoprotective activities by blocking APC's active site with the SPC-54 monoclonal antibody worsened disease outcome and brought the mortality rate from 50% to 90%. In this observed procoagulant pathological context, where we observe increased activity of FV and where a deficiency of APC functions resulted in increased mortality, it wouldn't be surprising to observe an even more severe phenotype with the addition of APC resistance. To test this idea, we generated K18-hACE2 mice harboring the homologous human FV Leiden (FV L) mutation (R504Q). The Leiden mutation in FV eliminates one of several sites in FVa that are substrates for proteolysis by APC, resulting in diminished inactivation of FVa by APC and preventing the formation of the anticoagulant form of FV that serves as a cofactor for protein S-dependent inactivation of FVIIIa by APC. Upon SARS-CoV-2 infection, the presence of the homozygous FV L mutation in K18-hACE2 mice didn't affect the severity of the disease as measured by body weight loss during the course of the infection, and homozygous mutated mice had the same mortality rate as FV WT mice. Surprisingly, K18-hACE2 male mice carrying a heterozygous FV L mutation were extremely protected from SARS-CoV-2 infection, as their mortality dropped from 50% to only 15%. Histological analysis reveals how heterozygous FV L mice displayed a great reduction in immune infiltrate-associated fibrin deposition, suggesting an unexpected protective role of this prothrombotic mutation in the development of CAC. The protective effect of FV L heterozygosity may be attributable to enhanced thrombin formation which boosts inflammation and enhanced APC generation controlling proinflammatory and prothrombotic signaling, thus showing a delicate balance achieved by FV L heterozygosity that was lost for FV L homozygosity. As seen also in mouse models of bacterial sepsis, such favorable effects associated with FV L support the somewhat counterintuitive speculation that a partial increase in thrombin production in the early phase of the infection may support the resolution of COVID-19 complications.

Factor VIII: A Dynamic Modulator of Hemostasis and Thrombosis in Trauma.

A trace amount of thrombin cleaves factor VIII (FVIII) into an active form (FVIIIa), which catalyzes FIXa-mediated activation of FX on the activated platelet surface. FVIII rapidly binds to von Willebrand factor (VWF) after secretion and becomes highly concentrated via VWF-platelet interaction at a site of endothelial inflammation or injury. Circulating levels of FVIII and VWF are influenced by age, blood type (nontype O > type O), and metabolic syndromes. In the latter, hypercoagulability is associated with chronic inflammation (known as thrombo-inflammation). In acute stress including trauma, releasable pools of FVIII/VWF are secreted from the Weibel-Palade bodies in the endothelium and then augment local platelet accumulation, thrombin generation, and leukocyte recruitment. Early systemic increases of FVIII/VWF (>200% of normal) levels in trauma result in a lower sensitivity of contact-activated clotting time (activated partial thromboplastin time [aPTT] or viscoelastic coagulation test [VCT]). However, in severely injured patients, multiple serine proteases (FXa plasmin and activated protein C [APC]) are locally activated and may be systemically released. Severity of traumatic injury correlates with prolonged aPTT and elevated activation markers of FXa, plasmin, and APC, culminating in a poor prognosis. In a subset of acute trauma patients, cryoprecipitate that contains fibrinogen, FVIII/VWF, and FXIII is theoretically advantageous over purified fibrinogen concentrate to promote stable clot formation, but comparative efficacy data are lacking. In chronic inflammation or subacute phase of trauma, elevated FVIII/VWF contributes to the pathogenesis of venous thrombosis by enhancing not only thrombin generation but also augmenting inflammatory functions. Future developments in coagulation monitoring specific to trauma patients, and targeted to enhancement or inhibition of FVIII/VWF, are likely to help clinicians gain better control of hemostasis and thromboprophylaxis. The main goal of this narrative is to review the physiological functions and regulations of FVIII and implications of FVIII in coagulation monitoring and thromboembolic complications in major trauma patients.

Factor VIII mutated with Lys1813Ala within the factor IXa-binding region enhances intrinsic coagulation potential.

Factor VIII (FVIII) functions as a cofactor of FIXa for FX activation in the intrinsic tenase complex. The 1811-1818 region in the FVIII A3 domain was observed to contribute to FIXa binding, and the K1813A/K1818A mutant increased the binding affinity for FIXa. The current study aims to identify mutated FVIII protein(s) that increase FVIIIa cofactor activity in the 1811-1818 region. FVIII mutants with K1813A, K1818A, and K1813A/K1818A were expressed in baby hamster kidney cells and were followed by assessments using purified and global coagulation assays for mouse models with hemophilia A (HA). A surface plasmon resonance-based assay revealed that the Kd value of FVIII-K1813A for FIXa interaction was lower than that of the wild-type (WT) (3.9±0.7/6.3±0.3 nM). However, the Km value of FVIII-K1813A for FIXa on tenase activity was comparable with that of the WT, whereas the kcat of this mutant was significantly greater than that of the WT. Thrombin-catalyzed FVIII-K1813A activation was ∼1.3-fold more enhanced than that of the WT, and the spontaneous decay of activated FVIII-K1813A was ∼2.5-fold slower than that of WT. The heat stability assay revealed that the decay rate of FVIII-K1813A was ∼2.5-fold slower than that of WT. Thrombin generation assay and rotational thromboelastometry using blood samples from patients with HA demonstrated that the addition of FVIII-K1813A (0.5 nM) exhibited a coagulation potential compatible with that of WT (1 nM). In the tail clip assay of HA mice, FVIII-K1813A showed a two- to fourfold higher hemostatic potential than that of the WT. FVIII-K1813A, with higher a FIXa binding affinity, enhances the global coagulation potential because of the stability of FVIII/FVIIIa molecules.

The hemostatic profile of cold-stored whole blood from non-greyhound and greyhound dogs over 42 days

To compare the hemostatic characteristics of cold-stored whole blood (CSWB) from non-greyhound dogs (NGD) and greyhound dogs (GD) over 42 days of storage, notably, platelet closure time (PCT) (NGD only), manual platelet count (PLT) (GD only), ellagic acid (INTEM) and tissue factor activated (EXTEM) rotational thromboelastometry, prothrombin (PT) and activated partial thromboplastin time (aPTT), fibrinogen concentration (FIB), and the activities of factors (F) FII, FV, FVII, FVIII, FIX, FX, FXIII antigen (FXIII:Ag), and von Willebrand factor antigen (vWF:Ag). Whole blood from 10 NGD and 10 GD, was refrigerated in CPD blood bags at 4°C for 42 days. Blood was analyzed before refrigeration (day 0) and at day 1 (d1), 3, 5, 7, 10, 14, 17, 21, 24, 28, 31, 35, 38, and 42. Multivariate linear mixed effects models were created to evaluate coagulation parameters over time and compare NGD and GD. Data are summarized as estimated marginal means with 95% confidence intervals. Significance was set at P < 0.05. The PCT for all NGD CSWB was above the device limit by d7. The PLT for GD CSWB did not change during storage. The mean alpha-angle for INTEM and EXTEM decreased to <50% of baseline at d38 and d31 for NGD, and d31 and d17 for GD CSWB. The mean maximum clot firmness (MCF) for INTEM and EXTEM reduced to <50% of baseline at d42 and d28 for both GD and NGD. PT and aPTT for NGD and GD increased over time. For NGD CSWB, the mean FVIII and vWF:Ag activities decreased to <50% of baseline at d7 and d28, respectively, and FIB reached 0.982 g/dL by d24. For GD CSWB, FVIII, FXIII:Ag and FV activities decreased to <50% of baseline by d3, d38, and d38, respectively, and FIB was 0.982 g/dL at baseline. Alpha-angle and MCF for both INTEM and EXTEM, and activities for FII, FV, FIX, FXIII:Ag were significantly lower, and vWF:Ag was significantly higher overall in GD CSWB compared with NGD. A significant difference in the pattern of change over time was detected between NGD and GD in EXTEM alpha-angle, INTEM and EXTEM MCF, FII, and FVIII activities. The in vitro viscoelastic parameters of GD and NGD CSWB declines over 42 days, but numerous hemostatic parameters (INTEM and EXTEM alpha-angle and MCF, activity of FII, FV, FV, FVII, FIX, FX, FXIII:Ag, vWF:Ag, and FIB) remain within 50% of baseline for more than 14 days. CSWB from GD compared to NGD has reduced hemostatic activity overall, but a similar pattern of decline for most parameters over time.

Different modeling approaches in the simulation of extrinsic coagulation factor X activation: Limitations and areas of applicability.

Proteolytic reactions on the phospholipid membrane surface, so-called "membrane-dependent" reactions, play central role in the process of blood clotting. One particularly important example is FX activation by the extrinsic tenase (VIIa/TF). Here we constructed three mathematical models of FX activation by VIIa/TF: (A) a homogeneous "well-mixed" model, (B) a two-compartment "well-mixed" model, (C) a heterogeneous model with diffusion, to investigate the impact and importance of inclusion of each complexity level. All models provided good description of the reported experimental data and were equivalently applicable for <40 μM of phospholipids. Model C provided better predictions than A, B in the presence of TF-negative phospholipid microparticles. Models predicted that for high TF surface density (STF ) and FX deficiency the FX activation rate was limited by the rate of FX binding to the membrane. For low STF and excess of FX the reaction rate was limited by the tenase formation rate. The analysis of the substrate delivery pathways revealed that FX bound to VIIa/TF predominantly from solution for STF >2.8 × 10-3 nmol/cm2 and from the membrane for lower STF . We proposed the experimental setting to distinguish between the collision-limited and non-collision-limited binding. The analysis of models in flow and non-flow conditions revealed that the model of a vesicle in flow might be substituted by model C in the absence of the substrate depletion. Together, this study was the first which provided the direct comparison of more simple and more complex models. The reaction mechanisms were studied in a wide range of conditions.

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

AbstractFactor 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.

Glycated albumin modulates the contact system with implications for the kallikrein-kinin and intrinsic coagulation systems

BackgroundHuman serum albumin (HSA) is the most abundant plasma protein and is sensitive to glycation in vivo. The chronic hyperglycemic conditions in patients with diabetes mellitus (DM) induce a nonenzymatic Maillard reaction that denatures plasma proteins and forms advanced glycation end products (AGEs). HSA-AGE is a prevalent misfolded protein in patients with DM and is associated with factor XII activation and downstream proinflammatory kallikrein-kinin system activity without any associated procoagulant activity of the intrinsic pathway. ObjectivesThis study aimed to determine the relevance of HSA-AGE toward diabetic pathophysiology. MethodsThe plasma obtained from patients with DM and euglycemic volunteers was probed for activation of FXII, prekallikrein (PK), and cleaved high-molecular-weight kininogen by immunoblotting. Constitutive plasma kallikrein activity was determined via chromogenic assay. Activation and kinetic modulation of FXII, PK, FXI, FIX, and FX via in vitro–generated HSA-AGE were explored using chromogenic assays, plasma-clotting assays, and an in vitro flow model using whole blood. ResultsPlasma obtained from patients with DM contained increased plasma AGEs, activated FXIIa, and resultant cleaved cleaved high-molecular-weight kininogen. Elevated constitutive plasma kallikrein enzymatic activity was identified, which positively correlated with glycated hemoglobin levels, representing the first evidence of this phenomenon. HSA-AGE, generated in vitro, triggered FXIIa-dependent PK activation but limited the intrinsic coagulation pathway activation by inhibiting FXIa and FIXa-dependent FX activation in plasma. ConclusionThese data indicate a proinflammatory role of HSA-AGEs in the pathophysiology of DM via FXII and kallikrein-kinin system activation. A procoagulant effect of FXII activation was lost through the inhibition of FXIa and FIXa-dependent FX activation by HSA-AGEs.

Identification of non-neutralizing anti-factor X autoantibodies in three Japanese cases of autoimmune acquired factor X deficiency.

Autoimmune factor X (FX or F10) deficiency (AiF10D) is an extremely rare acquired haemorrhagic disorder characterized by a severe reduction in FX activity due to autoantibodies against FX. Anti-FX autoantibodies were investigated in four patients with suspected AiF10D, and their properties were analysed. Anti-FX auto antibodies in plasma were detected by ELISA with three of four cases. One case of anti-FX autoantibody negativity was later diagnosed as AL-amyloidosis. IgG1 and IgG3 coexisted in all anti-FX autoantibodies of the three patients with AiF10D (cases X1, X2, and X3). Western blot analysis showed that the antibodies were bound to the FX light chain for cases X2 and X3, but the binding was weak for case X1. When the fusion proteins of a secretory luciferase with full-length FX or its γ-carboxylated glutamic acid (Gla) domain were added to the plasma of the three patients, both fusion proteins were immunoprecipitated as antigen-antibody complexes. Contrarily, the latter fusion protein produced in the presence of warfarin demonstrated a decrease in the collection rate, suggesting that their autoantibodies recognized the light chain and regions containing Gla residues. Since all three patients were essentially negative for FX inhibitors, it was concluded that the anti-FX autoantibodies for these cases were predominantly non-neutralizing. The concentration of the FX antigen also significantly reduced in these patients, suggesting that anti-FX autoantibodies promote the clearance of FX. Immunological anti-FX autoantibody detection is highly recommended to ensure that AiF10D cases are not overlooked, and to start necessary immunosuppressive therapies.

Factor X Activator for Hemophilia Patients with Inhibitors: A Phase 1, First-in-Human, Multi-Center, and Open-Label Trial

Background Bleeding episodes of hemophilia A (HA) or B (HB) patients with inhibitor are difficult to control. Bypass treatment agents have been widely used as hemostatic treatment agents, which provide imperfect treatment for bleeding episodes. Non-factor replacement treatments with different mechanisms have also been explored. There are still some limitations whether in terms of complications or efficacy. Blood coagulation factor Xa (FXa) is straightforward and faster acting for boosting thrombin generation in hemophilia patients, then STSP-0601, a specific FX activator purified from the venom of Daboia Russellii siamensis was developed. Methods This is a phase I, first-in-human, multi-center, open-label, dose-escalation study to investigate the safety, immunogenicity, pharmacokinetics (PK) and pharmacodynamics (PD) of STSP-0601. This study was divided into two parts, the single-dose part (Part A) and the multiple-dose part (Part B). Both HA and HB patients with inhibitors were eligible for this study. Patients received a single intravenous injection of STSP-0601 (0.01 U/kg, 0.04 U/kg, 0.08 U/kg, 0.16 U/kg, 0.32 U/kg or 0.48 U/kg) in Part A or at a maximum six injections of STSP-0601(0.16U/kg) every four hours in Part B in non-bleeding state. This study was registered at www.clinicaltrials.gov with trial number as NCT-04747964 and NCT-05027230. Findings A total of 16 inhibitor patients were enrolled in Part A and 7 inhibitor patients enrolled in Part B. Eight (22.2%) adverse events (AE) in Part A and 18 (75%) AEs in Part B were reported to related to STSP-0601. The most common AEs were increased level of D-Dimer and fibrin and fibrinogen degradation products (FDP). All of these AEs (100%) in Part A and 94.4% (17/18) in Part B were grade 1. Neither serious adverse event (SAE) nor dose-limiting toxicity (DLT) events were reported in both Parts. The change of coagulation factor X compared with the baseline was still within 10% in single dose and 20% in multi-dose administrations. Anti-drug antibody of the administration of STSP-0601 was not detected. In Part A, STSP-0601 exhibited a linear PK profile. Maximum plasma concentration (Cmax) was 110.04±32.03 pg/mL at 0.16U/kg, 163.51±50.79 pg/mL at 0.32U/kg and 296.48±122.65 pg/mL at 0.48U/kg. The elimination half-life (t1/2) were 7.33±0.55h, 8.33±0.41h and 7.57±0.68h respectively. In Part B, the area under the plasma concentration-time curve extrapolated to infinity (AUC0-∞) was 3342.02 h*pg/mL, and the t1/2 was 8.40 h. In Part A and B, both peak height and endogenous thrombin-generating potential (ETP) of thrombo-generation assay (TGA) increased in a dose-dependent manner and reached a maximum value 5-10min after STSP-0601 administration. After four doses of STSP-0601, the increase of TG peak height and the shortening of APTT reached the plateau stage. Compared to the baseline, the decreased value of APTT reached a maximum of 36.2% in 0.48U/kg dose cohort in Part A and 42.8% in Part B after 4 doses. Interpretation Both single and multiple injections of STSP-0601are safe and well tolerated. Starting from the single dose of 0.16 U/kg, STSP-0601 significantly improved the coagulation-related laboratory indicators. These results indicate that STSP-0601 has potential to be used as a hemostatic treatment for bleeding episodes in HA or HB patients with inhibitor.

Assessing the individual roles of FII, FV, and FX activity in the thrombin generation process.

Thrombin generation (TG) is known as a physiological approach to assess the hemostatic function. Although it correlates well with thrombosis and bleeding, in the current setup it is not sensitive to the effects of fluctuations in single coagulation factors. We optimized the calibrated automated thrombinography (CAT) method to quantify FII, FV and FX activity within the coagulation system. The CAT assay was fine-tuned for the assessment of FII, FV and FX by diluting the samples in FII-, FV-, or FX-deficient plasma, respectively, and measuring TG. Plasma FII levels correlated linearly with the ETP up to a plasma concentration of 100% FII. FV and FX levels correlated linearly with the peak height up to a plasma level of 2.5% FV and 10% FX, respectively. Sensitized CAT protocols were designed by adding a fixed volume of a pre-diluted patient sample to FII, FV, and FX deficient plasma in TG experiments. This approach makes the TG measurement dependent on the activity of the respective coagulation factor. The ETP or peak height were quantified as readouts for the coagulation factor activity. The intra- and inter-assay variation coefficients varied from 5.0 to 8.6%, and from 3.5 to 5.9%, respectively. Reference values were determined in 120 healthy subjects and the assays were clinically validated in 60 patients undergoing coronary artery bypass grafting (CABG). The sensitized CAT assays revealed that the contribution of FII, FV, and FX to the TG process was reduced after CABG surgery, leading to reduced prothrombin conversion and subsequently, lower TG.

Mutations of TFPI-binding exosites on factor VII cause bleeding phenotypes in factor VII deficiency

AbstractTissue factor (TF) pathway inhibitor (TFPI) is a Kunitz-type anticoagulation protein that inhibits activated factor VII (FVIIa)/TF complex. Incidentally, many different F7 gene variants, including TFPI-binding exosite mutations, have been reported in patients with congenital FVII deficiency and clinical bleeding variabilities. Here, TFPI-binding exosites (R147 and K192) on FVII zymogen were selectively disrupted to understand their roles in the pathogenesis of bleeding phenotypes. Expression of recombinant FVII variants (R147A, K192A, and R147A/K192A) demonstrated markedly reduced secretion of FVII owing to intracellular retention in the endoplasmic reticulum, as demonstrated by upregulation of the unfolded protein response genes in all FVII variants. FVII variants showed a similar FVII activation pattern and FVIIa amidolytic activity than FVII wild-type (WT). In contrast to FVII activation, R147A and K192A showed a 90% reduction in FX activation relative to WT, whereas the R147A/K192A variant demonstrated a 99% decrease in FX activation. The clotting time was markedly prolonged with R147A and K192A than WT, and no FVII coagulant activity was detected in R147A/K192A. In addition, the thrombin generation assay revealed a significant prolongation of lag time in all FVII variants. Our study explains how mutations of TFPI-binding exosites of FVII can lead to bleeding phenotypes in individuals carrying these aberrancies.

Effect of different irrigation activation methods on non-infected dentinal tubule penetration of medicaments: A CLSM study.

The whole root canal disinfection is crucial in terms of long-term endodontic success. In this context, applying medicaments following effective irrigation activation procedures becomes an important point. The purpose of this study was to evaluate and compare the efficacy of various irrigation activation techniques on non-infected dentinal tubule penetration of calcium hydroxide (CH), double (DAP), and triple (TAP) antibiotic pastes. A total of 180 extracted human permanent mandibular premolar single-rooted teeth were selected and randomly divided into a control group and four main groups according to the irrigation activation procedures (n = 36) as KTP laser irradiation, conventional needle, NaviTip FX, sonic (SI) and ultrasonic activation (UI) procedures. Each group was randomly subdivided into three subgroups according to the medicament type (n = 12); CH, DAP, and TAP. After the activation procedures, the root canals were filled with CH, TAP, and DAP mixed with 0.1% fluorescent rhodamine B isothiocyanate. Specimens were sectioned at 2, 5, and 8 mm from the apex, and all the sections were examined under a confocal laser scanning microscope to calculate the dentinal tubule penetration. Data were analyzed using a three-way analysis of variance and Tukey's post hoc tests (P = 0.05). TAP provided a statistically significant greater penetration than the other groups (P < 0.05). UI provided a statistically significant higher dentinal tubules penetration area than other activation procedures (P < 0.05). Medicament penetration depends on the type of medicament, activation procedures, and root canal level. The TAP may be preferred following the ultrasonic activation in terms of long term root canal treatment success.

Platelet Activation via Glycoprotein VI Initiates Thrombin Generation: A Potential Role for Platelet-Derived Factor IX?

AbstractCollagen triggers coagulation via activation of factor (F) XII. In a platelet-rich environment, collagen can also trigger coagulation independently of FXII. We studied a novel mechanism of coagulation initiation via collagen-dependent platelet activation using thrombin generation (TG) in platelet-rich plasma. Collagen-induced coagulation is minimally affected by active-site inactivated FVIIa, anti-FVII antibodies, or FXIIa inhibition (corn trypsin inhibitor). Activation of platelets via specific glycoprotein (GP) VI agonists initiates TG, FX activation, and fibrin formation. To determine the platelet-derived trigger of coagulation, we systematically reconstituted factor-deficient plasmas with washed platelets. TG triggered by GPVI-activated platelets was significantly affected in FIX- and FVIII-deficient plasma but not in FVII- and FXII-deficient plasma. In a purified system composed of FX and FVIII, we observed that absence of FIX was compensated by GPVI-activated platelets, which could be inhibited by an anti-FIX antibody, suggesting FIXa activity from activated platelets. Furthermore, with the addition of FVIII in FIX-deficient plasma, TG induced by GPVI-activated platelets was restored, and was inhibited by the anti-FIX antibody. In conclusion, GPVI-activated platelets initiate TG, probably via platelet-derived FIXa activity.

Novel interaction of properdin and coagulation factor XI: Crosstalk between complement and coagulation

BackgroundEvidence of crosstalk between the complement and coagulation cascades exists, and dysregulation of either pathway can lead to serious thromboinflammatory events. Both the intrinsic pathway of coagulation and the alternative pathway of complement interact with anionic surfaces, such as glycosaminoglycans. Hitherto, there is no evidence for a direct interaction of properdin (factor P [FP]), the only known positive regulator of complement, with coagulation factor XI (FXI) or activated FXI (FXIa). ObjectivesThe aim was to investigate crosstalk between FP and the intrinsic pathway and the potential downstream consequences. MethodsChromogenic assays were established to characterize autoactivation of FXI in the presence of dextran sulfate (DXS), enzyme kinetics of FXIa, and the downstream effects of FP on intrinsic pathway activity. Substrate specificity changes were investigated using SDS‐PAGE and liquid chromatography–mass spectrometry (LC‐MS). Surface plasmon resonance (SPR) was used to determine direct binding between FP and FXIa. Results/ConclusionsWe identified a novel interaction of FP with FXIa resulting in functional consequences. FP reduces activity of autoactivated FXIa toward S‐2288. FXIa can cleave FP in the presence of DXS, demonstrated using SDS‐PAGE, and confirmed by LC‐MS. FXIa can cleave factor IX (FIX) and FP in the presence of DXS, determined by SDS‐PAGE. DXS alone modulates FXIa activity, and this effect is further modulated by FP. We demonstrate that FXI and FXIa bind to FP with high affinity. Furthermore, FX activation downstream of FXIa cleavage of FIX is modulated by FP. These findings suggest a novel intercommunication between complement and coagulation pathways.