Suppressing protein Z-dependent inhibition of factor Xa improves coagulation in hemophilia A.

Essentials Protein Z (PZ) catalyzes PZ-dependent proteinase inhibitor (ZPI) inactivation of factor (F)Xa. Gene-deletion of PZ or ZPI improves coagulation in hemophilia (FVIII knockout) mice. A PZ blocking antibody enhances thrombin generation in human hemophilia plasma. Suppression of the PZ/ZPI pathway may ameliorate the phenotype of severe hemophilia. SUMMARY: Background Hemostasis requires a balance between procoagulant and anticoagulant factors. Hemophiliacs bleed because of a procoagulant deficiency. Targeted reduction in the activity of endogenous anticoagulant pathways is currently being investigated as a means of improving hemostasis in hemophilia. Protein Z (PZ) is a cofactor that serves as a catalyst for PZ-dependent protease inhibitor (ZPI) inactivation of activated factor X at phospholipid surfaces. Objectives To evaluate the effects of PZ or ZPI gene deletion in hemophilic mice, and of blocking PZ in human hemophilic plasma. Methods A tail vein rebleeding assay (TVRB) was developed on the basis of the serial disruption of clots forming over a period of 15 min following tail vein laceration in an anesthetized mouse. Wild-type (WT)/FVIII knockout FVIIIKO, PZ knockout PZKO/FVIIIKO and ZPI knockout ZPIKO/FVIIIKO mice were evaluated in this model, and their plasmas were tested in thrombin generation assays. A mAb against PZ was evaluated in human hemophilic plasma thrombin generation assays. Results The numbers of clot disruptions (mean ± standard error of the mean) in the TVRB were: 4.0 ± 0.9 for WT/FVIIIKO mice; 23.8 ± 1.1 for WT/FVIIIKO mice supplemented with 100% FVIII; 15.2 ± 1.1 for PZKO/FVIIIKO mice; and 14.7 ± 1.2 for ZPIKO/FVIIIKO mice. Thrombin generation in PZKO/FVIIIKO and ZPIKO/FVIIIKO mouse plasmas was similar to that in FVIIIKO plasma supplemented with ~ 15% recombinant FVIII. A mAb against PZ added to human hemophilic plasma enhanced thrombin generation to an extent similar to the addition of ~ 15% FVIII. Conclusions Blockade of the PZ/ZPI system may be sufficient to ameliorate the phenotype of severe hemophilia.

Re-evaluation of mouse tissue factor pathway inhibitor and comparison of mouse and human tissue factor pathway inhibitor physiology.

Essentials Mouse models are often used to define roles of tissue factor pathway inhibitor (TFPI) in man. TFPI isoform-specific KOs reveal unexpected differences between mouse and human TFPI physiology. Mouse plasma contains 20 times more TFPI than man, derived from TFPIγ, a form not found in man. TFPIγ null mice, expressing only TFPI isoforms α and ß, may better reflect the human situation. SUMMARY: Background Mouse models can provide insight into the pathophysiology of human thrombosis and hemostasis. Tissue factor pathway inhibitor (TFPI) regulates coagulation through protein S (PS)-enhanced factor (F) Xa inhibition and FXa-dependent inhibition of FVIIa/tissue factor (TF) activity. TFPI is expressed as isoforms α and ß in man, and α, ß and γ in the mouse. Objective Assess the reliability of extending TFPI-related studies in mice to humans. Method Compare mouse and human TFPI physiology using a variety of methods. Results Mouse TFPI and human TFPI are similar in regard to: (i) the mechanisms for FVIIa/TF and FXa inhibition; (ii) TFPIα is a soluble form and TFPIß is glycosyl phosphatidyl inositol (GPI) membrane anchored; (iii) the predominant circulating form of TFPI in plasma is lipoprotein-associated; (iv) low levels of TFPIα circulate in plasma and increase following heparin treatment; and (v) TFPIα is the isoform in platelets. They differ in that: (i) mouse TFPI circulates at a ~20-fold higher concentration; (ii) mouse lines with isolated isoform deletions show this circulating mouse TFPI is derived from TFPIγ; (iii) sequences homologous to the mouse TFPIγ exon are present in many species, including man, but in primates are unfavorable for splicing; and (iv) tandem mass spectrometry (MS/MS) detects sequences for TFPI isoforms α and ß in human plasma and α and γ in mouse plasma. Conclusion To dissect the pathophysiological roles of human TFPIα and TFPIß, studies in TFPIγ null mice, expressing only α and ß, only α or only ß should better reflect the human situation.

Protein Z-dependent protease inhibitor and protein Z in peripheral arterial disease patients.

SUMMARY INTRODUCTION: Protein Z is a vitamin K-dependent protein that serves as a cofactor for the inhibition of activated factor X by the serpin protein Z-dependent protease inhibitor (ZPI). Protein Z plasma levels have been shown to be reduced in patients with peripheral arterial disease (PAD), but ZPI levels have not yet been reported. The aim of this study was to more fully assess the protein Z-ZPI system in individuals with atherosclerosis selected by the presence of symptomatic PAD. MATERIALS AND METHODS: Protein Z and ZPI levels were determined in 95 PAD patients (73 males; 22 females) [median age: 73 years (range, 50-86 years)] and in 190 controls comparable for age and gender. Protein Z was measured using a commercial immunoassay, and ZPI was measured with a homemade immunoassay and a functional assay. RESULTS: Protein Z antigen, ZPI antigen and ZPI function were found to be significantly lower in PAD patients with respect to controls [protein Z, median 72.5% (range: 3.4-123.7%) vs. 90.7% (range: 32.1-203.2%), P < 0.0001; ZPI antigen, 86.1% (range: 25.1-149.5%) vs. 93.2% (range: 48.9-171.3%), P = 0.004; ZPI function, 83.5% (range: 21.1-135.2%) vs. 97.2% (range: 50.5-175.5%), P < 0.0001]. The lowest tertiles of protein Z antigen [odds ratio (OR) 5.4, 95% confidence interval (CI) 2.2-13.5, P < 0.0001] and ZPI function (OR 2.4, 95% CI 1.1-5.5, P = 0.03) were associated with PAD on multivariate analysis after adjustment for age, gender, and traditional cardiovascular risk factors. A significant inverse relationship was also observed between protein Z and ZPI levels and the number of traditional cardiovascular risk factors and the clinical severity of disease (Fontaine stage). CONCLUSIONS: Low levels of protein Z antigen and protein Z activity are significantly associated with the occurrence and severity of atherosclerotic PAD.

Comparison of cell-surface TFPIalpha and beta.

BACKGROUND: Tissue factor pathway inhibitor (TFPI) is mainly produced by endothelial cells and alternative mRNA splicing generates two forms, TFPIalpha and TFPIbeta. A portion of expressed TFPI remains associated with the cell surface through both direct (TFPIbeta) and indirect (TFPIalpha) glycosylphosphatidyl-inositol (GPT)-mediated anchorage. OBJECTIVE: Compare the structure and properties of TFPIalpha and TFPIbeta. METHODS: TFPIalpha and TFPIbeta, with protein molecular masses of 36 and 28 kDa, respectively, migrate similarly (46 kDa) on SDS-PAGE. Experiments using specific glycosidases were carried out to determine the different glycosylation pattern of the two forms. ECV304 cells, a cell line with some endothelial properties, were stimulated with IL-lbeta, LPS, and TNFalpha for up to 24 hrs and mRNA levels and protein synthesis were determined. Stable clones of ECV304 cells that express reduced levels of TFPIalpha, TFPIbeta or both were produced using a plasmid-based small-interfering RNA technique. Surface TFPI activity was determined by a two-stage chromogenic assay based on the ability of each form to inhibit FXa activation by FVIIa on cells with comparable amount of tissue factor (TF). RESULTS AND CONCLUSIONS: The deglycosylation studies show that the difference in molecular masses is due to a greater degree of sialylation in O-linked carbohydrate in TFPIbeta. The mRNA and protein levels of neither form of TFPI were affected by stimulation of cells with inflammatory stimuli. Although TFPIalpha comprises 80% of the surface-TFPI, TFPIbeta was responsible for the bulk of the cellular FVIIa/TF inhibitory activity, suggesting a potential alternative role for cell surface TFPIalpha.

Heritability of plasma concentrations of clotting factors and measures of a prethrombotic state in a protein C-deficient family.

BACKGROUND: Earlier studies found strong support for a genetic basis for regulation of coagulation factor levels and measures of a prethrombotic state (d-dimer, prothrombin fragment 1.2). OBJECTIVES: Estimation of how much of the variation in the levels of coagulation factors and measures of a prethrombotic state, including measures of protein C activation and inactivation, could be attributed to heritability and household effect. PATIENTS AND METHODS: Blood samples were collected from 330 members of a large kindred of French-Canadian origin with type I protein C deficiency. Heritability and common household effect were estimated for plasma concentrations of prothrombin, factor (F)V, factor VIII, factor (F)IX, fibrinogen, von Willebrand factor (VWF), antithrombin, protein C, protein S, protein Z, protein Z-dependent protease inhibitor (ZPI), fibrinopeptide A (FPA), protein C activation peptide (PCP), activated protein C-protein C inhibitor complex (APC-PCI), activated protein C-alpha1-antitrypsin complex (APC-alpha1AT), prothrombin fragment 1.2 (F1.2) and d-dimer, using the variance component method in sequential oligo-genic linkage analysis routines (SOLAR). RESULTS: The highest heritability was found for measures of thrombin activity (PCP and FPA). High estimates were also found for prothrombin, FV, FIX, protein C, protein Z, ZPI, APC-PCI and APC-alpha1AT. An important influence of shared household effect on phenotypic variation was found for VWF, antithrombin, protein S and F1.2. CONCLUSIONS: We found strong evidence for the heritability of single coagulation factors and measures of a prethrombotic state. Hemostatic markers with statistically significant heritability constitute potential targets for the identification of novel genes involved in the control of quantitative trait loci.

The rediscovery and isolation of TFPI.

Tissue factor pathway inhibitor (TFPI) is a multivalent Kunitz-type proteinase inhibitor that produces factor (F)Xa-dependent feedback inhibition of the factor VIIa/tissue factor (FVIIa/TF) catalytic complex that is responsible for the initiation of coagulation. Since 1985, when Rapaport and colleagues reported that the lipoprotein fraction of plasma contained a FXa-dependent inhibitor of FVIIa/TF, myriad articles have established its biochemical structure, its mechanism of action, and its physiological importance. This brief personal account reviews historical studies that established the existence of the inhibitor and the events that led to its initial isolation.

Autoimmune antiphospholipid antibodies impair the inhibition of activated factor X by protein Z/protein Z-dependent protease inhibitor.

The hemostatic process is tightly regulated by several antithrombotic mechanisms. Among them, protein Z (PZ)-dependent protease inhibitor (ZPI) potently inhibits factor (F)Xa in a manner dependent on calcium ions, phospholipids and PZ. Autoimmune antiphospholipid antibodies (aPL) are mainly directed against phospholipid-binding plasma proteins such as beta2-glycoprotein I (beta2GPI) and prothrombin, and are known to interfere with phospholipid-dependent hemostatic pathways. In this study, we investigated whether purified aPL are able to interfere with inhibition of FXa by PZ/ZPI. beta2GPI modestly delayed the FXa inactivation by PZ/ZPI and most isolated aPL-IgGs were found to further increase the inhibitory potential of beta2GPI on PZ/ZPI activity. Without beta2GPI, the PZ/ZPI activity was unaffected by the addition of aPL-IgG. As PZ deficiency is hypothesized to lead to a prothrombotic state, we performed a case-control study to measure plasma levels of PZ and ZPI in 66 patients with autoimmune aPL and 152 normal controls. The prevalence of low PZ levels (below the 5th percentile of controls) was significantly greater in the 37 patients with definite antiphospholipid syndrome (APS) (24.3%) but not in the 29 aPL patients not fulfilling the criteria for APS (10.3%) compared with the normal group (4.6%, P < 0.001 vs. APS). ZPI antigen levels were similar in patients with aPL and normal controls. Concomitant PZ deficiency increased by approximately sevenfold the risk of arterial thrombosis in aPL patients. Taken together, these data suggest that the PZ/ZPI system is commonly impaired in aPL patients thus probably increasing the thrombotic risk.

High titers of autoantibodies to tissue factor pathway inhibitor are associated with the antiphospholipid syndrome.

As the activity of the tissue factor pathway inhibitor (TFPI) may be impaired in patients with antiphospholipid antibodies (aPL), 162 aPL patients were evaluated for autoantibodies to recombinant TFPI (anti-TFPI) using an optimized ELISA. Anti-TFPI (>18 U mL(-1) for IgG and/or > 15 U mL-1 for IgM) were detected in 54 patients with aPL (33.3%) and in three out of 79 normal controls (3.8%, P < 0.0001). Among aPL patients, the prevalence of positive anti-TFPI was 38.3 and 28.4% in those with or without diagnosis of definite antiphospholipid syndrome (APS). Patients with definite APS had a significantly greater frequency of high titer (>50 U mL(-1)) anti-TFPI than aPL patients from the no definite APS group (18.5% vs. 6.2%, OR 3.7, P= 0.017). Most aPL recognized full-length TFPI, but not a truncated form of TFPI lacking the C-terminus of the molecule. Isolated IgGs from subjects with anti-TFPI impaired the dose-dependent inhibitory effect of TFPI on factor Xa activity in the presence, but not in the absence of phospholipid vesicles. Thus, aPL with high titer anti-TFPI limit TFPI action and are associated with the APS.

Lipoprotein (a) binds and inactivates tissue factor pathway inhibitor: a novel link between lipoproteins and thrombosis.

Lipoprotein (a) [Lp(a)] has been associated with both anti-fibrinolytic and atherogenic effects. However, no direct link currently exists between this atherogenic lipoprotein and intravascular coagulation. The current study examined the binding and functional effects of Lp(a), its lipoprotein constituents, apoliprotein (a) [apo(a)] and low-density lipoprotein (LDL), and lysine-plasminogen (L-PLG), which shares significant homology with apo(a), on tissue factor pathway inhibitor (TFPI), a major regulator of tissue factor-mediated coagulation. Results indicate that Lp(a), apo(a), and PLG but not LDL bound recombinant TFPI (rTFPI) in vitro and that apo(a) bound to a region spanning the last 37 amino acid residues of the c-terminus of TFPI. The apparent binding affinity for TFPI was much higher for Lp(a) (KD approximately 150 nM) compared to PLG (KD approximately 800 nM) and nanomolar concentrations of apo(a) (500 nM) inhibited PLG binding to TFPI. Lp(a) also inhibited in a concentration-dependent manner rTFPI activity and endothelial cell surface TFPI activity in vitro, whereas PLG had no such effect. Moreover physiologic concentrations of PLG (2 microM) had no effect on the concentration-dependent inhibition of TFPI activity induced by Lp(a). In human atherosclerotic plaque, apo(a) and TFPI immunostaining were shown to coexist in smooth muscle cell-rich areas of the intima. These data suggest a novel mechanism whereby Lp(a) through its apo(a) moiety may promote thrombosis by binding and inactivating TFPI.

Protein Z-dependent regulation of coagulation.

Protein Z (PZ) is a 62 kDa vitamin K-dependent plasma protein that serves as a cofactor for the inhibition of factor Xa by protein Z-dependent protease inhibitor (ZPI). ZPI is a recently identified 72 kDa member of the serpin superfamily of proteinase inhibitors that contains a tyrosine at its reactive center. PZ circulates in plasma in a complex with ZPI. Inhibition of factor Xa by ZPI in the presence of phospholipids and Ca++ is enhanced 1000-fold by PZ, but ZPI also inhibits factor XIa in a process that does not require PZ, phospholipids or Ca++. ZPI activity is consumed during coagulation through proteolysis mediated by factor Xa with PZ and factor Xla. Concomitant PZ deficiency dramatically increases the severity of the prothrombotic phenotype of factor VLeiden mice. Studies to determine the potential roles of PZ and ZPI deficiency in human thrombosis are in progress.

Deficiency of tissue factor pathway inhibitor promotes atherosclerosis and thrombosis in mice.

BACKGROUND: Tissue factor initiates blood coagulation after atherosclerotic plaque disruption. Tissue factor pathway inhibitor (TFPI) inhibits tissue factor activity and may reduce thrombus formation in this setting. We evaluated the effect of heterozygous TFPI deficiency on the development of atherosclerosis and thrombosis in atherosclerosis-prone mice. METHODS AND RESULTS: Mice with a combined heterozygous TFPI deficiency and homozygous apolipoprotein E deficiency (TFPI(+/-)/apoE(-/-)) were generated by crossbreeding, and they were analyzed for atherosclerosis throughout the vascular tree. Compared with mice with a normal TFPI genotype (TFPI(+/+)/apoE(-/-)), mice with a TFPI deficiency exhibited a greater atherosclerotic burden involving the carotid and common iliac arteries. Staining for active tissue factor within the plaque revealed more activity in TFPI(+/-)/apoE(-/-) mice compared with TFPI(+/+)/apoE(-/-) mice. Consistent with increased plaque tissue factor activity, the time to occlusive thrombosis after photochemical carotid plaque injury was significantly decreased in TFPI(+/-)/apoE(-/-) mice. CONCLUSIONS: These observations indicate that TFPI protects from atherosclerosis and is an important regulator of the thrombosis that occurs in the setting of atherosclerosis.

Protein Z circulates in plasma in a complex with protein Z-dependent protease inhibitor.

Protein Z (PZ) is a vitamin K-dependent plasma protein that forms a Ca++-dependent complex with factor Xa at phospholipid surfaces. This interaction between PZ and factor Xa enhances by >1,000-fold the inhibition of factor Xa by the serpin called protein Z-dependent protease inhibitor (ZPI). These experiments show that PZ also binds ZPI in a process that does not require Ca++ or phospholipids. In pooled normal plasma, which contains excess ZPI relative to PZ, all the PZ appears to be bound in a complex with ZPI. The binding of PZ to ZPI reduces the rate and extent of factor XIa inhibition produced by ZPI. During the course of these studies, it was noted that a PZ purification procedure, that included NaSCN (2.0 M) elution of PZ from an immunoaffinity column, produced aggregated, inactive forms of PZ.