Inhibition of tissue factor-factor VIIa-catalyzed factor X activation by factor Xa-tissue factor pathway inhibitor. A rotating disc study on the effect of phospholipid membrane composition.

The physiological inhibitor of tissue factor (TF).factor VIIa (FVIIa), full-length tissue factor pathway inhibitor (TFPI(FL)) in complex with factor Xa (FXa), has a high affinity for anionic phospholipid membranes. The role of anionic phospholipids in the inhibition of TF.FVIIa-catalyzed FX activation was investigated. FXa generation at a rotating disc coated with TF embedded in a membrane composed of pure phosphatidylcholine (TF.PC) or 25% phosphatidylserine and 75% phosphatidylcholine (TF.PSPC) was measured in the presence of preformed complexes of FXa.TFPI(FL) or FXa.TFPI(1-161) (TFPI lacking the third Kunitz domain and C terminus). At TF.PC, FXa.TFPI(FL) and FXa.TFPI(1-161) showed similar rate constants of inhibition (0.07 x 10(8) M(-1) s(-1) and 0.1 x 10(8) M(-1) s(-1), respectively). With phosphatidylserine present, the rate constant of inhibition for FXa.TFPI(FL) increased 3-fold compared with a 9-fold increase in the rate constant for FXa. TFPI(1-161). Incubation of TF.PSPC with FXa.TFPI(FL) in the absence of FVIIa followed by depletion of solution FXa.TFPI(FL) showed that FXa.TFPI(FL) remained bound at the membrane and pursued its inhibitory activity. This was not observed with FXa.TFPI(1-161) or at TF.PC membranes. These data suggest that the membrane-bound pool of FXa.TFPI(FL) may be of physiological importance in an on-site regulation of TF.FVIIa activity.     

Probing the interface between factor Xa and tissue factor in the quaternary complex tissue factor-factor VIIa-factor Xa-tissue factor pathway inhibitor.

Blood coagulation is triggered by the formation of a complex between factor VIIa (FVIIa) and its cofactor, tissue factor (TF). TF-FVIIa is inhibited by tissue factor pathway inhibitor (TFPI) in two steps: first TFPI is bound to the active site of factor Xa (FXa), and subsequently FXa-TFPI exerts feedback inhibition of TF-FVIIa. The FXa-dependent inhibition of TF-FVIIa activity by TFPI leads to formation of the quaternary complex TF-FVIIa-FXa-TFPI. We used site-directed fluorescence probing to map part of the region of soluble TF (sTF) that interacts with FXa in sTF-FVIIa-FXa-TFPI. We found that the C-terminal region of sTF, including positions 163, 166, 200 and 201, is involved in binding to FXa in the complex, and FXa, most likely via its Gla domain, is also in contact with the Gla domain of FVIIa in this part of the binding region. Furthermore, a region that includes the N-terminal part of the TF2 domain and the C-terminal part of the TF1 domain, i.e. the residues 104 and 197, participates in the interaction with FXa in the quaternary complex. Moreover, comparisons of the interaction areas between sTF and FX(a) in the quaternary complex sTF-FVIIa-FXa-TFPI and in the ternary complexes sTF-FVII-FXa or sTF-FVIIa-FX demonstrated large similarities.     

Contribution of regions distal to glycine-160 to the anticoagulant activity of tissue factor pathway inhibitor

The functions of the first two Kunitz domains of tissue factor pathway inhibitor (TFPI) are well defined as active site-directed inhibitors of factor VIIa and factor Xa. The anticoagulant properties of the third Kunitz domain and C-terminal region were probed using altered forms of TFPI. TFPI-160 contains the first two Kunitz domains. K1K2C contains the first two Kunitz domains and the basic C-terminus. Neither TFPI-160 nor K1K2C contains the third Kunitz domain. In amidolytic assays containing calcium, TFPI-160 is a less potent inhibitor of factor Xa than TFPI. However, addition of the C-terminus in K1K2C nearly restores inhibitory activity to that of TFPI, indicating that the third Kunitz domain is not required for direct inhibition of factor Xa. When compared in assays containing phospholipids and factor Va, K1K2C and TFPI-160 are poor inhibitors compared to TFPI, demonstrating that the third Kunitz domain is required for the full anticoagulant activity of TFPI. TFPI was further characterized in amidolytic assays performed with Gla-domainless factor Xa and in prothrombin activation assays using submicellar concentrations of short-chain phospholipids (C6PS). TFPI and K1K2C are worse inhibitors of Gla-domainless factor Xa, compared to wild-type factor Xa, while TFPI-160 inhibits both forms of factor Xa equally, suggesting a C-terminus/Gla domain interaction. TFPI is a potent inhibitor of thrombin generation by prothrombinase assembled with C6PS, while TFPI-160 and K1K2C are not. Conversely, TFPI does not inhibit prothrombin activation by prothrombinase assembled on a two-dimensional lipid bilayer. Together, the data indicate that the region between Gly-160 and the end of the third Kunitz domain contributes to TFPI function by orienting the second Kunitz domain so that it can bind the active site of phospholipid-associated factor Xa prior to prothrombinase assembly and/or by slowing formation of the prothrombinase complex.     

Role of the Gla and first epidermal growth factor-like domains of factor X in the prothrombinase and tissue factor-factor VIIa complexes

Factor X (FX) has high structure homology with other proteins of blood coagulation such as factor IX (FIX) and factor VII (FVII). These proteins present at their amino-terminal extremity a gamma-carboxyglutamic acid containing domain (Gla domain), followed by two epidermal growth factor-like (EGF1 and EGF2) domains, an activation peptide, and a serine protease domain. After vascular damage, the tissue factor-FVIIa (TF-FVIIa) complex activates both FX and FIX. FXa interacts stoichiometrically with tissue pathway inhibitor (TFPI), regulating TF-FVIIa activity by forming the TF-FVIIa-TFPI-FXa quaternary complex. Conversely, FXa boosts coagulation by its association with its cofactor, factor Va (FVa). To investigate the contribution of the Gla and EGF1 domains of FX in these complexes, FX chimeras were produced in which FIX Gla and EGF1 domains substituted the corresponding domains of FX. The affinity of the two chimeras, FX/FIX(Gla) and FX/FIX(EGF1), for the TF-FVIIa complex was markedly reduced compared with that of wild-type-FX (wt-FX) independently of the presence of phospholipids. Furthermore, the association rate constants of preformed FX/FIX(Gla)-TFPI and FX/FIX(EGF1)-TFPI complexes with TF-FVIIa were, respectively, 10- and 5-fold slower than that of wt-FXa-TFPI complex. Finally, the apparent affinity of FVa was 2-fold higher for the chimeras than for wt-FX in the presence of phospholipids and equal in their absence. These data demonstrate that FX Gla and EGF1 domains contain residues, which interact with TF-FVIIa exosites contributing to the formation of the TF-FVIIa-FX and TF-FVIIa-TFPI-FXa complexes. On the opposite, FXa Gla and EGF1 domains are not directly involved in FVa binding.     

Structural mechanism for heparin-binding of the third Kunitz domain of human tissue factor pathway inhibitor.

Tissue factor pathway inhibitor (TFPI) inhibits the activity of coagulation factor VIIa and Xa through its K1 and K2 domain, respectively, and the inhibitory activity is enhanced by heparin. The function of the K3 domain of TFPI has not been established, but the domain probably harbors a heparin binding site (HBS-2). We determined the three-dimensional solution structure of the TFPI K3 domain (Glu182-Gly242) by heteronuclear multidimensional NMR. The results showed that the molecule is composed of one antiparallel beta-sheet and one alpha-helix, and in overall structure is very similar to the K2 domain, with the rms deviation of 1.55 A for the 58 defined C(alpha) positions. However, the surface electrostatic properties of both domains are different each other. The lack of inhibitory activity of the K3 domain is explained by the absence of electrostatic interaction with factor Xa over a large surface area. A titration experiment with size-fractionated heparin showed that a heparin binding site was located in the vicinity of the alpha-helix. In this region, a positively charged cluster is formed by Lys213, Lys232, and Lys240, and the negatively charged sulfate groups of heparin bind there. The enhancement of inhibitory activity by heparin probably was not due to a conformational change to TFPI itself. It is likely that heparin simply increases the local concentration of TFPI on the cell surface and stabilizes the initial complex that forms.     

Ixolaris binding to factor X reveals a precursor state of factor Xa heparin-binding exosite

Ixolaris is a two-Kunitz tick salivary gland tissue factor pathway inhibitor (TFPI). In contrast to human TFPI, Ixolaris specifically binds to factor Xa (FXa) heparin-binding exosite (HBE). In addition, Ixolaris interacts with zymogen FX. In the present work we characterized the interaction of Ixolaris with human FX quantitatively, and identified a precursor state of the heparin-binding exosite (proexosite, HBPE) as the Ixolaris-binding site on the zymogen. Gel-filtration chromatography demonstrated 1:1 complex formation between fluorescein-labeled Ixolaris and FX. Isothermal titration calorimetry confirmed that the binding of Ixolaris to FX occurs at stoichiometric concentrations in a reaction which is characteristically exothermic, with a favorable enthalpy (DeltaH) of -10.78 kcal/mol. ELISA and plasmon resonance experiments also indicate that Ixolaris binds to plasma FX and FXa, or to recombinant Gla domain-containing FX/FXa with comparable affinities ( approximately 1 nM). Using a series of mutants on the HBPE, we identified the most important amino acids involved in zymogen/Ixolaris interaction-Arg-93 > Arg-165 > or = Lys-169 > Lys-236 > Arg-125-which was identical to that observed for FXa/Ixolaris interaction. Remarkably, Ixolaris strongly inhibited FX activation by factor IXa in the presence but not in the absence of factor VIIIa, suggesting a specific interference in the cofactor activity. Further, solid phase assays demonstrated that Ixolaris inhibits FX interaction with immobilized FVIIIa. Altogether, Ixolaris is the first inhibitor characterized to date that specifically binds to FX HBPE. Ixolaris may be a useful tool to study the physiological role of the FX HBPE and to evaluate this domain as a target for anticoagulant drugs.     

重组TFPI缺失突变体TFPI1-161在毕赤酵母中的高效表达及功能鉴定

人组织因子途径抑制物(TFPI)是一种体内天然存在的外源性凝血途径特异性抑制物。缺失突变体TFPI1-161包括TFPI的N末端、K1和K2结构域,是一种研究TFPi结构与功能及其相互关系的理想对照分子。以克隆质粒pGEM-3Zf(-)-TFPi为模板,用PCR方法获得TFPI1-161基因,构建表达质粒pPIC9K-TFPi1-161并转化毕赤酵母GS115。通过筛选多拷贝转化子及优化发酵培养条件,首次在毕赤酵母中高效表达了TFPI1-161经纯化后最终产量高于酿酒酵母20倍以上。由于糖基化程度不同,TFPI1-161表达为TFPI1-161(24kD)和TFPI1-161(27kD)两种分子形式,其等电点分别为4、8和4．9。根据等电点差异,二可通过阴离子交换层析得到分离,其活性无显性差异。经分子筛和阴离子交换层析分离纯化后,从4L发酵培养液中可分别获得1.4g TFPI1-161(24kD)和1.8gTFPI1-161(27kD),其比活性分别达12880u／mg和12400u／mg,回收率达55％。经稀释的凝血酶原时间及发色底物法检测,重组TFPI1-161具有良好的抗凝及抑制FXa活性的作用。为获得大量TFPI1-161提供了一种廉价高效的蛋白表达纯化方式,为进一步的基础及临床前研究奠定了基础。     

氨基酸序列突变对TFPI生物半衰期和生物活性的影响

通过对个别氨基酸突变的研究,获得了保持良好生物活性的长半衰期组织因子途径抑制因子(tissue factor pathwayinhibitor,TFPI)重组蛋白的有效途径.采用定点诱变和基因重组技术,首先在TFPI cDNA特定位点形成一个位点的沉默突变,以提高TFPI在毕赤酵母细胞内的表达量,此cDNA称为mTFPI.在此基础上,通过系列位点突变,形成3个羧基端突变体:m0TFPI、m1TFPI和m2TFPI.将上述4种TFPI cDNA与表达质粒pPic9连接,转染大肠杆菌,通过PCR和DNA测序确认重组质粒,转染酵母细胞GS115,甲醇诱导表达重组蛋白.采用层析方法纯化TFPI重组蛋白,用125I标记重组蛋白,静脉注射给药,比较四者在SD大鼠体内血浆代谢清除速度.用底物显色法测定重组蛋白抑制凝血因子Xa(Fxa)的活性,比较各株TFPI重组蛋白突变体在体内、体外对FXa的抑制作用及肝素对各株TFPI重组蛋白功能的影响.结果显示,相比野生型TFPI重组蛋(mTFPI)而言,3株羧基端突变体m0TFPI、m1TFPI、m2TFPI在SD大鼠体内血浆代谢清除时间均有不同程度延长,其生物代谢半衰期分别是mTFPI的1.5倍、1.9倍和大于2倍,与m-TFPI相比,3个rTFPI突变体在体内、体外抑制FXa的作用无明显减弱,与肝素的结合能力及协同能力也无明显减弱.结果表明,m0TFPI、m1TFPI和m2TFPI在生物半衰期得到明显延长的同时,仍保持良好的抑制Fxa的生物活性.     

Syndecan-3 and TFPI Colocalize on the Surface of Endothelial-, Smooth Muscle-, and Cancer Cells

Background

Tissue factor (TF) pathway inhibitor (TFPI) exists in two isoforms; TFPIα and TFPIβ. Both isoforms are cell surface attached mainly through glycosylphosphatidylinositol (GPI) anchors. TFPIα has also been proposed to bind other surface molecules, like glycosaminoglycans (GAGs). Cell surface TFPIβ has been shown to exert higher anticoagulant activity than TFPIα, suggesting alternative functions for TFPIα. Further characterization and search for novel TFPI binding partners is crucial to completely understand the biological functions of cell associated TFPI.

Methods and Results

Potential association of TFPI to heparan sulphate (HS) proteoglycans in the syndecan family were evaluated by knock down studies and flow cytometry analysis. Cell surface colocalization was assessed by confocal microscopy, and native PAGE or immunoprecipitation followed by Western blotting was used to test for protein interaction. Heparanase was used to enzymatically degrade cell surface HS GAGs. Anticoagulant potential was evaluated using a factor Xa (FXa) activity assay. Knock down of syndecan-3 in endothelial,- smooth muscle- and breast cancer cells reduced the TFPI surface levels by 20-50%, and an association of TFPIα to syndecan-3 on the cell surface was demonstrated. Western blotting indicated that TFPIα was found in complex with syndecan-3. The TFPI bound to syndecan-3 did not inhibit the FXa generation. Removal of HS GAGs did not release TFPI antigen from the cells.

Conclusions

We demonstrated an association between TFPIα and syndecan-3 in vascular cells and in cancer cells, which did not appear to depend on HS GAGs. No anticoagulant activity was detected for the TFPI associated with syndecan-3, which may indicate coagulation independent functions for this cell associated TFPI pool. This will, however, require further investigation.     

Thermodynamic linkage between the S1 site, the Na+ site, and the Ca2+ site in the protease domain of human coagulation factor xa. Studies on catalytic efficiency and inhibitor binding

The serine protease domain of factor Xa (FXa) contains a sodium as well as a calcium-binding site. Here, we investigated the functional significance of these two cation-binding sites and their thermodynamic links to the S1 site. Kinetic data reveal that Na(+) binds to the substrate bound FXa with K(d) approximately 39 mm in the absence and approximately 9.5 mm in the presence of Ca(2+). Sodium-bound FXa (sodium-Xa) has approximately 18-fold increased catalytic efficiency ( approximately 4.5-fold decrease in K(m) and approximately 4-fold increase in k(cat)) in hydrolyzing S-2222 (benzoyl-Ile-Glu-Gly-Arg-p-nitroanilide), and Ca(2+) further increases this k(cat) approximately 1.4-fold. Ca(2+) binds to the protease domain of substrate bound FXa with K(d) approximately 705 microm in the absence and approximately 175 microm in the presence of Na(+). Ca(2+) binding to the protease domain of FXa (Xa-calcium) has no effect on the K(m) but increases the k(cat) approximately 4-fold in hydrolyzing S-2222, and Na(+) further increases this k(cat) approximately 1.4-fold. In agreement with the K(m) data, sodium-Xa has approximately 5-fold increased affinity in its interaction with p-aminobenzamidine (S1 site probe) and approximately 4-fold increased rate in binding to the two-domain tissue factor pathway inhibitor; Ca(2+) (+/-Na(+)) has no effect on these interactions. Antithrombin binds to Xa-calcium with a approximately 4-fold faster rate, to sodium-Xa with a approximately 24-fold faster rate and to sodium-Xa-calcium with a approximately 28-fold faster rate. Thus, Ca(2+) and Na(+) together increase the catalytic efficiency of FXa approximately 28-fold. Na(+) enhances Ca(2+) binding, and Ca(2+) enhances Na(+) binding. Further, Na(+) enhances S1 site occupancy, and S1 site occupancy enhances Na(+) binding. Therefore, Na(+) site is thermodynamically linked to the S1 site as well as to the protease domain Ca(2+) site, whereas Ca(2+) site is only linked to the Na(+) site. The significance of these findings is that during physiologic coagulation, most of the FXa formed will exist as sodium-Xa-calcium, which has maximum biologic activity.     

Role of factor VIII C2 domain in factor VIII binding to factor Xa.

Factor VIII (FVIII) is activated by proteolytic cleavages with thrombin and factor Xa (FXa) in the intrinsic blood coagulation pathway. The anti-C2 monoclonal antibody ESH8, which recognizes residues 2248-2285 and does not inhibit FVIII binding to von Willebrand factor or phospholipid, inhibited FVIII activation by FXa in a clotting assay. Furthermore, analysis by SDS-polyacrylamide gel electrophoresis showed that ESH8 inhibited FXa cleavage in the presence or absence of phospholipid. The light chain (LCh) fragments (both 80 and 72 kDa) and the recombinant C2 domain dose-dependently bound to immobilized anhydro-FXa, a catalytically inactive derivative of FXa in which dehydroalanine replaces the active-site serine. The affinity (K(d)) values for the 80- and 72-kDa LCh fragments and the C2 domain were 55, 51, and 560 nM, respectively. The heavy chain of FVIII did not bind to anhydro-FXa. Similarly, competitive assays using overlapping synthetic peptides corresponding to ESH8 epitopes (residues 2248-2285) demonstrated that a peptide designated EP-2 (residues 2253-2270; TSMYVKEFLISSSQDGHQ) inhibited the binding of the C2 domain or the 72-kDa LCh to anhydro-FXa by more than 95 and 84%, respectively. Our results provide the first evidence for a direct role of the C2 domain in the association between FVIII and FXa.     

Inhibition of platelet-surface-bound proteins during coagulation under flow I: TFPI

Blood coagulation is a self-repair process regulated by activated platelet surfaces, clotting factors, and inhibitors. Tissue factor pathway inhibitor (TFPI) is one such inhibitor, well known for its inhibitory action on the active enzyme complex comprising tissue factor (TF) and activated clotting factor VII. This complex forms when TF embedded in the blood vessel wall is exposed by injury and initiates coagulation. A different role for TFPI, independent of TF:VIIa, has recently been discovered whereby TFPI binds a partially cleaved form of clotting factor V (FV-h) and impedes thrombin generation on activated platelet surfaces. We hypothesized that this TF-independent inhibitory mechanism on platelet surfaces would be a more effective platform for TFPI than the TF-dependent one. We examined the effects of this mechanism on thrombin generation by including the relevant biochemical reactions into our previously validated mathematical model. Additionally, we included the ability of TFPI to bind directly to and inhibit platelet-bound FXa. The new model was sensitive to TFPI levels and, under some conditions, TFPI could completely shut down thrombin generation. This sensitivity was due entirely to the surface-mediated inhibitory reactions. The addition of the new TFPI reactions increased the threshold level of TF needed to elicit a strong thrombin response under flow, but the concentration of thrombin achieved, if there was a response, was unchanged. Interestingly, we found that direct binding of TFPI to platelet-bound FXa had a greater anticoagulant effect than did TFPI binding to FV-h alone, but that the greatest effects occurred if both reactions were at play. The model includes activated platelets’ release of FV species, and we explored the impact of varying the FV/FV-h composition of the releasate. We found that reducing the zymogen FV fraction of this pool, and thus increasing the fraction that is FV-h, led to acceleration of thrombin generation.     

Functional and Structural Characterization of Factor Xa Dimer in Solution

Previous studies showed that binding of water-soluble phosphatidylserine (C6PS) to bovine factor Xa (FXa) leads to Ca²⁺-dependent dimerization in solution. We report the effects of Ca²⁺, C6PS, and dimerization on the activity and structure of human and bovine FXa. Both human and bovine dimers are 10⁶- to 10⁷-fold less active toward prothrombin than the monomer, with the decrease being attributed mainly to a substantial decrease in k_cat. Dimerization appears not to block the active site, since amidolytic activity toward a synthetic substrate is largely unaffected. Circular dichroism reveals a substantial change in tertiary or quaternary structure with a concomitant decrease in α-helix upon dimerization. Mass spectrometry identifies a lysine (K²⁷⁰) in the catalytic domain that appears to be buried at the dimer interface and is part of a synthetic peptide sequence reported to interfere with factor Va (FVa) binding. C6PS binding exposes K³⁵¹ (part of a reported FVa binding region), K²⁴² (adjacent to the catalytic triad), and K⁴²⁰ (part of a substrate exosite). We interpret our results to mean that C6PS-induced dimerization produces substantial conformational changes or domain rearrangements such that structural data on PS-activated FXa is required to understand the structure of the FXa dimer or the FXa-FVa complex.     

Tissue factor pathway inhibitor binds to platelet thrombospondin-1

Tissue factor pathway inhibitor (TFPI) is a Kunitz-type serine proteinase inhibitor that down-regulates tissue factor-initiated blood coagulation. The most biologically active pool of TFPI is associated with the vascular endothelium, however, the biochemical mechanisms responsible for its cellular binding are not entirely defined. Proposed cellular binding sites for TFPI include nonspecific association with cell surface glycosaminoglycans and binding to glycosyl phosphatidylinositol-anchored proteins. Here, we report that TFPI binds specifically and saturably to thrombospondin-1 (TSP-1) purified from platelet alpha-granules with an apparent K(D) of approximately 7.5 nm. Binding is inhibited by polyclonal antibodies against TFPI and partially inhibited by the B-7 monoclonal anti-TSP-1 antibody. TFPI bound to immobilized TSP-1 remains an active proteinase inhibitor. Additionally, in solution phase assays measuring TFPI inhibition of factor VIIa/tissue factor catalytic activity, the rate of factor Xa generation was decreased 55% in the presence of TSP-1 compared with TFPI alone. Binding experiments done in the presence of heparin and with altered forms of TFPI suggest that the basic C-terminal region of TFPI is required for TSP-1 binding. The data provide a mechanism for the recruitment and localization of TFPI to extravascular surfaces within a bleeding wound, where it can efficiently down-regulate the procoagulant activity of tissue factor and allow subsequent aspects of platelet-mediated healing to proceed.     

Inhibitors of factor VIIa affect the interface between the protease domain and tissue factor

Blood coagulation is triggered by the formation of a complex between factor VIIa (FVIIa) and its cofactor, tissue factor (TF). The gamma-carboxyglutamic acid-rich domain of FVIIa docks with the C-terminal domain of TF, the EGF1 domain of FVIIa contacts both domains of TF, and the EGF2 domain and protease domain (PD) form a continuous surface that sits on the N-terminal domain of TF. Our aim was to investigate the conformational changes that occur in the sTF.PD binding region when different types of inhibitors, i.e., one active-site inhibitor (FFR-chloromethyl ketone (FFR)), two different peptide exosite inhibitors (E-76 and A-183), and the natural inhibitor tissue factor pathway inhibitor (TFPI), were allowed to bind to FVIIa. For this purpose, we constructed two sTF mutants (Q37C and E91C). By the aid of site-directed labeling technique, a fluorescent label was attached to the free cysteine. The sTF.PD interface was affected in position 37 by the binding of FFR, TFPI, and E-76, i.e., a more compact structure was sensed by the probe, while for position 91 located in the same region no change in the surrounding structure was observed. Thus, the active site inhibitors FFR and TFPI, and the exosite inhibitor E-76 have similar effects on the probe in position 37 of sTF, despite their differences in size and inhibition mechanism. The allosteric changes at the active site caused by binding of the exosite inhibitor E-76 in turn induce similar conformational changes in the sTF.PD interface as does the binding of the active site inhibitors. A-183, on the other hand, did not affect position 37 in sTF, indicating that the A-183 inhibition mechanism is different from that of E-76.     

Catabolism of factor VIIa bound to tissue factor in fibroblasts in the presence and absence of tissue factor pathway inhibitor

Vascular injury leads to the exposure of blood to fibroblasts and smooth muscle cells within the vessel wall. These cells constitutively express tissue factor (TF), the cellular receptor for plasma clotting factor VIIa (FVIIa). Formation of TF.FVIIa complexes on cell surfaces triggers the blood coagulation cascade. In the present study, we have investigated the fate of TF.FVIIa complexes formed on the cell surface of fibroblasts in the presence and absence of plasma inhibitor, tissue factor pathway inhibitor (TFPI). FVIIa bound to TF on the cell surface was internalized and degraded without depleting the cell surface TF antigen and activity. TFPI significantly enhanced the TF-specific internalization and degradation of FVIIa. TFPI-enhanced internalization and degradation of FVIIa requires the C-terminal domain of TFPI and factor Xa. TFPI. Xa-mediated internalization of FVIIa was associated with the depletion of TF from the cell surface. A majority of the internalized FVIIa was degraded, but a small portion of the internalized FVIIa recycles back to the cell surface as an intact protein. In addition to TF, other cell surface components, such as low density lipoprotein receptor-related protein (LRP) and heparan sulfates, are essential for TFPI.Xa-induced internalization of FVIIa. Acidification of cytosol, which selectively inhibits the endocytotic pathway via coated pits, inhibited TFPI.Xa-mediated internalization but not the basal internalization of FVIIa. Overall, our data support the concept that FVIIa bound to cell surface TF was endocytosed by two different pathways. FVIIa complexed with TF in the absence of the inhibitor was internalized via a LRP-independent and probably noncoated pit pathway, whereas FVIIa complexed with TF along with the inhibitor was internalized via LRP-dependent coated pit pathway.     

A computational modeling and molecular dynamics study of the Michaelis complex of human protein Z-dependent protease inhibitor (ZPI) and factor Xa (FXa)

Protein Z-dependent protease inhibitor (ZPI) and antithrombin III (AT3) are members of the serpin superfamily of protease inhibitors that inhibit factor Xa (FXa) and other proteases in the coagulation pathway. While experimental structural information is available for the interaction of AT3 with FXa, at present there is no structural data regarding the interaction of ZPI with FXa, and the precise role of this interaction in the blood coagulation pathway is poorly understood. In an effort to gain a structural understanding of this system, we have built a solvent equilibrated three-dimensional structural model of the Michaelis complex of human ZPI/FXa using homology modeling, protein–protein docking and molecular dynamics simulation methods. Preliminary analysis of interactions at the complex interface from our simulations suggests that the interactions of the reactive center loop (RCL) and the exosite surface of ZPI with FXa are similar to those observed from X-ray crystal structure-based simulations of AT3/FXa. However, detailed comparison of our modeled structure of ZPI/FXa with that of AT3/FXa points to differences in interaction specificity at the reactive center and in the stability of the inhibitory complex, due to the presence of a tyrosine residue at the P1 position in ZPI, instead of the P1 arginine residue in AT3. The modeled structure also shows specific structural differences between AT3 and ZPI in the heparin-binding and flexible N-terminal tail regions. Our structural model of ZPI/FXa is also compatible with available experimental information regarding the importance for the inhibitory action of certain basic residues in FXa. Figure Solvent equilibrated models for protein z-dependent protease inhibitor and its initial reactive complex with coagulation factor Xa (show here) are developed. Electronic supplementary material  The online version of this article (doi:) contains supplementary material, which is available to authorized users. V.C. and C.J.L. contributed equally to this work. The solvent-equilibrated PDB structure of the ZPI/FXa will be made available upon request. Conflict of interest statement  The authors state that they have no conflict of interest.     

Tissue factor pathway inhibitor induces expression of JUNB and GADD45B mRNAs

Tissue factor pathway inhibitor (TFPI) is a Kunitz-type protease inhibitor that regulates tissue factor-triggered blood coagulation. It has previously been reported that TFPI inhibits the proliferation of human umbilical vein endothelial cells (HUVECs), suggesting that TFPI may act as more than just a mediator of coagulation through changes in gene expression. By using DNA-array techniques and Northern blot analysis, we here revealed that TFPI transiently induced the mRNA expression of JUNB and GADD45B. The inducible effects were not observed in TFPIdeltaC (lacking the C-terminal basic region) or antithrombin (heparin-binding anticoagulant protease inhibitor). Moreover, the TFPI-induced expression of GADD45B was blocked by receptor-associated protein, which masks the ligand-binding domain of very low density lipoprotein receptor (VLDL-R). In conclusion, this is the first report to show an effect of TFPI on mRNA expression, and suggests that TFPI modulates cellular functions by inducing JUNB and GADD45B expression through binding to VLDL-R.     

Factor Xa (FXa) inhibitor from the nymphs of the camel tick Hyalomma dromedarii

An inhibitor of factor Xa (FXa) was isolated from the nymphs of the camel tick Hyalomma dromedarii by a combination of chromatography on DEAE-cellulose and Sephacryl S-300 columns. The isolated nymphal FXa inhibitor turned out to be a homogenous preparation of a single polypeptide chain (15 kDa) as judged by both the native and denatured SDS-PAGE. Its pI value ranged from 7.7 to 7.9. The inhibitor is a potent anticoagulant since it prolonged both the activated partial thromboplastin time (APTT) and the prothrombin time (PT) of the camel plasma in a concentration-dependent manner. Its activity was threefold lower toward thrombin than FXa, but it did not inhibit any of the proteases; trypsin, α-chymotrypsin, papain, pepsin and subtilisin. The inhibitor binds at two sites on FXa uncompetitively with an inhibition constant (K_i) value of 134 nM.