Localization of tissue factor in actin-filament-rich membrane areas of epithelial cells

Tissue factor (TF), the cellular receptor and cofactor for clotting factor VII/VIIa (FVII/VIIa), is known mainly as the initiator of the coagulation protease cascade. Recently, it was shown that inactivation of the murine TF gene (TF-/-) results in embryonic lethality which is most likely due to some failure of vascular integrity. On the other hand, gene disruption in mice of coagulation proteins like FVII, prothrombin, and fibrinogen results in phenotypes of embryonic development that contrast with that of TF-/-, suggesting a role for TF beyond fibrin formation in embryogenesis. In addition, there is a growing body of evidence that cellular TF may be involved in nonhemostatic functions. To determine the microtopography of membrane TF with regard to the cytoskeleton organization, we examined the expression patterns of TF and cytoskeletal proteins in various cell lines by means of double immunofluorescence and electron microscopy (EM). In spreading cells, a granular membrane TF expression of the cell cortex and a pronounced granular TF staining of microspikes, lamellipodes, and ruffled membrane areas were observed. Especially, actin and alpha-actinin were in close proximity to TF in these regions. Colocalization of TF and nonmuscle filamin (ABP-280) at the leading edge of spreading cells indicated an association of TF with the actin filament system, too. Using scanning EM we found gold-labeled TF at long processes and actin-filament-containing microspikes of neighboring cells in both branching and contact sites. By the means of immunogold EM we observed that TF is localized at the cell surface in a spotty pattern, at the base and at the top of budding processes. The observed staining pattern points to a connection of TF with elements of the cytoskeleton in these highly dynamic membrane regions, a fact which is underlined by the recently described molecular interaction of TF's cytoplasmic domain with ABP-280. In cells undergoing cytokinesis, we detected also strong TF expression in dynamic membrane areas and protrusions of the midbodies, indicating an accumulation of TF in actin-rich membrane areas with high contractile activity. In addition, we were able to demonstrate that immobilized ligands for TF, both catalytically active and inactive FVIIa or anti-TF mAbs, accelerated adhesion and spreading of TF-expressing cancer cells. Thus, our findings support the contention that ligation of cellular TF may be involved in morphogenic processes such as adhesion and spreading by an association to cytoskeletal structures. On the other hand, incubation of these cells with proteolytically active FVIIa but not with covalently inactivated FVIIa (DEGR-FVIIa) or anti-TF mAbs in solution resulted in increased motility of these cells, indicating that not only ligation of TF but also the proteolytic activity of TF-FVIIa complex is involved in cell migration.     

Progesterone utilizes distinct membrane pools of tissue factor to increase coagulation and invasion and these effects are inhibited by TFPI

Tissue factor (TF) serving as the receptor for coagulation factor VII (FVII) initiates the extrinsic coagulation pathway. We previously demonstrated that progesterone increases TF, coagulation and invasion in breast cancer cell lines. Herein, we investigated if tissue factor pathway inhibitor (TFPI) could down-regulate progesterone-increased TF activity in these cells. Classically, TFPI redistributes TF-FVII-FX-TFPI in an inactive quaternary complex to membrane associated lipid raft regions. Herein, we demonstrate that TF increased by progesterone is localized to the heavy membrane fraction, despite progesterone-increased coagulation originating almost exclusively from lipid raft domains, where TF levels are extremely low. The progesterone increase in coagulation is not a rapid effect, but is progesterone receptor (PR) dependent and requires protein synthesis. Although a partial relocalization of TF occurs, TFPI does not require the redistribution to lipid rafts to inhibit coagulation or invasion. Inhibition by TFPI and anti-TF antibodies in lipid raft membrane fractions confirmed the dependence on TF for progesterone-mediated coagulation. Through the use of pathway inhibitors, we further demonstrate that the TF up-regulated by progesterone is not coupled to the progesterone increase in TF-mediated coagulation. However, the progesterone up-regulated TF protein may be involved in progesterone-mediated breast cancer cell invasion, which TFPI also inhibits.     

Regulation of tissue factor gene expression in the monocyte procoagulant response to endotoxin.

Tissue factor is the cellular receptor and cofactor for plasma factor VIIa which initiates the coagulation protease cascade on cell surfaces. Although normally absent from all intravascular cell types, tissue factor can be induced to appear on circulating monocytes and vascular endothelial cells by specific inflammatory or immunological mediators. In this study, we have examined the regulation of endotoxin-induced tissue factor gene expression in peripheral blood monocytes.     

Selective attenuation of the extrinsic limb of the tissue factor-driven coagulation protease cascade by occupancy of a novel peptidyl docking site on tissue factor

Tissue factor (TF), the receptor and cofactor for factor VIIa (VIIa) for cellular initiation of the coagulation protease cascade, drives thrombogenesis, inflammation, tumor cell metastasis, and the lethality of severe sepsis. To identify TF surface loci that can selectively inhibit substrate zymogen association and activation, TF(1-218), the extracellular domain, was used as the target for the phage display search. This resulted in selection of 59 clones from a phage gpVIII surface protein-expressed library of constrained combinatorial peptides. Of these, one encoding the peptide Glu-Cys-Leu-Arg-Ser-Val-Val-Thr-Cys on gpVIII most avidly bound TF(1-218), as did the synthetic peptide. Inhibition of binding was selective with an IC(50) of 30 nM for proteolytic activation of factor X by the TF(1-218)-VIIa complex. In contrast, there was no inhibition of factor IX activation. The selective inhibition of only factor X association with TF(1-218) will spare the intrinsic hemostatic pathway while attenuating the extrinsic thrombogenic pathway. This and related peptidyl structures provide the potential for the more precise identification of TF surface loci that mediate selective functional properties of the protein as well as a structural basis for the design of novel molecules for selectively attenuating initiation of the extrinsic limb of the coagulation protease cascade and other functions of TF.     

Flow cytometric analysis of tissue factor (TF) expression on stimulated monocytes--comparison to procoagulant activity of mononuclear blood cells

Whereas tissue factor (TF), a 47 kDa transmembrane glycoprotein, is constitutively present in certain tissues such as epithelial tissue, brain, and placenta, it is normally not expressed by cells within the vasculature. However, inflammatory mediators including bacterial lipopolysaccharide (LPS) can stimulate the expression of cell surface procoagulant activity (PCA) on monocytes. In our present study the kinetics (over 24 h) of molecular TF expression on LPS-stimulated monocytes analyzed by flow cytometry corresponds closely to functional PCA of human mononuclear blood cells (MBC). Both PCA and TF expression on monocytes were rapid events reaching their maximum after about 6 h of stimulation. At this time approximately 70-80% of monocytes had also achieved maximum anti-TF MAb receptor density. For certain analytical applications, monitoring of molecular TF expression on monocytes by flow cytometry using anti-TF MAb is favorable because there is no influence by PCA inhibitors.     

Ligand-induced protease receptor translocation into caveolae: a mechanism for regulating cell surface proteolysis of the tissue factor- dependent coagulation pathway

The ability to regulate proteolytic functions is critical to cell biology. We describe events that regulate the initiation of the coagulation cascade on endothelial cell surfaces. The transmembrane protease receptor tissue factor (TF) triggers coagulation by forming an enzymatic complex with the serine protease factor VIIa (VIIa) that activates substrate factor X to the protease factor Xa (Xa). Feedback inhibition of the TF-VIIa enzymatic complex is achieved by the formation of a quaternary complex of TF-VIIa, Xa, and the Kunitz-type inhibitor tissue factor pathway inhibitor (TFPI). Concomitant with the downregulation of TF-VIIa function on endothelial cells, we demonstrate by immunogold EM that TF redistributes to caveolae. Consistently, TF translocates from the Triton X-100-soluble membrane fractions to low- density, detergent-insoluble microdomains that inefficiently support TF- VIIa proteolytic function. Downregulation of TF-VIIa function is dependent on quaternary complex formation with TFPI that is detected predominantly in detergent-insoluble microdomains. Partitioning of TFPI into low-density fractions results from the association of the inhibitor with glycosyl phosphatidylinositol anchored binding sites on external membranes. Free Xa is not efficiently bound by cell-associated TFPI; hence, we propose that the transient ternary complex of TF-VIIa with Xa supports translocation and assembly with TFPI in glycosphingolipid-rich microdomains. The redistribution of TF provides evidence for an assembly-dependent translocation of the inhibited TF initiation complex into caveolae, thus implicating caveolae in the regulation of cell surface proteolytic activity.     

Caveolae optimize tissue factor-Factor VIIa inhibitory activity of cell-surface-associated tissue factor pathway inhibitor

TFPI (tissue factor pathway inhibitor) is an anticoagulant protein that prevents intravascular coagulation through inhibition of fXa (Factor Xa) and the TF (tissue factor)-fVIIa (Factor VIIa) complex. Localization of TFPI within caveolae enhances its anticoagulant activity. To define further how caveolae contribute to TFPI anticoagulant activity, CHO (Chinese-hamster ovary) cells were co-transfected with TF and membrane-associated TFPI targeted to either caveolae [TFPI-GPI (TFPI-glycosylphosphatidylinositol anchor chimaera)] or to bulk plasma membrane [TFPI-TM (TFPI-transmembrane anchor chimaera)]. Stable clones had equal expression of surface TF and TFPI. TX-114 cellular lysis confirmed localization of TFPI-GPI to detergent-insoluble membrane fractions, whereas TFPI-TM localized to the aqueous phase. TFPI-GPI and TFPI-TM were equally effective direct inhibitors of fXa in amidolytic assays. However, TFPI-GPI was a significantly better inhibitor of TF-fVIIa than TFPI-TM, as measured in both amidolytic and plasma-clotting assays. Disrupting caveolae by removing membrane cholesterol from EA.hy926 cells, which make TFPIα, CHO cells transfected with TFPIβ and HUVECs (human umbilical vein endothelial cells) did not affect their fXa inhibition, but significantly decreased their inhibition of TF-fVIIa. These studies confirm and quantify the enhanced anticoagulant activity of TFPI localized within caveolae, demonstrate that caveolae enhance the inhibitory activity of both TFPI isoforms and define the effect of caveolae as specifically enhancing the anti-TF activity of TFPI.     

Platelet-associated tissue factor contributes to the collagen-triggered activation of blood coagulation

The extravascular localization of tissue factor (TF), the central initiator of coagulation, is thought to ensure that thrombus formation is prevented in the intact vessel. We observed that during a 5-min stimulation of human blood with collagen (type I), TF antigen appeared on the surface of platelets adhering to leukocytes. The rapidly presented intravascular TF was competent to start the coagulation cascade. The isolated platelets from healthy donors contained appreciable amounts of the TF protein, while no TF antigen was detected in the neutrophils and rapidly isolated monocytes. Direct interactions with the neutrophils and monocytes were apparently necessary to activate the platelet-associated TF. This was most likely mediated by inactivation of tissue factor pathway inhibitor through leukocyte elastase. In summary, the leukocyte-elicited activation of the platelet TF participates in the rapid initiation of coagulation by collagen.     

Expression of recombinant rabbit tissue factor in Pichia pastoris,and its application in a prothrombin time reagent

Tissue factor (TF), or thromboplastin, is a cell membrane-associated glycoprotein composed, in full length, of cytoplasmic, transmembrane, and extracellular domains. It functions as a cofactor in a complex with factor VII (FVII), generating activated factor VII (FVIIa) and initiating blood coagulation. The prothrombin time (PT) assay uses TF as the in vitro activator of coagulation under defined conditions, and it is primarily used to diagnose and manage the extrinsic-pathway factor defficiencies. To overcome the limitations of natural-source TF, we have expressed the mature full-length recombinant rabbit TF (rRTF) protein in Pichia pastoris. Isolation, by purification by immobilized metal-affinity chromatography, of full-length rRTF was facilitated by engineering a (His)(6) tail on its C-terminus, which maximizes the selection of rRTF with intact transmembrane and cytoplasmic domains, critical for proper activity. A PT reagent that incorporates this purified rRTF has performance characteristics similar to those of PT reagents made with natural TF as indicated in method comparison studies, and shows lot-to-lot consistency and reproducibility.     

The cofactor function of the N-terminal domain of tissue factor

Tissue factor (TF) is an integral membrane protein cofactor for factor VIIa (fVIIa) that initiates the blood coagulation cascade during vascular injury. TF has two fibrinonectin type III-like domains, both of which make extensive interactions with both the light and heavy chains of fVIIa. In addition to interaction with fVIIa, the membrane proximal C-terminal domain of TF is also known to bind the natural substrates factors IX and X, thereby facilitating their assembly and recognition by fVIIa in the activation complex. Both fVIIa and TF are elongated proteins, and their complex appears to be positioned nearly perpendicular to the membrane surface. It is possible that, similar to fVIIa, the N-terminal domain of TF also contacts the natural substrates. To investigate this possibility, we substituted all 23 basic and acidic residues of the N-terminal domain of TF with Ala or Asn and expressed the mutants as soluble TF(2-219) in a novel expression/purification vector system in the periplasmic space of bacteria. Following purification to homogeneity, the cofactor properties of mutants in promoting the amidolytic and proteolytic activity of fVIIa were analyzed in appropriate kinetic assays. The amidolytic activity assays indicated that several charged residues spatially clustered at the junction of the N- and C-terminal domains of TF are required for high affinity interaction with fVIIa. On the other hand, the proteolytic activity assays revealed that none of the residues under study may be an interactive site for either factor IX or factor X. However, it was discovered the Arg(74) mutant of TF was defective in enhancing both the amidolytic and proteolytic activity of fVIIa, suggesting that this residue may be required for the allosteric activation of the protease.     

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.     

Cross-talk of integrin alpha3beta1 and tissue factor in cell migration

In cancer and angiogenesis, coagulation-independent roles of tissue factor (TF) in cell migration are incompletely understood. Immobilized anti-TF extracellular domain antibodies induce cell spreading, but this phenomenon is epitope specific and is not induced by anti-TF 5G9. Spreading on anti-TF is beta1 integrin-dependent, indicating functional interactions of the TF extracellular domain 5G9 epitope (a presumed integrin-binding site) and integrins. Recombinant TF extracellular domain supports adhesion of cells expressing alphavbeta3 or certain beta1 integrin heterodimers (alpha3beta1, alpha4beta1, alpha5beta1, alpha6beta1, alpha9beta1) and adhesion is blocked by specific anti-integrin antibodies or mutations in the integrin ligand-binding site. Although several studies have linked TF to cell migration, we here demonstrate that TF specifically regulates alpha3beta1-dependent migration on laminin 5. Expression of TF suppresses alpha3beta1-dependent migration, but only when the TF cytoplasmic domain is not phosphorylated. Suppression of migration can be reversed by 5G9, presumably by disrupting integrin interaction, or by the protease ligand VIIa, known to induce PAR-2-dependent phosphorylation of TF. In both cases, release of alpha3beta1 inhibition is prevented by mutation of critical phosphorylation sites in the TF cytoplasmic domain. Thus, TF influences integrin-mediated migration through cooperative intra- and extracellular interactions and phosphorylation regulates TF's function in cell motility.     

The cytoplasmic domain of tissue factor is phosphorylated by a protein kinase C-dependent mechanism.

Tissue factor (TF) is an integral membrane glycoprotein that serves as a cellular receptor and cofactor for the activation of the plasma protease factor VII. TF activity in both monocytes and endothelial cells is regulated by various cytokines and mitogens, including the protein kinase C (PKC) activator phorbol 12-myristate 13-acetate (PMA). Three TF constructs (full-length human, a cytoplasmic domain deletion mutant, and a human-rat TF chimera), expressed in a human kidney cell line, were used to examine the in vivo phosphorylation state of TF after PMA treatment. The cytoplasmic domains of both rat and human TF were rapidly phosphorylated after cells were treated with 10-100 nM PMA. This response was completely abolished by preincubating cells with staurosporine, the potent PKC inhibitor, prior to PMA treatment. Localization of the phosphorylation site(s) to the cytoplasmic domain was demonstrated using a deletion mutant of TF and by CNBr digestion at the single methionine residue (Met-210) in the TF sequence. The rat TF cytoplasmic domain was phosphorylated to a higher specific activity than the human TF cytoplasmic domain. Phosphoamino acid analysis of the chimeric TF revealed both phosphothreonine and phosphoserine, whereas human TF contained only phosphoserine. Thus both potential phosphoacceptor sites are phosphorylated in the rat TF cytoplasmic domain. Alignment of TF cDNA sequences of mouse, rat, rabbit, and man revealed that the phosphoacceptor site (X-S*/T*-P-X, where asterisk indicates the phosphorylated residue) in the cytoplasmic domain has been conserved through evolution.     

Deencryption of cellular tissue factor is independent of its cytoplasmic domain

Tissue factor (TF) is a transmembrane molecule that, when exposed to plasma, is the key initiator of coagulation. Cellular TF activity is normally "encrypted", but treating cells with calcium ionophore (i.e. , ionomycin or A23187) increases ("deencrypts") TF activity without increasing TF mRNA or antigen expression. Deencryption results from both plasma membrane phosphatidylserine (PS)-dependent and -independent mechanisms; however, the nature of the PS-independent component is unclear. Since deencryption has been suggested to result from release of TF dimers on the cell surface, and since TF's cytoplasmic domain binds to actin-binding protein 280 and interacts with the cytoskeleton, we hypothesized that interactions with the cytoskeleton, through the cytoplasmic domain, play a role in mediating encryption/deencryption. We examined TF deencryption and the role of the cytoplasmic domain in the PS-independent component using baby hamster kidney (BHK) cells expressing full length TF (BHK-TF) or TF lacking its cytoplasmic domain (BHK-descyt) (Sorensen et al. (1999) J. Biol. Chem. 274, 21349). Both BHK-TF and BHK-descyt cells exhibited a dose-dependent, 1.5- to 10-fold increase in TF activity upon treatment with calcium ionophore, and this increase in activity was only partially blocked by annexin V. These results indicate that deencryption is not restricted to cells which naturally express TF and that the PS-independent component of deencryption is intact on cells transfected with either full length or truncated TF. Our results clearly indicate that deencryption is not dependent on an intact cytoplasmic domain in transfected BHK cells.     

Phospholipid-independent and -dependent interactions required for tissue factor receptor and cofactor function

Membrane anchoring of tissue factor (TF), the cell receptor for coagulation factor VIIa (VIIa), exemplifies an effective mechanism to localize proteolysis at the cell surface. A recombinant TF mutant (TF1-219), deleted of membrane spanning and intracellular domains, was used to evaluate the role of phospholipid interactions for assembly of substrate with the catalytic TF.VIIa complex. TF1-219 was secreted by cells rather than expressed as a cell membrane protein. Unlike free VIIa, TF1-219 as well as the TF1-219.VIIa complex demonstrated no stable association with phospholipid. In the absence of lipid, kinetic evaluation of substrate factor X cleavage by free VIIa, TF.VIIa, and TF1-219.VIIa suggests that the catalytic function of VIIa rather than substrate recognition is enhanced by complex formation. Furthermore, compared with free factor X, factor X on phospholipid was preferentially cleaved as a substrate by TF1-219.VIIa. TF-dependent initiation of the coagulation protease cascades thus involves an enhancement of the activation of factor X on the cell surface by a crucial role of the TF transmembrane domain to membrane anchor the reaction, by the TF extracellular domain to provide protein-protein interactions with VIIa to enhance the activity of the catalytic domain of VIIa, and the preferential presentation of factor X as a substrate when associated with phospholipid surfaces.     

Structural modulation of factor VIIa by full-length tissue factor (TF1-263): implication of novel interactions between EGF2 domain and TF

Tissue factor (TF)-mediated factor VII (FVII) activation and a subsequent proteolytic TF-FVIIa binary complex formation is the key step initiating the coagulation cascade, with implications in various homeostatic and pathologic scenarios. TF binding allosterically modifies zymogen-like free FVIIa to its highly catalytically active form. As a result of unresolved crystal structure of the full-length TF_1-263-FVIIa binary complex and free FVIIa, allosteric alterations in FVIIa following its binding to full-length TF and the consequences of these on function are not entirely clear. The present study aims to map and identify structural alterations in FVIIa and TF resulting from full-length TF binding to FVIIa and the key events responsible for enhanced FVIIa activity in coagulation. We constructed the full-length TF_1-263-FVIIa membrane bound complex using computational modeling and subjected it to molecular dynamics (MD) simulations. MD simulations showed that TF alters the structure of each domain of FVIIa and these combined alterations contribute to enhanced TF-FVIIa activity. Detailed, domain-wise investigation revealed several new non-covalent interactions between TF and FVIIa that were not found in the truncated soluble TF-FVIIa crystal structure. The structural modulation of each FVIIa domain imparted by TF indicated that both inter and intra-domain communication is crucial for allosteric modulation of FVIIa. Our results suggest that these newly formed interactions can provide additional stability to the protease domain and regulate its activity profile by governing catalytic triad (CT) orientation and localization. The unexplored newly formed interactions between EGF2 and TF provides a possible explanation for TF-induced allosteric activation of FVIIa.     

III. Instantaneous inhibition by compound 48/80 of tissue factor-initiated extrinsic coagulation is mediated by the downregulation of factor VII activation

Our previous study has demonstrated a unique biological function of compound 48/80 (48/80) in the downregulation of monocytic tissue factor (TF)-initiated hypercoagulation in response to bacterial endotoxin (lipopolysaccharide, LPS) [A. J. Chu et al. (1999) Biochim. Biophys. Acta 1472, 386-395]. The inhibition was not due to the blockade of LPS cell signaling as evidenced by the unaffected LPS-induced TF synthesis. In the present study, we investigate the direct inhibitory action of 48/80 on the extrinsic coagulation cascade. TF-initiated coagulation was assayed by a single-stage clotting assay. Chromogenic assays dissected the extrinsic pathway to measure the activities of FVII, FX, and prothrombin by monitoring the hydrolyses of nitroaniline-conjugated substrates, identifying the inhibitory site(s). We report that 48/80 in vitro instantaneously inhibited rabbit brain thromboplastin (rbTF)-initiated coagulation in a dose-dependent manner. 48/80 preferentially inhibited FVII activation without any detectable effect on FVIIa, FXa, and thrombin activities. Neither FX activation nor prothrombin activation was affected. The significant inhibition on FVII activation was found to be noncompetitive with a fourfold reduction in the apparent Vmax of FVIIa formation from 7.1 to 1.7 nM/min, while the apparent Km (approximately 365 nM) remained unaffected. Western blotting analysis further confirmed that FVIIa formation derived from FVII was significantly diminished by 48/80, which was accompanied by blocked FVII binding to rbTF. In conclusion, 48/80 readily blocked FVII binding to rbTF, leading to diminished FVII activation and FVIIa formation. As a result, TF-initiated extrinsic coagulation was downregulated.