Correlation between trypsin binding to a specific receptor and prostacyclin production in cultured vascular endothelial cells

The correlation between the binding and processing of trypsin and its effect on prostacyclin (PGI2) production in cultured adult bovine aortic endothelial (ABAE) cells was studied. ABAE cells demonstrated an ability to produce PGI2 in a dose-response manner to trypsin at the range of 0.1-2.0 micrograms/ml with a saturation at a concentration of 1 microgram/ml. Likewise, 125I-trypsin binding to the cultured cells increased in a dose-response way and reached saturation at a concentration of about 1 microgram/ml; 125I-trypsin was bound to a specific high-affinity cell-surface receptor with a dissociation constant (Kd) of 1.5 X 10(-8) M and each of the confluent ABAE cells has about 1.2 X 10(5) such receptors sites. The cell-surface receptor for trypsin displayed specific characteristics and an excess amount of unlabeled trypsin successfully abolished 125I-trypsin binding while thrombin in excess failed to compete for 125I-trypsin binding. Only a small fraction of the cell-surface-bound 125I-trypsin was internalized and subsequently degraded by ABAE cells as compared to the process of 125I-trypsin internalization by human skin fibroblasts (HSF). This study demonstrated that the stimulatory effect of trypsin on prostacyclin production and release by ABAE cells might be mediated by a specific cell-surface receptor for trypsin on these cells distinct from the thrombin receptor.     

Covalent binding of thrombin to specific sites on corneal endothelial cells

Binding of 125I-labeled human alpha-thrombin to endothelial cells derived from bovine corneas was studied in tissue culture. Specific and saturable binding to the cell surface occurred at 37 degrees C but to a much smaller extent at 4 degrees C. Binding of [125I]thrombin to a specific site on these cells with formation of a 77000-dalton complex was demonstrated by NaDodSO4 (sodium dodecyl sulfate)-polyacrylamide gel electrophoresis. Binding of [125I]thrombin was blocked by a 100-fold excess of unlabeled alpha-thrombin and by the thrombin inhibitor, hirudin. There are approximately 100000 of these thrombin binding sites on the cell surface. Formation of the complex could be detected as early as 15 s, increased rapidly over the next 20-30 min, and then continued at a slower rate for the next 2.5 h. The catalytically active site of the enzyme was required for formation of the NaDodSO4-stable complex as shown by the inability of diisopropyl phosphorofluoride inactivated thrombin to form stable complexes with these cells. The complex was dissociated in NaDodSO4 with 1.0 M hydroxylamine, suggesting an acyl linkage of the enzyme to the cellular binding site. The thrombin-endothelial cell complex was distinct from the thrombin-antithrombin III complex (Mr approximately 90000) on gel electrophoresis, and its formation was not enhanced by heparin. Additional thrombin-cell complexes (Mr less than 77000) were also identified; however, they represent a small fraction of the total thrombin bound to the cells. These observations demonstrate that alpha-thrombin is capable of reacting specifically with corneal endothelial cells to form a NaDod-SO4-stable complex which requires the catalytically active enzyme.     

Localization of anticoagulantly active heparan sulfate proteoglycans in vascular endothelium: antithrombin binding on cultured endothelial cells and perfused rat aorta

We have studied the interaction of 125I-antithrombin (125I-AT) with microvascular endothelial cells (RFPEC) to localize the cellular site of anticoagulantly active heparan sulfate proteoglycans (HSPG). The radiolabeled protease inhibitor bound specifically to the above HSPG with a Kd of approximately 50 nM. Confluent monolayer RFPEC cultures exhibited a linear increase in the amount of AT bound per cell for up to 16 d, whereas suspension RFPEC cultures possessed a constant number of protease inhibitor binding sites per cell for up to 5 d. These results suggest that monolayer RFPEC cultures secrete anticoagulantly active HSPG, which then accumulate in the extracellular matrix. This hypothesis was confirmed by quantitative light and EM level autoradiography which demonstrated that the AT binding sites are predominantly located in the extracellular matrix with only small quantities of protease inhibitor complexed to the cell surface. We have also pinpointed the in vivo position of anticoagulantly active HSPG within the blood vessel wall. Rat aortas were perfused, in situ, with 125I-AT, and bound labeled protease inhibitor was localized by light and EM autoradiography. The anticoagulantly active HSPG were concentrated immediately beneath the aortic and vasa vasorum endothelium with only a very small extent of labeling noted on the luminal surface of the endothelial cells. Based upon the above data, we propose a model whereby luminal and abluminal anticoagulantly active HSPG regulate coagulation mechanism activity.     

Protease specificity and heparin binding and activation of recombinant protease nexin I

Structural and functional properties of alpha-protease nexin I (alpha-PNI) expressed in Chinese hamster ovary cells were studied. All three cysteines were in the reduced form, showing that the potential disulfide bridge between residues Cys117 and Cys131 was not formed. Heparin association rate enhancements were from ka = 8.3 x 10(5) to 0.7-1.6 x 10(9) M-1 s-1 for the interaction of PNI with thrombin, from ka = 5.1 x 10(3) to 3.5 x 10(5) M-1 s-1 for interaction with Factor Xa, and from ka = 2.2 x 10(6) to 1.0 x 10(7) M-1 s-1 for interaction with trypsin; there was no rate enhancement of the plasmin interaction (ka = 1.0 x 10(5) M-1 s-1). The minimal heparin pentasaccharide had no effect on these interactions. Cleavage of the reactive center loop of PNI by three different proteases gave the typical stressed to relaxed change in thermal stability, but unlike with antithrombin III, there was no loss of heparin affinity. A similar difference from antithrombin was that PNI-thrombin complexes retained normal heparin affinity. These results are compatible with a role for protease nexin I as a cell-associated thrombin inhibitor that remains bound to the cell surface even after complexing with the protease, as compared with the role of antithrombin III as a circulating inhibitor of thrombin that becomes activated on binding to the microvasculature and is released on complex formation.     

Binding of thrombin to thrombomodulin accelerates inhibition of the enzyme by antithrombin III. Evidence for a heparin-independent mechanism

The endothelial cell surface provides a receptor for thrombin-designated thrombomodulin (TM) which regulates thrombin formation and the activity of the enzyme at the vessel wall surface by serving as a potent cofactor for the activation of protein C by thrombin. Heparin-like structures of the vessel wall have been proposed as another regulatory mechanism catalyzing the inhibition of thrombin by antithrombin III. In the present study, the interaction of antithrombin III with the thrombin-TM complex and its interference with heparin and polycations were investigated by using human components and TM isolated from the microvasculature of rabbit lung. Purified TM bound thrombin and acted as a cofactor for protein C activation. The addition of heparin (0.5 unit/mL) to the reaction mixture interfered neither with the binding of thrombin to TM nor with the activation of protein C. However, the polycations protamine (1 unit/mL) as well as polybrene (0.1 mg/mL) affected the thrombin-TM interaction. This was documented by an increase in the Michaelis constant from 8.3 microM for thrombin alone to 19.5 microM for thrombin-TM with the chromogenic substrate compound S-2238 in the presence of 1 unit/mL protamine. When the inhibition of thrombin by antithrombin III was determined, the second-order rate constant k2 = 8.4 X 10(3) M-1 s-1 increased about 8-fold in the presence of TM, implying an accelerative function of TM in this reaction. Although purified TM did not bind to antithrombin III-Sepharose, suggesting the absence of heparin-like structures within the receptor molecule, protamine reversed the accelerative effect of TM in the inhibition reaction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of the receptor for protease nexin-I:protease complexes on human fibroblasts

Fibroblasts as well as several other cell types, secrete a number of protease inhibitors into their culture media. Among these inhibitors are the protease nexins, a class of proteins which covalently bind serine proteases, thereby inactivating their specific targets. Protease nexin-I, first discovered in human foreskin fibroblasts, binds thrombin, plasmin, and urokinase with high affinity, forming covalently linked complexes. Human fibroblasts bind complexes of protease nexin-I and its target protease via a cell-surface, high-affinity receptor. We have analyzed a number of characteristics of this receptor, and found them to be typical of class II receptors in general. At 4 degrees C binding of PN-I:protease complexes was competed by heparin. In addition, binding was independent of the particular protease bound to the PN-I; purified complexes of PN-I with thrombin or urokinase competed equipotently for [125]I-thrombin:PN-I binding. As the pH of the binding buffer was lowered, binding to cells increased. A twofold increase in binding was attained by lowering the pH from 7.5 to 4.5. This phenomenon was not due to irreversible, pH-induced changes to either the cell surface or the labeled complexes. At 37 degrees C, the removal of labeled complexes from culture medium was rapid; approximately 80% was removed by 4 hours under given conditions. The internalization of complexes was also very rapid, with an estimated ke (endocytic rate constant) of 1.0 min-1. At neutral pH, fibroblasts bind complexes in a saturable manner. Scatchard analysis yields a receptor number of 250,000 per cell and a Kd of 1 nM.     

Anti-thrombin activity in cultured aortic and capillary endothelial cells: binding, internalization and degradation of thrombin

Thrombin (Th) binds specifically to confluent cultures of adult bovine aortic (ABAE) and bovine brain capillary (BBC) endothelial cells. Saturation of 125I-Th binding is observed after 1 h exposure to the ligand and at an extracellular concentration of 0.5 and 1.0 microgram/ml for ABAE and BBC cells, respectively. Under optimal conditions both ABAE and BBC cultures bind about 2 to 5 ng/10(6) cells, which represents about 20% of Th binding to bovine corneal endothelial (BCE) cells. Under optimal conditions less than 30% of the total cell associated 125I-Th is internalized in ABAE and BBC cells, while in BCE cells the extent of internalization is more than 50%. The internalized 125I-Th is degraded both in ABAE and BBC cells as previously demonstrated in BCE cells. As analyzed by SDS-PAGE, 17%, 22% and 77% of the bound 125I-Th is in complex with anti-thrombins (anti-Ths) in BBC, ABAE and BCE cultures, respectively. ABAE cells possess 3 types of complexes, one which appears only on the cell surface with a molecular weight of 78 kDa, and two others which appear only in the conditioned medium (CM) with molecular weights of 84 and 85 kDa. BBC and BCE cells demonstrate only one type of complex with a molecular weight of 77 kDa which appears both on the cell surface and in the CM. The 125I-Th 77 kDa complex formed in the CM of BCE cells is recognized and bound by BBC cells and ABAE cells.(ABSTRACT TRUNCATED AT 250 WORDS)     

In vivo catabolism of heparin cofactor II and its complex with thrombin: evidence for a common receptor-mediated clearance pathway for three serine proteinase inhibitors

The plasma clearance of 125I-labeled human heparin cofactor II and its complex with thrombin was studied in mice to determine whether a specific mechanism exists for the catabolism of the inhibitor-proteinase complex. Initial studies demonstrated that murine plasma contains a heparin cofactor II-like inhibitor as shown by the presence of a dermatan sulfate-sensitive thrombin inhibitor. Human heparin cofactor II cleared from the circulation of mice with an apparent half-life of 80 min while heparin cofactor II-thrombin complexes cleared with an apparent half-life of only 10 min. The specificity of the clearance mechanism was investigated by clearance competition studies involving coinjection of excess unlabeled heparin cofactor II-alpha-thrombin, antithrombin III-alpha-thrombin, or alpha 1-proteinase inhibitor-elastase, and by tissue distribution studies. The results demonstrated that the clearance of 125I-labeled heparin cofactor II-alpha-thrombin is a receptor-mediated process, and that the same hepatocyte receptor system recognizes complexes containing heparin cofactor II, antithrombin III, and alpha 1-proteinase inhibitor.     

Association of thrombin, plasmin, thrombin-antithrombin III complex and plasmin-antithrombin III complex with isolated hepatocytes

The interaction of thrombin, plasmin or their antithrombin III complexes with isolated mouse hepatocytes was studied. Plasmin bound to hepatocytes in a concentration-dependent manner with an apparent Kd of 6.4.10(-8) M, attaining equilibrium within 10 min, and the interaction was inhibited by 6-amino-n-hexanoic acid. Plasmin treated with diisopropylfluorophosphate (DFP) bound to the cells in similar way as the untreated form of the enzyme. Thrombin bound also to hepatocytes, in a concentration-dependent manner, with a Kd of 5.4.10(-8) M reaching a steady state after 180 min. Thrombin inactivated with DFP, however, was inhibited in its binding to these cells. These data suggest that, whereas the kringle domains of plasmin are responsible for the enzyme-cell interaction, the active center of thrombin may be involved in the binding of this enzyme to hepatocytes. Plasmin-antithrombin III and thrombin-antithrombin III complexes were also associated with hepatocytes in a time-dependent manner, reaching a plateau after 180 min, and the two complexes competed in the interaction. While the interaction of active proteinases plasmin or thrombin with hepatocytes did not result in their internalization, the antithrombin III complexes were taken up by the cells, and thrombin-antithrombin III complex was degraded. These results indicate that hepatocytes may participate in the elimination of proteinase-antithrombin III complexes from the plasma, while the association of plasmin and thrombin with hepatocytes could imply distinct biological importance.     

Covalent binding of human thrombin to a human endothelial cell-associated protein

Binding of 125I-thrombin to endothelial cells derived from human umbilical vein was studied in tissue culture. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and autoradiography revealed covalent binding of thrombin in a 72-kDa complex. This binding is specific and requires the catalytically active site of the enzyme. Formation of the complex could be detected as early as 3 min after addition of thrombin or with a thrombin concentration as low as 0.5 nM. This irreversible binding exhibits thrombin dose-dependence and reaches maximum levels at a concentration of 50 nM (10 fmol/10(5) cells). Some characteristics of the 72-kDa complex were compared to those of the complexes formed between thrombin and protease nexin originating from fibroblasts or platelets: (i) its electrophoretic mobility on SDS-PAGE is identical to that of the thrombin-platelet protease nexin complex, (ii) heparin prevents the appearance of the complex on the cell surface, (iii) plasmin in a 100-fold molar excess prevents the covalent linkage of thrombin, suggesting that the protease specificity of the endothelial component involved in the complex might not be restricted to thrombin. Yet no release, nor any secretion of the endothelial protein, could be detected. These results indicate that active thrombin binds covalently to a specific endothelial protein that is in several respects similar to fibroblast or platelet protease nexin and provides a thrombin binding site distinct from thrombomodulin and glycosaminoglycans.     

Antiangiogenic antithrombin blocks the heparan sulfate-dependent binding of proangiogenic growth factors to their endothelial cell receptors: evidence for differential binding of antiangiogenic and anticoagulant forms of antithrombin to proangiogenic heparan sulfate domains

The anticoagulant serpin antithrombin acquires a potent antiangiogenic activity upon undergoing conformational alterations to cleaved or latent forms. Here we show that antithrombin antiangiogenic activity is mediated at least in part through the ability of the conformationally altered serpin to block the proangiogenic growth factors fibroblast growth factor (FGF)-2 and vascular endothelial growth factor (VEGF) from forming signaling competent ternary complexes with their protein receptors and heparan sulfate co-receptors on endothelial cells. Cleaved and latent but not native forms of antithrombin blocked the formation of FGF-2-FGF receptor-1 ectodomain-heparin ternary complexes, and the dimerization of these complexes in solution and similarly inhibited the formation of FGF-2-heparin binary complexes and their dimerization. Only antiangiogenic forms of antithrombin likewise inhibited (125)I-FGF-2 binding to its low affinity heparan sulfate co-receptor and blocked FGF receptor-1 autophosphorylation and p42/44 MAP kinase phosphorylation in cultured human umbilical vein endothelial cells (HUVECs). Moreover, treatment of HUVECs with heparinase III to specifically eliminate the FGF-2 heparan sulfate co-receptor suppressed the ability of antiangiogenic antithrombin to inhibit growth factor-stimulated proliferation. Antiangiogenic antithrombin inhibited full-length VEGF(165) stimulation of HUVEC proliferation but did not affect the stimulation of cells by the heparin-binding domain-deleted VEGF(121). Taken together, these results demonstrate that antiangiogenic forms of antithrombin block the proangiogenic effects of FGF-2 and VEGF on endothelial cells by competing with the growth factors for binding the heparan sulfate co-receptor, which mediates growth factor-receptor interactions. Moreover, the inability of native antithrombin to bind this co-receptor implies that native and conformationally altered forms of antithrombin differentially bind proangiogenic heparan sulfate domains.     

Cell-binding domain of endothelial cell thrombospondin: localization to the 70-kDa core fragment and determination of binding characteristics.

Endothelial and other cell types synthesize thrombospondin (TSP), secrete it into their culture medium, and incorporate it into their extracellular matrix. TSP is a large multifunctional protein capable of specific interactions with other matrix components, as well as with cell surfaces, and can modulate cell adhesion to the extracellular matrix. With the aim of understanding the mechanism by which TSP exerts its effect on cell adhesion, we studied the interaction of endothelial cell TSP (EC-TSP) with three different cell types: endothelial cells, granulosa cells, and myoblasts. We find that endothelial cells specifically bind radiolabeled EC-TSP with a Kd of 25 nM, and the number of binding sites is 2.6 X 10(6)/cell. Binding is not inhibitable by the cell-adhesion peptide GRGDS, indicating that the cell-binding site of EC-TSP is not in the RGD-containing domain. Localization of the cell-binding site was achieved by testing two chymotryptic fragments representing different regions of the TSP molecule, the 70-kDa core fragment and the 27-kDa N-terminal fragment, for their ability to bind to the cells. Cell-binding capacity was demonstrated by the 70-kDa fragment but not by the 27-kDa fragment. Binding of both intact [125I]EC-TSP and of the 125I-labeled 70-kDa fragment was inhibited by unlabeled TSP, heparin, fibronectin (FN), monoclonal anti-TSP antibody directed against the 70-kDa fragment (B7-3), and by full serum, but not by heparin-absorbed serum or the cell-adhesion peptide GRGDS. The 70-kDa fragment binds to endothelial cells with a Kd of 47 nM, and the number of binding sites is 5.0 x 10(6)/cell.(ABSTRACT TRUNCATED AT 250 WORDS)     

Involvement of heparin chain length in the heparin-catalyzed inhibition of thrombin by antithrombin III

The mechanism of the heparin-promoted reaction of thrombin with antithrombin III was investigated by using covalent complexes of antithrombin III with either high-affinity heparin (Mr = 15,000) or heparin fragments having an average of 16 and 12 monosaccharide units (Mr = 4,300 and 3,200). The complexes inhibit thrombin in the manner of active site-directed, irreversible inhibitors: (Formula: see text) That is, the inhibition rate of the enzyme is saturable with respect to concentration of complexes. The values determined for Ki = (k-1 + k2)/k1 are 7 nM, 100 nM, and 6 microM when the Mr of the heparin moieties are 15,000, 4,300, 3,200, respectively, whereas k2 (2 S-1) is independent of the heparin chain length. The bimolecular rate constant k2/Ki for intact heparin is 3 X 10(8) M-1 S-1 and the corresponding second order rate constant k1 is 6.7 X 10(8) M-1 S-1, a value greater than that expected for a diffusion-controlled bimolecular reaction. The bimolecular rate constants for the complexes with heparin of Mr = 4,300 and 3,200 are, respectively, 2 X 10(7) M-1 S-1 and 3 X 10(5) M-1 S-1. Active site-blocked thrombin is an antagonist of covalent antithrombin III-heparin complexes: the effect is monophasic and half-maximum at 4 nM of antagonist against the complex with intact heparin, whereas the effect is weaker against complexes with heparin fragments and not monophasic. We conclude that virtually all of the activity of high affinity, high molecular weight heparin depends on binding both thrombin and antithrombin III to heparin, and that the exceptionally high activity of heparin results in part from the capacity of thrombin bound nonspecifically to heparin to diffuse in the dimension of the heparin chain towards bound antithrombin III. Increasing the chain length of heparin results in an increased reaction rate because of a higher probability of interaction between thrombin and heparin in solution.     

Urokinase binding and receptor identification in cultured endothelial cells.

Recombinant human single-chain urokinase (rscu-PA), two-chain urokinase (tcu-PA), and diisopropyl-fluorophosphate-treated tcu-PA (DFP-tcu-PA) bound to cultured human and porcine endothelial cells in a rapid, saturable, dose-dependent and reversible manner. Analysis of specific binding results in cultured human umbilical vein endothelial cells (HUVECs) gave the following estimated values for Kd and Bmax: 0.57 +/- 0.08 nM (mean +/- S.E.) and 188,000 +/- 18,000 sites/cell for 125I-labeled rscu-PA; 0.54 +/- 0.10 nM and 132,000 +/- 23,900 sites/cells for 125I-labeled tcu-PA; 0.89 +/- 0.14 nM and 143,000 +/- 30,300 sites/cell for 125I-labeled DFP-tcu-PA, respectively. Values for Kd were similar for primary and subcultured (six passages) HUVECs, but Bmax values were lower in subcultured HUVECs. Similar Kd values were found in cultured porcine endothelial cells; however, Bmax values varied depending on the endothelial cell type. All 125I-labeled urokinase forms yielded similar cross-linked approximately 110-kDa ligand-receptor complexes with cultured HUVECs, and 125I-labeled DFP-tcu-PA bound to a single major approximately 55-kDa protein in whole-cell lysates (ligand blotting/autoradiography), suggesting the presence of a single major approximately 55-kDa urokinase receptor in cultured HUVECs. The approximately 55-kDa urokinase receptor, isolated from several separate batches of cultured HUVECs (3-5 micrograms of protein, approximately 1 x 10(9) cells), by ligand affinity chromatography, exhibited the following properties: retained biologic activity as evidenced by its ability to bind 125I-labeled rscu-PA by ligand blotting/autoradiography and formation of a cross-linked 125I-labeled approximately 110-kDa rscu-PA-receptor complex; single-chain approximately 55-kDa protein, following reduction; complete conversion to and formation of a single major deglycosylated approximately 35-kDa protein, following treatment with N-glycanase.     

Binding of type 1 plasminogen activator inhibitor to the extracellular matrix of cultured bovine endothelial cells

The binding of type 1 plasminogen activator inhibitor (PAI-1) to the extracellular matrix (ECM) of cultured bovine aortic endothelial cells was investigated using purified 125I-labeled or L-[35S]methionine-labeled PAI-1 as probes. Little specific binding of latent PAI-1 to ECM previously depleted of endogenous PAI-1 could be demonstrated. In contrast, the guanidine-activated form of PAI-1 bound to ECM in a dose- and time-dependent manner, and binding was saturable. The dissociation constant (Kd) for this interaction was estimated to be 60 nM by Scatchard analysis, and approximately 6 pmol of activated PAI-1 was bound per cm2 of ECM. Binding was relatively specific since unlabeled, activated PAI-1 competed with 35S-labeled PAI-1 for binding to ECM, but latent PAI-1 did not. Moreover, PAI-2, protein C inhibitor (i.e. PAI-3), protease nexin-1, and alpha 2-antiplasmin were not able to compete. Tissue-type plasminogen activator (tPA) also inhibited binding, but diisopropyl fluorophosphate-inactivated tPA did not. Pretreatment of ECM with tPA, urokinase-type PA, or thrombin had no effect on its ability to subsequently bind PAI-1, whereas trypsin, plasmin, and elastase pretreatment greatly reduced its ability to bind PAI-1. Guanidine-activated, radiolabeled PAI-1 resembled active endogenous PAI-1 since it was unstable in solution but stable when bound to ECM. In addition, it formed complexes with tPA that had a relatively low affinity for ECM. These data suggest that ECM of bovine aortic endothelial cells contains a protease-sensitive structure that binds active PAI-1 tightly and relatively selectively and that this association stabilizes PAI-1 against the spontaneous loss of activity that occurs in solution.     

Receptor-bound thrombin is not internalized through coated pits in mouse embryo cells

The localization of thrombin receptors on mouse embryo (ME) cells was examined using electron microscope (EM) immunocytological techniques. ME cells were fixed with formaldehyde, prior to thrombin binding, and thrombin visualized on cell surfaces using affinity-purified antithrombin rabbit antibody and colloidal gold labeled anti-rabbit IgG. Colloidal gold particles were found in clusters on the surface of cells incubated with thrombin. There were approximately seven particles per cluster observed in thin sections with cluster diameters ranging from 70 to 200 nm. These clusters were not observed on cells incubated without thrombin. The total number of particles present on cells incubated with and without thrombin indicate that the colloidal gold labeling is approximately 98% specific for thrombin. Only four colloidal gold particles out of approximately 1,200 were associated with coated pits. Thus the thrombin receptor clusters do not appear to associate with coated membrane regions. To determine whether receptor-bound thrombin was internalized by receptor-mediated endocytosis, ME cells were incubated with 125I-thrombin and examined using EM autoradiography and the trypsin sensitivity of 125I-thrombin which was associated with the cells. In two types of experiments, where thrombin was incubated with cells at 4 degrees C and the temperature increased to 37 degrees C and where initial incubation was at 37 degrees C, the receptor-directed specific internalization proceeded at approximately the same rate as nonspecific internalization. These studies indicate that thrombin that binds to its receptors on ME cells is not rapidly internalized by receptor-mediated endocytosis.     

Association of alpha 2-macroglobulin-thrombin and alpha 2-macroglobulin-plasmin complexes with isolated hepatocytes

125I-labelled alpha 2-macroglobulin complexed with thrombin or plasmin bound to hepatocytes in a concentration- and time-dependent manner. The apparent Kd values calculated from displacement experiments were 7.9 X 10(-8) M for alpha 2-macroglobulin-thrombin and 8.5 X 10(-8) M for alpha 2-macroglobulin-plasmin. Association of these complexes was only partially reversible; after a 180 min incubation period, 50-60% of the bound radioactivity was internalized by the cells. alpha 2-Macroglobulin itself bound also to hepatocytes, but the affinity of the alpha 2-macroglobulin complexes was higher than that of the inhibitor alone, and alpha 2-macroglobulin was not internalized, either. 125I-labelled thrombin or plasmin bound to hepatocytes as well. These bindings were also concentration-dependent and could be decreased with an excess of unlabelled ligands. Binding rates and amounts of the bound proteinases were higher than those of their alpha 2-macroglobulin complexes. The alpha 2-macroglobulin-thrombin complex competed with the alpha 2-macroglobulin-plasmin complex in binding to hepatocytes, whereas there was no competition between these complexes and the antithrombin III-thrombin complex. These results suggest that the binding sites of hepatocytes for alpha 2-macroglobulin-proteinase and antithrombin III-proteinase complexes are different.     

Ligand specificity of human thrombomodulin. Equilibrium binding of human thrombin, meizothrombin, and factor Xa to recombinant thrombomodulin.

Thrombomodulin is an endothelial glycoprotein that serves as a cofactor for protein C activation. To examine the ligand specificity of human thrombomodulin, we performed equilibrium binding assays with human thrombin, thrombin S205A (wherein the active site serine is replaced by alanine), meizothrombin S205A, and human factor Xa. In competition binding assays with CV-1(18A) cells expressing cell surface recombinant human thrombomodulin, recombinant wild type thrombin and thrombin S205A inhibited 125I-diisopropyl fluorophosphate-thrombin binding with similar affinity (Kd = 6.4 +/- 0.5 and 5.3 +/- 0.3 nM, respectively). However, no binding inhibition was detected for meizothrombin S205A or human factor Xa (Kd greater than 500 nM). In direct binding assays, 125I-labeled plasma thrombin and thrombin S205A bound to thrombomodulin with Kd values of 4.0 +/- 1.9 and 6.9 +/- 1.2 nM, respectively. 125I-Labeled meizothrombin S205A and human factor Xa did not bind to thrombomodulin (Kd greater than 500 nM). We also compared the ability of thrombin and factor Xa to activate human recombinant protein C. The activation of recombinant protein C by thrombin was greatly enhanced in the presence of thrombomodulin, whereas no significant activation by factor Xa was detected with or without thrombomodulin. Similar results were obtained with thrombin and factor Xa when human umbilical vein endothelial cells were used as the source of thrombomodulin. These results suggest that human meizothrombin and factor Xa are unlikely to be important thrombomodulin-dependent protein C activators and that thrombin is the physiological ligand for human endothelial cell thrombomodulin.     

Thrombin interaction with platelets. Influence of a platelet protease nexin

A fraction of the 125I-thrombin that binds to human platelets is taken into a sodium dodecyl sulfate-resistant 77 kDa complex with a platelet factor (Bennett, W. F., and Glenn, K. C. (1980) Cell 22, 621-627). Here we show that this platelet factor is in several respects similar to protease nexin I (PNI), a fibroblast thrombin inhibitor. The complexes are of the appropriate size, bind to Sepharose that has been derivatized with anti-PNI antibody, do not form when the thrombin active site has been blocked with diisopropylphosphofluoridate, and do not appear on platelets when heparin is present. However, the platelet factor does not bind urokinase, indicating that this "platelet PN" may be distinct from PNI. Following brief incubation with 125I-thrombin, platelet PN X 125I X thrombin complexes are found both associated with the platelets and free in the binding medium. 125I-Thrombin has a higher affinity for platelet PN than for platelet receptors. In 30-s binding incubations carried out with thrombin at concentrations below 0.3 nM, formation of the 77-kDa complex accounts for most of the platelet specific binding of 125I-thrombin. Subtracting this large contribution to 125I-thrombin-specific binding reveals that the reversible binding of 125I-thrombin to platelet receptors exhibits sigmoidal thrombin dose-dependence. Thrombin stimulation of platelet [14C]serotonin release exhibits similar thrombin dose dependence. These results indicate that platelets may possess a mechanism for suppressing their interaction with active thrombin at thrombin doses below 0.3 nM. It is possible that platelet PN carries out this function by capturing thrombin before thrombin binds to its signal-transmitting receptors.     

Human recombinant interleukin-1 beta- and tumor necrosis factor alpha-mediated suppression of heparin-like compounds on cultured porcine aortic endothelial cells

Cytokines are known to tip the balance of the coagulant-anticoagulant molecules on the endothelial cell surface toward intravascular coagulation. Their effects on endothelial cell surface-associated heparin-like compounds have not been examined yet. Incorporation of [35S]sulfate into heparan sulfate on cultured porcine aortic endothelial cells was suppressed by human recombinant interleukin-1 beta (rIL-1 beta) or tumor necrosis factor alpha (rTNF alpha) in a dose- and time-dependent manner with little effect on cell number, protein content, and [3H]leucine incorporation of cells. Maximal inhibition was achieved by incubation of cells with 100 ng/ml of rIL-1 beta or 5 ng/ml of rTNF alpha for 12-24 hours, resulting in a reduction of the synthesis of heparan sulfate on the cell surface by approximately 50%. The dose dependency was consistent with that seen in the stimulation of endothelial cell procoagulant activity by each cytokine. The suppression of heparan sulfate synthesis was sustained for at least 48 hours after pretreatment of cells with cytokines and was unchanged after the addition of indomethacin or polymyxin B. The rate of degradation of prelabeled 35S-heparan sulfate on the cell surface was not altered by cytokine treatments. Neither the size, the net negative charge, nor the proportion of the molecule with high affinity for antithrombin III of endothelial cell heparan sulfate was changed by cytokines. Furthermore, specific binding of 125I-labeled antithrombin III to the endothelial cell surface was reduced to 40-60% of control by cytokines. In parallel with reduction in binding, antithrombin III cofactor (heparin-like) activity was partially diminished in cytokine-treated endothelial cells. Thus, cytokine-mediated suppression of heparin-like substance on endothelial cells appears to be another cytokine-inducible endothelial effects affecting coagulation.