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J. Biol. Chem., Vol. 283, Issue 5, 2470-2477, February 1, 2008

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Bivalent Binding to _A/'-Fibrin Engages Both Exosites of Thrombin and Protects It from Inhibition by the Antithrombin-Heparin Complex^*

From the Henderson Research Centre and McMaster University, Hamilton, Ontario L8V 1C3, Canada

Received for publication, September 13, 2007 , and in revised form, November 29, 2007.

	ABSTRACT

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Thrombin exosite 1 binds the predominant _A/_A-fibrin form with low affinity. A subpopulation of fibrin molecules, _A/'-fibrin, has an extended COOH terminus '-chain that binds exosite 2 of thrombin. Bivalent binding to _A/'-fibrin increases the affinity of thrombin 10-fold, as determined by surface plasmon resonance. Because of its higher affinity, thrombin dissociates 7-fold more slowly from _A/'-fibrin clots than from _A/_A-fibrin clots. After 24 h of washing, however, both _A/'- and _A/_A-fibrin clots generate fibrinopeptide A when incubated with fibrinogen, indicating the retention of active thrombin. Previous studies demonstrated that heparin heightens the affinity of thrombin for fibrin by simultaneously binding to fibrin and exosite 2 on thrombin to generate a ternary heparin-thrombin-fibrin complex that protects thrombin from inhibition by antithrombin and heparin cofactor II. In contrast, dermatan sulfate does not promote ternary complex formation because it does not bind to fibrin. Heparin-catalyzed rates of thrombin inhibition by antithrombin were 5-fold slower in _A/'-fibrin clots than they were in _A/_A-fibrin clots. This difference reflects bivalent binding of thrombin to _A/'-fibrin because (a) it is abolished by addition of a '-chain-directed antibody that blocks exosite 2-mediated binding of thrombin to the '-chain and (b) the dermatan sulfate-catalyzed rate of thrombin inhibition by heparin cofactor II also is lower with _A/'-fibrin than with _A/_A-fibrin clots. Thus, bivalent binding of thrombin to _A/'-fibrin protects thrombin from inhibition, raising the possibility that _A/'-fibrin serves as a reservoir of active thrombin that renders thrombi thrombogenic.

	INTRODUCTION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Thrombin plays a critical role in coagulation (1). As a potent procoagulant, thrombin converts fibrinogen to fibrin, activates platelets, and amplifies its own generation by activating upstream factors (f.)² V, VIII, and XI. The procoagulant activity of thrombin is tightly regulated by inhibitors and by effector molecules that redirect the activity of thrombin. Inhibition is mediated by antithrombin in a reaction that is accelerated by glycosaminoglycans, such as heparin or heparan sulfate. Thrombomodulin is an important thrombin effector located on the endothelial cell surface. Once bound, the substrate specificity of thrombin is altered such that it no longer functions as a procoagulant but instead serves as an activator of protein C and thrombin-activable fibrinolysis inhibitor, thereby initiating anticoagulant and anti-fibrinolytic pathways, respectively. Glycoprotein (GP) 1b is another effector that functions to localize thrombin on the platelet surface, thereby promoting activation of the thrombin receptor.

The exquisite substrate specificity of thrombin and its tight regulation result, at least in part, from the presence of two positively charged exosites that flank the active site (2–4). Exosite 1 is used for docking thrombin with its substrates, orienting the reactants such that the appropriate bonds are presented to the active site for cleavage. Exosite 1 also is used in the regulation of thrombin. Thus, the NH₂ terminus of heparin cofactor II (HCII), a secondary inhibitor of thrombin, binds exosite 1 and this interaction renders HCII specific for thrombin (5). Exosite 1 also mediates thrombin binding to thrombomodulin. In contrast, exosite 2 mainly is used to tether thrombin to cells or other reactants. For example, exosite 2 mediates the binding of thrombin to GP 1b on the platelet surface or to the chondroitin sulfate moiety of thrombomodulin on the endothelial cell surface (6, 7). Heparin also utilizes exosite 2 to bind thrombin and to bridge it to antithrombin, thereby accelerating inhibition.

The interaction of thrombin-activable fibrinolysis inhibitor with fibrin is exosite-mediated (8, 9). Exosite 1 binds to the NH₂ terminus of the -or β-chains of fibrin with a K_d value of 2–4 µM (10). However, a subset of fibrin molecules binds thrombin with 10- to 20-fold higher affinity than the bulk fraction (10, 11). These fibrin molecules, which possess a variant form of the _A-chain with an extended COOH terminus that is designated ', are termed _A/' (12). Thrombin binds to this '-chain extension via exosite 2 (13, 14).

Under certain conditions, the low affinity of thrombin for homodimeric _A/_A-fibrin is enhanced. This occurs through the formation of a ternary heparin-thrombin-fibrin complex wherein thrombin binds _A/_A-fibrin via exosite 1 and heparin binds simultaneously to fibrin and to exosite 2 on thrombin, thereby bridging the thrombin to the fibrin (15, 16). Formation of this ternary heparin-thrombin-fibrin complex protects thrombin from inactivation by antithrombin and HCII. This protection reflects the inability of the serpin-bound heparin molecule to bridge to thrombin because exosite 2 is occupied by the fibrin-bound heparin (17). The extent of protection is greater for HCII than it is for antithrombin. This reflects the fact that, in addition to bridging of thrombin to HCII by heparin, the NH₂ terminus of HCII must also bind to exosite 1, which is already occupied. The phenomenon of thrombin protection when bound to fibrin may explain the limited capacity of heparin to block fibrin accretion in venous thrombosis models and the recurrent ischemic events that occur despite heparin treatment in patients with acute coronary syndromes (18, 19).

Both exosites of thrombin are engaged when the enzyme is incorporated within the ternary heparin-thrombin-fibrin complex. This bivalent binding protects thrombin from inhibition (17). Likewise, both exosites also are occupied in the high affinity interaction of thrombin with _A/'-fibrin (14). It is currently unknown whether thrombin bound to _A/'-fibrin is protected from inhibition by antithrombin and HCII. This is an important question because epidemiological studies suggest that elevated levels of _A/'-fibrinogen are a risk factor for thrombosis (20, 21). To begin to address this issue, we (a) used surface plasmon resonance to better elucidate the mode of binding of thrombin to _A/_A- and _A/'-fibrin, (b) examined the extent to which _A/_A- and _A/'-fibrin sequester thrombin and modulate its clotting activity, and (c) compared the capacity of _A/_A- and _A/'-fibrin to protect bound thrombin from inhibition by antithrombin and HCII.

	EXPERIMENTAL PROCEDURES

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Reagents—Human -thrombin, -thrombin, and plasminogen-free fibrinogen were from Enzyme Research Laboratories (South Bend, IN). Heparin, chloramine T, and ovalbumin were from Sigma; Atroxin was from Centerchem Inc. (Norwalk, CT). Antithrombin, HCII, and a sheep antibody directed against human factor XIII were from Affinity Biologicals, Inc. (Ancaster, ON). The tyrosine-phosphorylated peptide corresponding to the COOH-terminal 20 residues of the '-chain ('-peptide), VRPEHPAETEYDSLYPEDDL, and a rabbit polyclonal antibody directed against the '-peptide were prepared by Bachem Bioscience, Inc. (King of Prussia, PA). Chromozyme-thrombin (Chz-Th) (tosyl-Gly-Pro-Arg -nitroaniline acetate) was from Roche Applied Science. Dermatan sulfate (DS) was from Mediolanum Farmaceutici (Milan, Italy).

Radiolabeling—Thrombin was radiolabeled by reaction with ¹²⁵I-labeled Tyr-Pro-Arg chloromethyl ketone (YPR) (22). YPR (Bachem Bioscience, Inc.) was first radiolabeled by mixing 20 µl of 1 mg/ml YPR, 1 mCi of Na¹²⁵I (Perkin-Elmer Life Sciences) 15 µl of 4 mg/ml chloramine T, and 100 µl of phosphate-buffered saline, pH 7.4, for 90 s. The labeling reaction was terminated by incubating for a further 60 s after addition of 25 µl of 6 mg/ml sodium metabisulfite. To this reaction mixture was added 100 µl of 3.2 mg/ml thrombin. After incubation for 30 min at room temperature, ¹²⁵I-YPR-thrombin was separated from unincorporated YPR and ¹²⁵I by size exclusion chromatography on a PD-10 column (GE Healthcare) equilibrated with 20 mM Tris-HCl, 150 mM NaCl, pH 7.4 (TS). Fractions of 0.5 ml were collected, and aliquots were counted for radioactivity in a -counter. ¹²⁵I-YPR-thrombin concentration was 7.1 µM, as determined by absorbance at 280 nm (23), with a specific radioactivity of 680,000 counts/min/µg protein. D-Phe-Pro-Arg chloromethyl ketone (FPR) (EMD Chemicals, Inc., San Diego, CA) modified thrombin was prepared as described (23).

Fibrinogen Preparation—_A/'- and _A/_A-fibrinogen were isolated by fractionation of fibrinogen on a DEAE-Sepharose column (14, 24) in the presence of 10 units/ml aprotinin. About 300 mg of fibrinogen was loaded onto a 2.5 x 20-cm DEAE-FF-Sepharose column (GE Healthcare) equilibrated with 39 mM Tris-phosphoric acid, pH 8.8 (buffer A). The column was developed with a concave gradient to 50% buffer B (500 mM Tris-phosphoric acid, pH 4) followed by a linear gradient to 100% B. Chromatography was performed using a high pressure liquid chromatography system (Beckman 32 Karat; Beckman-Coulter Inc., Fullerton, CA) at a flow rate of 5 ml/min. The two fractions of fibrinogen were pooled separately and precipitated with 50% ammonium sulfate. Fibrinogen pellets were washed twice with 25% ammonium sulfate and then resuspended in TS. The _A/_A-fibrinogen pool was diluted to 10 mg/ml and applied to a sheep anti-human f.XIIIa column. The eluate was again ammonium sulfate-precipitated and dissolved in TS. Preparations were verified to be free of f.XIIIa activity by examining thrombin-clotted samples for - dimers on SDS-PAGE (25).

	MATERIALS AND METHODS

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Surface Plasmon Resonance—Fibrinogen (_A/' or _A/_A) or ovalbumin was bound to separate flow cells of a CM5 chip in a BIAcore 1000 using an amine coupling kit (BIAcore; GE Healthcare). Injection was continued until 7000 response units (RU) of fibrinogen or 2500 RU of ovalbumin was adsorbed. Flow cells were treated with 1 M ethanolamine and then washed with 20 mM Hepes-OH, pH 7.4, 150 mM NaCl (HBS) buffer containing 2 mM CaCl₂ and 0.005% Tween 20 at a flow rate of 20 µl/min. Flow cells were then treated with two injections of 300 µl of 100 nM thrombin at 5 µl/min to ensure complete conversion of fibrinogen to fibrin. Using saturating quantities of the '-peptide-directed antibody, 30% of the immobilized fibrin was determined to be in an accessible orientation. For binding studies, 20-µl aliquots of FPR-thrombin (0–5000 nM) were injected into the flow cells, followed by a 1-min wash to monitor dissociation. No regeneration of the flow cells between injections was necessary. Peak RU values (Req) were determined for each thrombin concentration and were corrected for the RU values with ovalbumin. Req values were converted to mass of FPR-thrombin, using the relation 1 pg = 1 RU (BIAtechnology Handbook; BIAcore). Moles of FPR-thrombin bound/mole of fibrin were calculated and plotted versus moles-free FPR-thrombin, and the data were analyzed by nonlinear regression of a one- or two-site rectangular hyperbola using TableCurve (Jandel Scientific, San Rafael, CA). The results are reported as means ± S.E. of two determinations.

The ability of the '-peptide to compete with -thrombin binding to _A/'-fibrin also was assessed by surface plasmon resonance. A CM5 chip with adsorbed _A/'-fibrin was prepared as described above. Aliquots of 5 µM -thrombin containing 0–25 µM '-peptide were injected, and Req values were determined.

Inhibition Kinetics—Thrombin inhibition was determined in a continuous assay by monitoring residual thrombin activity within fibrin clots. Samples containing 400 nM antithrombin or HCII, 2.7 µM _A/_A-or _A/'-fibrinogen, 400 µM Chz-Th, and 1 µg/ml heparin or 5 µg/ml DS were prepared in a multiwell plate. Clotting was initiated by the addition of 2.5 units/ml Atroxin and 2.2 nM thrombin. Atroxin was used in addition to thrombin to ensure that both forms of fibrinogen clotted at a similar and rapid rate. The reactions were monitored at 405 and 450 nm in a plate reader (Molecular Devices, Sunnyvale, CA). Clot formation occurred within 45 s. Absorbance values subsequent to this were analyzed with respect to time (t) by nonlinear regression analysis of the equation A = V_o/k₁ x (1 – e^{k1 x t}) + A_o to obtain k₁, the apparent, pseudo first-order rate constant of inhibition (26), where V_o is the initial reaction rate and A_o is the initial absorbance at 405 nm. The k₁ value was multiplied by (1 + [Chz-Th]/K_m) to correct for competition of the chromogenic substrate in the continuous assay, using a K_m of 15 µM. The apparent second-order rate constant (k_2,app) was obtained by dividing k₁ by the inhibitor concentration.

Thrombin Dissociation from Intact Fibrin Clots—Stock solutions consisting of 3 µM _A/_A-, _A/'-, or unfractionated fibrinogen in TS containing 2 mM CaCl₂, 0.005% Tween 20 (TS-TwCa), and 50,000 counts/min of ¹²⁵I-YPR-thrombin were prepared. 125-µl aliquots were added to microcentrifuge tubes, and clots were formed around truncated plastic inoculation loops (Bac-Loop; Thermo-Fisher Scientific, Waltham, MA) by incubation with 100 nM thrombin for 30 min at 37 °C. The clots were then removed from the tubes and washed three times with TS for 5 min. After quantifying radioactivity with a -counter, clots were suspended in 5 ml of TSTwCa in 50-ml conical tubes and incubated with gentle agitation for 24 h at 23 °C. A parallel series of clots were incubated in TS-TwCa containing 2 M NaCl to account for nonspecific binding. At intervals, clots were removed into 0.5 ml of the bathing buffer and the radioactivity was determined. The fraction of ¹²⁵I-YPR-thrombin remaining in the clot at each time point was calculated as a percent of the initial amount, and time courses were fit to a two-phase exponential decay curve with zero end point to determine the rates of dissociation. The two phases reflect rapid dissociation of the unbound, fluid fraction of thrombin and the slower dissociation of the fibrin-bound fraction.

The residual thrombin activity of the washed clots was determined by measuring their capacity to release fibrinopeptide A from fibrinogen. After incubation for 24 h, clots were washed twice for 5 min in TSTwCa and their radioactivity was determined. Each clot was then placed in a tube containing 500 µl of a 3-µM solution of unfractionated fibrinogen in TS-TwCa buffer and incubated at 37 °C for 30 min. At intervals, 50-µl aliquots were removed into tubes containing 150 µl of cold 100% ethanol. After vortexing, the tubes were maintained on ice until processed. Fibrinogen was pelleted by centrifugation (13,000 x g for 4 min), and the supernatants were removed and dried in a Speedvac (Thermo-Fisher Scientific) overnight. The samples were then reconstituted to their original volume with water and assayed for fibrinopeptide A by radioimmunoassay, as previously described (27).

	RESULTS

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

 
Thrombin Binding to _A/_A- and _A/'-Fibrin—To better elucidate the nature of the enhanced affinity of thrombin for _A/'-fibrin, surface plasmon resonance (SPR) was used. _A/_A-or _A/'-fibrinogen was immobilized in separate flow cells of a CM5 sensor chip. Flow cells were treated with 100 nM thrombin to convert fibrinogen to fibrin. Ovalbumin adsorbed to a separate flow cell served as a control. Successively higher concentrations of FPR--thrombin or FPR--thrombin were injected into the flow cells, followed by a dissociation step after each run. After the experiment, Req values were determined by the instrument software. Values were corrected for background signal in the ovalbumin flow cell, and the data were plotted against the input thrombin concentration (Fig. 1). Prior determination of the amount of fibrinogen adsorbed with the '-peptide-directed antibody permitted calculation of stoichiometries of interaction. The binding of -thrombin to _A/_A-fibrin occurred via a single site with a K_d of 3.4 ± 0.5 µM and a molar stoichiometry of 2.9 ± 0.5 thrombin/fibrin. This K_d value is comparable with the value of 2.3 µM obtained for binding of thrombin to intact _A/_A-fibrin clots (14). The stoichiometry likely reflects the dimeric nature of the fibrin molecule. In contrast, binding of -thrombin to immobilized _A/'-fibrin was mediated by two sites with K_d values of 11 ± 0.8 and 1100 ± 290 nM, respectively. These values are in agreement with K_d values of 100 and 1500 nM reported for the respective high and low affinity sites on intact _A/'-fibrin clots (14). The molar stoichiometry of the higher affinity site was 0.5 ± 0.1 thrombin/fibrin, whereas that of the lower affinity site was 3.4 ± 0.5. The lower stoichiometry of the higher affinity binding site may reflect the presence of only one '-chain in the _A/'-fibrin molecule.

-thrombin was used in place of -thrombin to reveal the role of exosite 1 in binding fibrin. For -thrombin binding to _A/'-fibrin, a single binding site with a K_d of 9 µM and a molar stoichiometry of 1 was observed (Fig. 1). No binding of -thrombin to _A/_A-fibrin was detected. In a subsequent experiment, a synthetic peptide analog of the COOH-terminal sequence of the '-chain abrogated binding of -thrombin to _A/'-fibrin (Fig. 2). The K_d value of the '-peptide for -thrombin determined from this experiment is 3.8 µM, comparable with the value of 1.0 µM obtained in direct binding experiments (14). These data confirm that thrombin binding to the '-chain of fibrin is mediated solely by exosite 2.

Although the binding parameters determined by SPR are comparable with those obtained in fibrin clots, fibrin on the SPR biosensor chips is likely monomeric, whereas that in intact clots is polymeric. This is relevant to the interaction of thrombin with _A/'-fibrin because it is hypothesized that the higher affinity binding results from interaction with two adjacent fibrin monomers within the protofibril (8). Fibrin monomers would not be expected to polymerize when adsorbed to the carboxydextran surface of the biosensor chip. However, the carboxydextran matrix may serve as a spacer that renders bound fibrin molecules sufficiently mobile such that thrombin can bridge individual fibrin monomers. Thrombin-mediated bridging would remain sensitive to exosite antagonists, consistent with the results obtained here. Further support for this type of interaction comes from the observation that antibodies, because of their bivalent nature, have been observed to bridge immobilized antigen in SPR experiments (28). Thus, the SPR data presented here are consistent with those observed using fibrin clots (14).

View larger version (23K): [in this window] [in a new window]   FIGURE 1. Binding of thrombin to fibrin measured using SPR. A, A/A-or A/'-fibrinogen was adsorbed to separate flow cells of a CM5 BIAcore chip to 7000 RU. As a control, ovalbumin was adsorbed to a separate flow cell. Flow cells were treated with 100 nM thrombin to convert the fibrinogen to fibrin and washed with HBS. Increasing concentrations (0–10 µM) of FPR--thrombin (FPR-IIa) were injected at a flow rate of 20 µl/min for 1 min, and the cells were then washed with HBS. The inset shows the sensorgram for FPR--thrombin titration with A/'-fibrin and ovalbumin flow cells, respectively. Peak RU values (Req), after correction for background, were determined and plotted against thrombin concentration. The data were analyzed by nonlinear regression of a two-site binding equation to determine the binding parameters (line). B, data for titration of A/A-fibrin (closed symbols) or A/'-fibrin (open symbols) with FPR--thrombin (circles) or FPR--thrombin (squares) are shown. Lines represent nonlinear regression analyses.

View larger version (12K): [in this window] [in a new window]   FIGURE 2. Effect of the '-peptide on the binding of FPR--thrombin to A/'-fibrin. A/'-fibrinogen was adsorbed to a CM5 flow cell and converted to fibrin with thrombin. Aliquots of FPR--thrombin were injected in the presence of 0–25 µM '-peptide, and the Req values were determined. After correction for background binding, values were plotted versus the '-peptide concentration. The data were analyzed by nonlinear regression (line) and yielded a Kd value of 3.8 µM for the interaction between the '-peptide and -thrombin.

View larger version (19K): [in this window] [in a new window]   FIGURE 3. Dissociation of 125I-YPR--thrombin from A/A-, A/'-, or unfractionated fibrin clots. 125 µl of 3 µM unfractionated- (circles), A/A-(squares), or A/'-(triangles) fibrinogen was clotted around plastic loops by the addition of 100 nM -thrombin and 2 mM CaCl2 in the presence of 50,000 counts/min 125I-YPR--thrombin. After washing, clots were placed in 50-ml conical tubes containing 5 ml of TSTw, and the radioactivity in the clots was determined at intervals. The fraction of 125I-YPR--thrombin remaining in the clots was calculated as a percent of the total and plotted versus time (closed symbols). Another series of clots was incubated in the presence of 2 M NaCl to account for nonspecific binding (open symbols). Lines represent nonlinear regression analysis of the data by two-component exponential decay. Data represent the mean and standard error of three experiments.

View larger version (16K): [in this window] [in a new window]   FIGURE 4. Fibrinogen-cleaving activity of thrombin bound to fibrin clots. The ability of fibrin-bound thrombin to release fibrinopeptide A (FPA) from fibrinogen was assessed using unfractionated (circles), A/A-(squares), or A/'-(triangles) fibrin clots, generated as described in the legend to Fig. 3. After 24 h of washing in TSTw buffer in the absence (closed symbols) or presence (open symbols) of 2 M NaCl, retained thrombin activity was quantified. Clots were incubated in buffer containing 3 µM A/A-fibrinogen for 30 min. At intervals, aliquots were removed, unreacted fibrinogen was precipitated with ethanol, and fibrinopeptide A was quantified by radioimmunoassay. Fibrinopeptide A levels are plotted versus time of incubation with fibrinogen. Data represent the mean and standard error of three experiments.

Protection of Thrombin from Inhibition by Binding to _A/'-Fibrin—Fibrin-bound thrombin is resistant to heparin-catalyzed inactivation by antithrombin and HCII (16, 30). Protection is a consequence of formation of the ternary complex in which fibrin-bound heparin binds exosite 2 and impairs the ability of antithrombin-bound heparin to bridge to thrombin. Because the '-chain also occupies exosite 2 with high affinity, we hypothesized that thrombin bound to _A/'-fibrin would demonstrate greater protection from inhibition by antithrombin or HCII than thrombin bound to _A/_A-fibrin. Inhibition experiments were done using clots prepared from the two forms of fibrinogen. Clotting was initiated with Atroxin to ensure a uniform rate of clot formation. Control experiments verified that thrombin binds comparably to clots prepared with Atroxin as it does to those made with thrombin (not shown). The residual chromogenic activity of 2.2 nM thrombin against Chz-Th was monitored continuously and used to calculate the apparent second-order rate constant of inhibition under pseudo-first-order conditions. The apparent heparin-catalyzed rate of thrombin inhibition by antithrombin was 1.1 x 10⁸ M^–1min^–1 in the absence of fibrin (Fig. 5A), which is comparable with the rate of 3.0 x 10⁸ M^–1min^–1 obtained using a discontinuous inhibition assay (16). In the presence of _A/_A-fibrin, the rate was reduced 11-fold, confirming the protection observed previously. In the presence of _A/'-fibrin, the rate of inhibition was reduced 55-fold, revealing 5-fold greater protection than that afforded by _A/_A-fibrin. The experiment was repeated in the presence of the '-peptide-directed antibody that reduces thrombin binding to _A/'-fibrin to that obtained with _A/_A-fibrin. In the presence of the antibody, the rate of inhibition with _A/'-fibrin was similar to that with _A/_A-fibrin. Thus, the additional interaction of thrombin with the '-chain affords thrombin more protection from inhibition by the heparin-antithrombin complex. Similar results in the presence of heparin were obtained when HCII was substituted for antithrombin (not shown).

Interpretation of these results could be compromised by the fact that in _A/'-fibrin clots thrombin still has the capacity to form a ternary heparin-thrombin-fibrin complex that could compete with the '-chain for thrombin exosite 2 binding. To address this possibility, the experiment was repeated using DS and HCII in place of heparin plus antithrombin. Although DS binds weakly to exosite 2, it does not bind to fibrin. Consequently, DS does not promote ternary complex formation (31). The DS-catalyzed rate of thrombin inhibition by HCII in the absence of fibrin was 1.3 x 10⁸ M^–1min^–1 (Fig. 5B). In the presence of _A/_A-fibrin, the rate decreased 5-fold. A 27-fold lower rate was observed with _A/'-fibrin clots. This reduced rate was abrogated when the '-peptide-directed antibody was added. Thus, _A/'-fibrin affords thrombin greater protection from inhibition by either antithrombin or HCII than does _A/_A-fibrin. Furthermore, the enhanced protection with _A/'-fibrin is independent of formation of the ternary heparin-thrombin-fibrin complex.

View larger version (14K): [in this window] [in a new window]   FIGURE 5. Protection of thrombin bound to A/A-or A/'-fibrin clots from inhibition by antithrombin or HCII. A, clots were prepared in a multiwell plate by clotting 2.7 µM A/A-or A/'-fibrinogen with 2.2 nM thrombin and 2.5 units/ml Atroxin in the presence of 2 mM CaCl2, 400 nM antithrombin, 400 µM Chz-Th, and 1 µg/ml heparin. The absorbance at 405 nm was read continuously in a platereader. To allow for clot formation, absorbance values during the first 45 s were omitted from the analyses. Absorbance values were plotted against time and analyzed by nonlinear regression to obtain the apparent, second-order inhibition rate constant. The extent of protection was calculated by dividing the rates of inhibition in the absence of fibrin with those determined in the presence of fibrin. Experiments were performed in the absence or presence of a polyclonal antibody against the '-peptide ('-Ab). B, experiments were repeated using 400 nM HCII and 5 µg/ml DS in place of antithrombin and heparin. Data represent the mean and standard error of two experiments.

	DISCUSSION

TOP ABSTRACT INTRODUCTION EXPERIMENTAL PROCEDURES MATERIALS AND METHODS RESULTS DISCUSSION REFERENCES

Previous work suggested that the mechanism by which thrombin within the ternary heparin-thrombin-fibrin complex is protected from inhibition reflects the inability of antithrombin-bound heparin to access exosite 2 of thrombin, thereby precluding essential bridging of enzyme and inhibitor by heparin (16). In the current study, we observed that both exosites of thrombin are ligated when bound to _A/'-fibrin and that the resultant protection exceeds that provided by _A/_A-fibrin clots. This conclusion was validated in two ways. First, the addition of a '-peptide-directed antibody reduced the extent of protection of thrombin from inhibition by the heparin-antithrombin complex afforded by _A/'-fibrin clots to a level similar to that of _A/_A-fibrin clots. These results demonstrate that the enhanced protection of thrombin provided by _A/'-fibrin reflects the presence of the '-sequence. Second, the enhanced protection of thrombin by _A/'-fibrin is not the result of increased formation of the ternary heparin-thrombin-fibrin complex, because _A/'-fibrin clots still afford thrombin more protection from inhibition by HCII than _A/_A-fibrin clots when heparin is replaced with DS, a glycosaminoglycan that does not bind fibrin. These results confirm that the protection of thrombin from inhibition by the heparin-antithrombin or heparin-HCII complex that occurs either by formation of the ternary heparin-thrombin-fibrin complex on _A/_A-fibrin or via bivalent binding of thrombin to _A/'-fibrin reflects impaired access of catalytic heparin, bound to antithrombin or to HCII, to exosite 2 on thrombin (8).

As a consequence of its higher affinity for _A/'-fibrin, more thrombin is sequestered in _A/'-fibrin clots than in _A/_A-fibrin clots. Thus, _A/'-fibrin clots may serve as a reservoir of active thrombin, which could render these clots thrombogenic. Such a phenomenon could explain the observed correlation between elevated levels of _A/'-fibrinogen and coronary artery disease (20). Recently, this correlation has been questioned (32, 33). It has been suggested, in fact, that _A/'-fibrin may play an anticoagulant role by sequestering thrombin and limiting its capacity to participate in coagulation or to activate platelets (33, 34). The fibrinopeptide A-generating activity of thrombin in washed fibrin clots was examined to verify that clot-associated thrombin retained coagulant activity. The activity of thrombin associated with _A/'-fibrin clots was comparable with that bound to _A/_A-fibrin clots, despite the fact that _A/'-fibrin clots contained more thrombin. Therefore, thrombin associated with both forms of fibrin clots retains catalytic activity, although that associated with _A/'-fibrin has reduced activity compared with that associated with _A/_A-fibrin. These findings are consistent with the observation that thrombin-induced fibrinopeptide release from _A/'-fibrinogen is slower than that from _A/_A-fibrinogen (35). Although these data support the concept that _A/'-fibrin plays an anticoagulant role as antithrombin I, this may be countered by the fact that _A/'-fibrin clots endow thrombin with a survival advantage that prolongs its procoagulant activity. Such a concept is supported by the observations that (a) clot-associated thrombin retains clotting activity in plasma, even in the presence of heparin (27), and (b) venous and arterial thrombi collected from autopsy specimens harbor active thrombin that can be inhibited with hirudin (36). Taken together, these findings support the concept that fibrin-bound thrombin contributes to the thrombogenic potential of thrombi (27, 37).

In addition to activation of platelets and upstream coagulation factors, another potential consequence of enhanced binding of thrombin to _A/'-fibrinogen is alteration of fibrin structure. Fibers formed from _A/'-fibrinogen are thinner and display greater branching than those formed from _A/_A-or unfractionated fibrinogen (35, 38). In addition to thrombin, _A/'-fibrin also binds f.XIII with higher affinity than _A/_A-fibrin (24), which may impair cross-linking (35). Enhanced binding of thrombin and f.XIII may explain why clots prepared from _A/'-fibrinogen differ from those formed from _A/_A-fibrinogen. Altered clot structure may thus render _A/'-fibrin clots more resistant to fibrinolysis (35, 39). Therefore, enhanced binding of thrombin represents only one mechanism by which the level of _A/'-fibrinogen may influence the risk of thrombosis.

Crystallographic studies have revealed the nature of individual interactions at exosites 1 and 2 with fibrinogen fragment E and the '-peptide, respectively (40, 41). When thrombin is bound to _A/'-fibrin, both of its exosites are ligated simultaneously. Similar bivalent binding of thrombin occurs when it interacts with chondroitin sulfate-containing thrombomodulin, bothrojaracin, HCII, or GP1b. Dual exosite occupation likely represents a mechanism by which the affinity of thrombin binding can be heightened and thrombin activity can be modulated. Thrombomodulin redirects the focus of thrombin to anticoagulation by providing a nascent substrate binding site for protein C or to attenuation of fibrinolysis by promoting thrombin-activable fibrinolysis inhibitor activation (42). Bothrojaracin is a high affinity thrombin inhibitor found in Bothrops venom that binds both exosites (43). HCII uses a double bridging mechanism to achieve effective rates of inhibition, binding exosite 1 via its NH₂-terminal tail and exosite 2 via heparin (31). GP Ib utilizes exosite 2 to tether thrombin to platelets, orienting it such that it can effectively activate the thrombin receptor (6). Furthermore, crystallographic studies demonstrate that GP 1b can interact with both exosites of thrombin (44, 45). Fibrin, either via _A/'-fibrin alone, or via _A/_A-fibrin with heparin, protects thrombin from inactivation by the heparin-antithrombin or heparin-HCII complex. All of these examples represent efforts to uniquely modulate thrombin activity in various environments. Interactions that utilize both exosites serve to retain and restrain thrombin activity subsequent to coagulation. In contrast, most procoagulant activities of thrombin, such as activation of f.V, f.VIII, and fibrinogen, typically involve only exosite 1. Ligation of a single exosite results in a lower affinity interaction that permits efficient substrate turnover. These observations demonstrate that selective utilization of exosites by substrates and ligands plays an important role in regulating thrombin activity in hemostasis (46).

	FOOTNOTES

 
^* This work was supported in part by Canadian Institutes of Health Research Grants MOP 3992 and CTP 79846, Heart and Stroke Foundation of Ontario Grants T4729 and T4730, and funds from the Ontario Research and Development Challenge Fund. The costs of publication of this article were defrayed in part by the payment of page charges. This article must therefore be hereby marked "advertisement" in accordance with 18 U.S.C. Section 1734 solely to indicate this fact.

¹ Recipient of a Career Investigator Award from the Heart and Stroke Foundation of Ontario, Heart and Stroke Foundation of Ontario/J. Fraser Mustard Endowed Chair in Cardiovascular Research, and Canada Research Chair (Tier 1) in Thrombosis. To whom correspondence should be addressed: 711 Concession St., Hamilton, Ontario L8V 1C3, Canada. Tel.: 905-574-8770; Fax: 905-575-2646; E-mail: jweitz{at}thrombosis.hhscr.org.

² The abbreviations used are: f., factor; Chz, chromozyme; DS, dermatan sulfate; FPR, D-Phe-Pro-Arg; GP, glycoprotein; HCII, heparin cofactor II; IIa, thrombin; RU, response unit; Req, RU equilibrium; SPR, surface plasmon resonance; t, half time of dissociation; YPR, D-Tyr-Pro-Arg.

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