The active site of antithrombin. Release of the same proteolytically cleaved form of the inhibitor from complexes with factor IXa, factor Xa, and thrombin

Reactions between near equimolar amounts of antithrombin and Factors IXa or Xa resulted in the formation of a free proteolytically modified, two-chain form of the inhibitor, in addition to the inactive antithrombin-protease complexes. The modified inhibitor produced by either enzyme was electrophoretically identical with that formed in the reaction with thrombin. As in the latter reaction, the formation of the modified antithrombin by Factor Xa was increased in the presence of heparin, while only small amounts were produced by Factor IXa both in the absence and presence of the polysaccharide. NH2-terminal sequence analyses of the isolated modified inhibitor formed by Factor Xa showed that a single Arg-Ser bond in the COOH-terminal end of the inhibitor had been cleaved. This cleavage site is identical with that identified in free thrombin-modified antithrombin. The purified antithrombin-Factor IXa and antithrombin-Factor Xa complexes were dissociated by ammonia or hydroxylamine into free enzyme and a modified two-chain form of the inhibitor. Electrophoresis studies and NH2-terminal sequence analyses showed that the modified antithrombin obtained from either complex was identical with that produced in free form by the two enzymes and also with the modified inhibitor that is released from the antithrombin-thrombin complex. The fact that identical results were obtained for the reactions between antithrombin and three enzymes with different specificities strongly suggests that the observed Arg-Ser cleavage site is the active site of antithrombin.     

Measurement of the kinetics of inhibition of activated coagulation factor X in human plasma: the effect of plasma and inhibitor concentration

A method has been developed for detailed kinetic studies of the inhibition of factor Xa in human plasma. Radiolabeled enzyme is not required, and the method can be used at initial factor Xa levels of 1 nM. The method is discontinuous and based on the removal of samples into an amidolytic assay done in the presence of 1% Lubrol-PX detergent. This permits the study of inhibition in mixtures containing phospholipid, platelets, or thromboplastin. The method can be used at inhibition rates in excess of 1 min-1, and by suitable analysis can be used to estimate the contribution of inhibition by alpha 2-macroglobulin, which does not itself inhibit amidolytic activity. The method is at present limited to cases where thrombin is not generated in large excess. Factor Xa inhibition has been studied in citrated plasma as a function of total plasma concentration, and--by the use of antithrombin-depleted plasma--as a function of the antithrombin concentration of the plasma. In all situations inhibition is characterized by second-order behavior: (i) total inhibition rate is proportional to plasma concentration up to 95%, giving a maximum rate in the absence of calcium of 1 min-1; (ii) inhibition in depleted plasma reconstituted with antithrombin shows inhibition rate to remain linearly related to antithrombin concentration; and (iii) the estimated rate due to alpha 2-macroglobulin is proportional to plasma concentration. It is thus confirmed that, as in pure systems, inhibition of factor Xa in whole plasma is linearly related to the concentration of each class of inhibitor.     

Thrombin generation and inactivation in the presence of antithrombin III and heparin

We have determined the rate constants of inactivation of factor Xa and thrombin by antithrombin III/heparin during the process of prothrombin activation. The second-order rate constant of inhibition of factor Xa alone by antithrombin III as determined by using the synthetic peptide substrate S-2337 was found to be 1.1 X 10(6) M-1 min-1. Factor Xa in prothrombin activation mixtures that contained prothrombin, and either saturating amounts of factor Va or phospholipid (20 mol % dioleoylphosphatidylserine/80 mol % dioleoylphosphatidylcholine, 10 microM), was inhibited by antithrombin III with a second-order rate constant that was essentially the same: 1.2 X 10(6) M-1 min-1. When both factor Va and phospholipid were present during prothrombin activation, factor Xa inhibition by antithrombin III was reduced about 10-fold, with a second-order rate constant of 1.3 X 10(5) M-1 min-1. Factor Xa in the prothrombin activation mixture that contained both factor Va and phospholipid was even more protected from inhibition by the antithrombin III-heparin complex. The first-order rate constants of these reactions at 200 nM antithrombin III and normalized to heparin at 1 microgram/mL were 0.33 and 9.5 min-1 in the presence and absence of factor Va and phospholipid, respectively. When the prothrombin concentration was varied widely around the Km for prothrombin, this had no effect on the first-order rate constants of inhibition. It is our conclusion that factor Xa when acting in prothrombinase on prothrombin is profoundly protected from inhibition by antithrombin III in the absence as well as in the presence of heparin.(ABSTRACT TRUNCATED AT 250 WORDS)     

The COOH-terminal domain of hirudin. An exosite-directed competitive inhibitor of the action of alpha-thrombin on fibrinogen

Hirudin, a potent 65-residue polypeptide inhibitor of alpha-thrombin found in the saliva of the leech Hirudo medicinalis, and fragments thereof are potentially useful as antithrombotic agents. Hirugen, the synthetic N-acetylated COOH-terminal dodecapeptide (Ac-Asn-Gly-Asp-Phe-Glu-Glu-Ile-Pro-Glu-Glu-Tyr(SO3)-Leu) of hirudin was shown in the present study to behave as a pure competitive inhibitor (Ki = 0.54 microM) of human alpha-thrombin-catalyzed release of fibrinopeptide A from human fibrinogen. In contrast to this inhibitory activity, hirugen slightly enhanced (increased kcat/Km 1.6-fold) alpha-thrombin-catalyzed hydrolysis of the fluorogenic tripeptide substrate N-p-Tosyl-Gly-Pro-Arg-7-amino-4-methylcoumarin. These observations indicate that hirugen binds to alpha-thrombin at an exosite distinct from the active site, and that interaction with this exosite is a major determinant of the competence of alpha-thrombin to bind fibrinogen. Consistent with this view, hirugen blocked binding of fibrin II to alpha-thrombin. Studies of the effect of hirugen on the rate of inactivation of alpha-thrombin by antithrombin III (AT), the major plasma inhibitor of alpha-thrombin, indicated that binding of hirugen to alpha-thrombin results in less than a 2.5-fold decrease in the rate of inactivation of alpha-thrombin by AT, both in the absence and presence of heparin. This behavior is distinct from that of active site-directed competitive inhibitors of alpha-thrombin which bind to alpha-thrombin and block both conversion of fibrinogen to fibrin and inactivation of alpha-thrombin by AT. Hirugen, an exosite-directed competitive inhibitor, blocks the interaction of alpha-thrombin with fibrinogen while leaving alpha-thrombin competent to react with AT. Thus, unlike active site-directed competitive inhibitors, hirugen should act in concert with AT and heparin to reduce the amount of fibrinogen that is processed during the lifetime of alpha-thrombin in plasma.     

Reactive site peptide structural similarity between heparin cofactor II and antithrombin III

Heparin cofactor II (Mr = 65,600) was purified 1800-fold from human plasma to further characterize the structural and functional properties of the protein as they compare to antithrombin III (Mr = 56,600). Heparin cofactor II and antithrombin III are functionally similar in that both proteins have been shown to inhibit thrombin at accelerated rates in the presence of heparin. There was little evidence for structural homology between heparin cofactor II and antithrombin III when high performance liquid chromatography-tryptic peptide maps and NH2-terminal sequences were compared. A partially degraded form of heparin cofactor II was also obtained in which a significant portion (Mr = 8,000) of the NH2 terminus was missing. The rates of thrombin inhibition (+/- heparin) by native and partially degraded-heparin cofactor II were not significantly different, suggesting that the NH2-terminal region of the protein is not essential either for heparin binding or for thrombin inhibition. A significant degree of similarity was found in the COOH-terminal regions of the proteins when the primary structures of the reactive site peptides, i.e. the peptides which are COOH-terminal to the reactive site peptide bonds cleaved by thrombin, were compared. Of the 36 residues identified, 19 residues in the reactive site peptide sequence of heparin cofactor II could be aligned with residues in the reactive site peptide from antithrombin III. While the similarities in primary structure suggest that heparin cofactor II may be an additional member of the superfamily of proteins consisting of antithrombin III, alpha 1-antitrypsin, alpha 1-antichymotrypsin and ovalbumin, the differences in structure could account for differences in protease specificity and reactivity toward thrombin. In particular, a disulfide bond which links the COOH-terminal (reactive site) region of antithrombin III to the remainder of the molecule and is important for the heparin-induced conformational change in the protein and high affinity binding of heparin does not appear to exist in heparin cofactor II. This observation provides an initial indication that while the reported kinetic mechanisms of action of heparin in accelerating the heparin cofactor II/thrombin and antithrombin III/thrombin reactions are similar, the mechanisms and effects of heparin binding to the two inhibitors may be different.     

Effects of PGI2 on the inactivation of thrombin, factor Xa, and plasmin by antithrombin-III and heparin.

The influence of PGI2 on the activity and on the inactivation of enzymes participating in blood coagulation (thrombin and Factor Xa) and fibrinolysis (plasmin) were investigated. According to the results PGI2 has no effect on the activity of Factor Xa and plasmin nor on the inactivation of these enzymes by antithrombin-III in the absence and presence of heparin at a concentration of PGI2 up to 400 micrograms/ml. An acceleration of the inactivation of thrombin by antithormbin-III was found in the presence of PGI2 within a concentration of 100-400 micrograms/ml without any effect on the heparin-accelerated inactivation of thrombin by antithrombin. We got similar results using clotting tests for the assay and the application of synthetic substrate for thrombin. This inactivation-accelerating effect of PGI2 on thrombin was only demonstratable at a concentration five magnitudes higher than that of the anti-aggregation effect on platelets.     

Evidence for a plasma inhibitor of the heparin accelerated inhibition of factor Xa by antithrombin III.

The ability of heparin fractions of different molecular weight to potentiate the action of antithrombin III against the coagulation factors thrombin and Xa has been examined in purified reaction mixtures and in plasma. Residual thrombin and Xa have been determined by their peptidase activities against the synthetic peptide substrates H-D-Phe-Pip-Arg-pNA and Bz-Ile-Gly-Arg-pNA. High molecular weight heparin fractions were found to have higher anticoagulant activities than low molecular weight heparin when studied with both thrombin and Xa incubation mixtures in purified mixtures and in plasma. The inhibition of thrombin by heparin fractions and antithrombin III was unaffected by other plasma components. However, normal human plasma contained a component that inhibited the heparin and antithrombin III inhibition of Xa particularly when the high molecular weight heparin fraction was used. Experiments using a purified preparation of platelet factor 4 suggested that the platelet-derived heparin-neutralizing protein was not responsible for the inhibition.     

The effect of Ca2+, phospholipid and factor V on the anti-(factor Xa) activity of heparin and its high-affinity oligosaccharides.

The influence of Ca2+, phospholipid and Factor V was determined on the rate of inactivation of Factor Xa by antithrombin III, in the absence and in the presence of unfractionated heparin and of three high-affinity heparin oligosaccharides in the Mr range 1500-6000. In the absence of heparin the addition of Ca2+, phospholipid and Factor V caused a 4-fold decrease in rate of inactivation of Factor Xa. As concentrations of unfractionated heparin were increased the protective effect of Ca2+/phospholipid/Factor V was gradually abolished, and at a concentration of 2.4 nM there were no differences in rates of neutralization of Factor Xa in the presence or absence of Ca2+, phospholipid and Factor V. In contrast, heparin decasaccharide (Mr 3000) and pentasaccharide (Mr 1500) fragments were unable to overcome the protective effect of Ca2+/phospholipid/Factor V; in the presence of these components their catalytic efficiencies were 16-fold and 40-fold less respectively than that of unfractionated heparin. A heparin 20-22-saccharide fragment (Mr approx. 6000) gave similar inactivation rates in the presence and in the absence of Ca2+/phospholipid/Factor V. Human and bovine Factor Xa gave similar results. These results indicate that in the presence of Ca2+/phospholipid/Factor V optimum inhibition of Factor Xa requires a saccharide sequence of heparin additional to that involved in binding to antithrombin III. The use of free enzyme for the assessment of anti-(Factor Xa) activity of low-Mr heparin fractions could give misleading results.     

C-terminal residues 621-635 of protein S are essential for binding to factor Va

Protein S is anticoagulant in the absence of activated protein C because of direct interactions with coagulation Factors Xa and Va. Synthetic peptides corresponding to amino acid sequences of protein S were tested for their ability to inhibit prothrombinase activity. The peptide containing the C-terminal sequence of protein S, residues 621-635 (PSP14), reversibly inhibited prothrombinase activity in the presence but not in the absence of Factor Va (K(i) approximately 2 microM). PSP14 inhibition of prothrombinase was independent of phospholipids but could be competitively overcome by increasing Factor Xa concentrations, suggesting that the C-terminal region of protein S may compete for a Factor Xa binding site on Factor Va. Studies using peptides with amino acid substitutions suggested that lysines 630, 631, and 633 were critical residues. PSP14 inhibited Factor Va activity in Factor Xa-one-stage clotting assays. PSP14 inhibited protein S binding to immobilized Factor Va. When preincubated with protein S, antibodies raised against PSP14 inhibited binding of protein S to Factor Va and blocked inhibition of prothrombinase activity by protein S. These results show that the C-terminal region of protein S containing residues 621-635 is essential for binding of protein S to Factor Va and that this interaction contributes to anticoagulant action.     

The effects of phospholipid and factor Va on the inhibition of factor Xa by antithrombin III

The rate of inhibition of Factor Xa by antithrombin III was found to be influenced by either phospholipid or Factor Va combined with phospholipid. Our results confirmed that Factor Va and phospholipid could protect Factor Xa from inhibition. However, when antithrombin III levels were extrapolated to infinity, the protective effect of lipid and Factor Va were eliminated and the rate of inhibition was accelerated. This indicated that the protective effect that was observed at low antithrombin III concentrations in the presence of phospholipid and Factor Va was due to inhibition of binding of the inhibitor to Factor Xa.     

The effect of prothrombin fragment 2 on the inhibition of thrombin by antithrombin III.

The effect of prothrombin fragment 2 on the inhibition of thrombin by antithrombin III has been studied. Fragment 2 was found to slow the rate of inhibition of thrombin by antithrombin III about 3-fold. The effect of prothrombin fragment 2 on antithrombin III inhibition was examined by comparing its action in the presence of either thrombin or meizothrombin (des fragment 1). The second order rate constants for antithrombin III inhibition of thrombin with saturating fragment 2 and antithrombin III inhibition of meizothrombin (des fragment 1) were the same. Prothrombin fragment 2 had no effect on either antithrombin III inhibition of meizothrombin (des fragment 1) or Factor Xa. The effect of the fragment on the reaction mechanism of thrombin inhibition was evaluated to see if the fragment altered binding of antithrombin III to thrombin or inhibited the formation of the covalent complex. The fragment was found to have no inhibitory effect on the rate of covalent complex formation, indicating that the protective effect of the fragment is by inhibiting binding of antithrombin III to thrombin. These data suggest that prothrombin fragment 2 may be an important factor in controlling the localization of clot formation by regulating the interaction between thrombin and antithrombin III.     

A prothrombinase complex of mouse peritoneal macrophages

Addition of prothrombin to mouse peritoneal macrophages in vitro resulted in the formation of a thrombin-like enzyme, as demonstrated by use of the luminogenic peptide substrate S-2621. The prothrombinase activity was sedimented by high-speed centrifugation following homogenization of the cells and was abolished by treatment of the cells with the nonionic detergent Triton X-100 at 0.02% concentration. Moreover, the activity was drastically reduced by maintaining cultures in the presence of warfarin and, presumably due to competitive substrate inhibition, by adding S-2222, a chromogenic peptide substrate for Factor Xa. These findings suggest that prothrombin cleavage is catalyzed by Factor Xa at the macrophage surface. The generated thrombin was inhibited by antithrombin, and this reaction was accelerated by heparin with high affinity for antithrombin but not by the corresponding oligosaccharides composed of 8-14 monosaccharide units. Such oligosaccharides which are capable of accelerating the inactivation of Factor Xa by antithrombin, inhibited thrombin formation from prothrombin in the macrophage cultures, presumably by promoting inactivation by antithrombin of Factor Xa in a prothrombinase complex. Activation of the macrophage coagulation system, as proposed to occur in certain inflammatory conditions, thus may be modulated at various levels by heparin, or heparin oligosaccharides, released from mast cells.     

Probing the molecular basis of factor Xa specificity by mutagenesis of the serpin, antithrombin.

The molecular basis of the substrate and inhibitor specificity of factor Xa, the serine proteinase of the prothrombinase complex, was investigated by constructing two mutants of human antithrombin (HAT) in which the reactive site loop of the serpin from the P4-P4' site was replaced with the corresponding residues of the two factor Xa cleavage sites in prothrombin (HAT/Proth-1 and HAT/Proth-2). These mutants together with prethrombin-2, the smallest zymogen form of thrombin containing only the second factor Xa cleavage site, were expressed in mammalian cells, purified to homogeneity and characterized in kinetic reactions with factor Xa in both the absence and presence of cofactors; factor Va, high affinity heparin and pentasaccharide fragment of heparin. HAT/Proth-1 inactivated factor Xa approximately 3-4-fold better than HAT/Proth-2 in either the absence or presence of heparin cofactors. In the absence of a cofactor, factor Xa reacted with the HAT/Proth-2 and prethrombin-2 with similar second-order rate constants (approximately 2-3x10(2) M(-1)s(-1)). Pentasaccharide catalyzed the inactivation rate of factor Xa by the HAT mutants 300-500-fold. A similar 10(4)-10(5)-fold enhancement in the reactivity of factor Xa with prethrombin-2 and the HAT mutants was observed in the presence of the cofactors Va and heparin, respectively. Factor Va did not influence the reactivity of factor Xa with either one of the HAT mutants. These results suggest that (1) in the absence of a cofactor, the P4-P4' residues of HAT and prethrombin-2 primarily determine the specificity reactions with factor Xa, (2) factor Va binding to factor Xa is not associated with allosteric changes in the catalytic pocket of enzyme that would involve interactions with the P4-P4' binding sites, and (3) similar to allosteric activation of HAT by heparin, a role for factor Va in the prothrombinase complex may involve rearrangement of the residues surrounding the scissile bond of the substrate to facilitate its optimal docking into the catalytic pocket of factor Xa.     

Effects of PGI2 on the inactivation of thrombin,factor Xa,and plasmin by antithrombin-III and hepartin

The influence of PGI₂ on the activity and on the inactivation of enzymes participating in blood coagulation /thrombin and Factor Xa/ and fibrinolysis /plasmin/ were investigated. According to the results PGI₂ has no effect on the activity of Factor Xa and plasmin nor on the inactivation of these enzymes by antithrombin-III in the absence and presence of heparin at a concentration of PGI₂ up to 400 μg/ml. An acceleration of the inactivation of thrombin by antithrombin-III was found in the presence of PGI₂ within a concentration of 100–400 μg/ml without any effect on the heparin-accelerated inactivation of thrombin by antithrombin. We got similar results using clotting tests for the assay and the application of synthetic substrate for thrombin. This inactivation-accelerating effect of PGI₂ on thrombin was only demonstratable at a concentration five magnitudes higher than that of the anti-aggregation effect on platelets.     

Anticoagulant activities of heparin oligosaccharides and their neutralization by platelet factor 4.

Oligosaccharides of well-defined molecular size were prepared from heparin by nitrous acid depolymerization, affinity chromatography on immobilized antithrombin III (see footnote on Nomenclature) and gel chromatography on Sephadex G-50. High affinity (for antithrombin III) octa-, deca-, dodeca-, tetradeca-, hexadeca- and octadeca-saccharides were prepared, as well as oligosaccharides of larger size than octadecasaccharide. The inhibition of Factor Xa by antithrombin III was greatly accelerated by all of these oligosaccharides, the specific anti-Factor Xa activity being invariably greater than 1300 units/mumol. The anti-Factor Xa activity of the decasaccharide was not significantly decreased in the presence of platelet factor 4, even at high platelet factor 4/oligosaccharide ratios. Measurable but incomplete neutralization of the anti-Factor Xa activities of the tetradeca- and hexadeca-saccharides was observed, and complete neutralization of octadeca- and larger oligo-saccharides was achieved with excess platelet factor 4. The octa-, deca-, dodeca-, tetradeca- and hexadeca-saccharides had negligible effect on the inhibition of thrombin by antithrombin III, whereas specific anti-thrombin activity was expressed by the octadeca-saccharide and by the larger oligosaccharides. An octadecasaccharide is therefore the smallest heparin fragment (prepared by nitrous acid depolymerization) that can accelerate thrombin inhibition by antithrombin III. The anti-thrombin activities of the octadecasaccharide and larger oligosaccharides were more readily neutralized by platelet factor 4 than were their anti-Factor Xa activities. These findings are compatible with two alternative mechanisms for the action of platelet factor 4, both involving the binding of the protein molecule adjacent to the antithrombin III-binding site. Such binding results in either steric interference with the formation of antithrombin III-proteinase complexes or in displacement of the antithrombin III molecule from the heparin chain.     

Interaction of factor Xa with heparin does not contribute to the inhibition of factor Xa by antithrombin III-heparin

Factor Xa modified by reductive methylation (greater than 92%) loses the capacity to bind heparin as determined both by gel chromatography and by sedimentation equilibrium ultracentrifugation. The kinetic properties of methylated factor Xa differ, with respect to KM and Vmax for a synthetic tripeptide substrate and for antithrombin III inhibition rate constants, from those of the unmodified enzyme. The 10,000-fold rate enhancement elicited by the addition of heparin to the antithrombin III inhibition reaction, however, is the same. The observed second-order rate constants (k"obs) for antithrombin III inhibition of factor Xa and methylated factor Xa are 3000 and 340 M-1 s-1, respectively, whereas k"obs values for the inhibition of factor Xa or methylated factor Xa with antithrombin III-heparin are 4 X 10(7) and 3 X 10(6) M-1 s-1, respectively. These findings provide direct evidence that the interaction of factor Xa with heparin is not involved in the heparin-enhanced inhibition of this enzyme.     

Localization of an antithrombin exosite that promotes rapid inhibition of factors Xa and IXa dependent on heparin activation of the serpin

We have previously shown that exosites in antithrombin outside the P6-P3' reactive loop region become available upon heparin activation to promote rapid inhibition of the target proteases, factor Xa and factor IXa. To identify these exosites, we prepared six antithrombin-alpha 1-proteinase inhibitor chimeras in which antithrombin residues 224-286 and 310-322 that circumscribe a region surrounding the reactive loop on the inhibitor surface were replaced in 10-16-residue segments with the homologous segments of alpha1-proteinase inhibitor. All chimeras bound heparin with a high affinity similar to wild-type, underwent heparin-induced fluorescence changes indicative of normal conformational activation, and were able to form SDS-stable complexes with thrombin, factor Xa, and factor IXa and inhibit these proteases with stoichiometries minimally altered from those of wild-type antithrombin. With only one exception, conformational activation of the chimeras with a heparin pentasaccharide resulted in normal approximately 100-300-fold enhancements in reactivity with factor Xa and factor IXa. The exception was the chimera in which residues 246-258 were replaced, corresponding to strand 3 of beta-sheet C, which showed little or no enhancement of its reactivity with these proteases following pentasaccharide activation. By contrast, all chimeras including the strand 3C chimera showed essentially wild-type reactivities with thrombin after pentasaccharide activation as well as normal full-length heparin enhancements in reactivity with all proteases due to heparin bridging. These findings suggest that antithrombin exosites responsible for enhancing the rates of factor Xa and factor IXa inhibition in the conformationally activated inhibitor lie in strand 3 of beta-sheet C of the serpin.     

Interactions and inhibition of blood coagulation factor Va involving residues 311-325 of activated protein C.

Activated protein C (APC) exerts its physiologic anticoagulant role by proteolytic inactivation of the blood coagulation cofactors Va and VIIIa. The synthetic peptide-(311-325) (KRNRTFVLNFIKIPV), derived from the heavy chain sequence of APC, potently inhibited APC anticoagulant activity in activated partial thromboplastin time (APTT) and Xa-1-stage coagulation assays in normal and in protein S-depleted plasma with 50% inhibition at 13 microM peptide. In a system using purified clotting factors, peptide-(311-325) inhibited APC-catalyzed inactivation of factor Va in the presence or absence of phospholipids with 50% inhibition at 6 microM peptide. However, peptide-(311-325) had no effect on APC amidolytic activity or on the reaction of APC with the serpin, recombinant [Arg358]alpha 1-antitrypsin. Peptide-(311-325) surprisingly inhibited factor Xa clotting activity in normal plasma, and in a purified system it inhibited prothrombinase activity in the presence but not in the absence of factor Va with 50% inhibition at 8 microM peptide. The peptide had no significant effect on factor Xa or thrombin amidolytic activity and no effect on the clotting of purified fibrinogen by thrombin, suggesting it does not directly inhibit these enzymes. Factor Va bound in a dose-dependent manner to immobilized peptide-(311-325). Peptide-(311-315) inhibited the binding of factor Va to immobilized APC or factor Xa.(ABSTRACT TRUNCATED AT 250 WORDS)     

Heparin enhances the specificity of antithrombin for thrombin and factor Xa independent of the reactive center loop sequence. Evidence for an exosite determinant of factor Xa specificity in heparin-activated antithrombin

Heparin activates the primary serpin inhibitor of blood clotting proteinases, antithrombin, both by an allosteric conformational change mechanism that specifically enhances factor Xa inactivation and by a ternary complex bridging mechanism that promotes the inactivation of thrombin and other target proteinases. To determine whether the factor Xa specificity of allosterically activated antithrombin is encoded in the reactive center loop sequence, we attempted to switch this specificity by mutating the P6-P3' proteinase binding sequence excluding P1-P1' to a more optimal thrombin recognition sequence. Evaluation of 12 such antithrombin variants showed that the thrombin specificity of the serpin allosterically activated by a heparin pentasaccharide could be enhanced as much as 55-fold by changing P3, P2, and P2' residues to a consensus thrombin recognition sequence. However, at most 9-fold of the enhanced thrombin specificity was due to allosteric activation, the remainder being realized without activation. Moreover, thrombin specificity enhancements were attenuated to at most 5-fold with a bridging heparin activator. Surprisingly, none of the reactive center loop mutations greatly affected the factor Xa specificity of the unactivated serpin or the several hundred-fold enhancement in factor Xa specificity due to activation by pentasaccharide or bridging heparins. Together, these results suggest that the specificity of both native and heparin-activated antithrombin for thrombin and factor Xa is only weakly dependent on the P6-P3' residues flanking the primary P1-P1' recognition site in the serpin-reactive center loop and that heparin enhances serpin specificity for both enzymes through secondary interaction sites outside the P6-P3' region, which involve a bridging site on heparin in the case of thrombin and a previously unrecognized exosite on antithrombin in the case of factor Xa.     

Effects of enzymatic deglycosylation on the biological activities of human thrombin and antithrombin

Sequential digestion of human thrombin and antithrombin with neuraminidase, βgalactosidase, β-N-acetylglucosaminidase, and endo-β-N-acetylglucosaminidase D resulted in the successive removal of sialic acid, galactose, N-acetylglucosamine, and mannose and more N-acetylglucosamine residues. The products obtained after each stage of deglycosylation had electrophoretic mobilites that were consistent with the calculated change in mass expected from the cleavage of the sugar moieties. The modified thrombins did not lose fibrinogen-clotting activity, amidolytic activity, nor the ability to form complexes with antithrombin. In addition, asialothrombin and asialoagalactothrombin caused the same extent of platelet release as did control thrombin. The products obtained after removal of sugars from antithrombin retained thrombin-neutralizing activity. In the presence of heparin the inhibition of thrombin as well as factor Xa was enhanced. Thus, the sugar residues of thrombin and antithrombin are not required for the formation of enzyme-inhibitor complexes or for the other activities that were measured.