Glycosaminoglycans bind factor Xa in a Ca2+-dependent fashion and modulate its catalytic activity

Recent studies have demonstrated the existence of a Ca(2+)-dependent heparin-binding site on factor Xa. To characterize this heparin-binding site, the extrinsic fluorescence of fluorescein-labeled, active site-blocked factor Xa was monitored as it was titrated with glycosaminoglycans of various sulfate content and chain length. The binding of glycosaminoglycans to factor Xa appears to be charge-dependent because affinity is correlated with degree of glycosaminoglycan sulfation. All glycosaminoglycans bind factor Xa with higher affinity in the presence of Ca(2+) than in its absence. In contrast, when Gla-domainless factor Xa was substituted for factor Xa, glycosaminoglycans bound with similar affinities in the absence and presence of Ca(2+). These results support the hypothesis that the anionic Gla domain impairs glycosaminoglycan binding in the absence of Ca(2+). The changes in fluorescence intensity of factor Xa when titrated with glycosaminoglycans suggest that glycosaminoglycans induce conformational changes in the active site environment of factor Xa. To explore the consequences of these conformational changes, the effect of glycosaminoglycans on the catalytic activity of factor Xa was examined. Glycosaminoglycans influenced the ability of factor Xa to cleave chromogenic substrates and attenuated the capacity of factor Xa to activate factor VII. The potency of glycosaminoglycans in these assays reflected their affinity for factor Xa. These studies suggest that glycosaminoglycan binding perturbs exosites on the surface of factor Xa, potentially modifying interactions with cofactors or substrates.     

Heparin binding to protein C inhibitor.

Protein C inhibitor is a plasma protein whose ability to inhibit activated protein C, thrombin, and other enzymes is stimulated by heparin. These studies were undertaken to further understand how heparin binds to protein C inhibitor and how it accelerates proteinase inhibition. The region of protein C inhibitor from residues 264-283 was identified as the heparin-binding site. This differs from the putative heparin-binding site in the related proteins antithrombin and heparin cofactor. The glycosaminoglycan specificity of protein C inhibitor was relatively broad, including heparin and heparan sulfate, but not dermatan sulfate. Non-sulfated and non-carboxylated polyanions also enhanced proteinase inhibition by protein C inhibitor. Heparin accelerated inhibition of alpha-thrombin, gamma T-thrombin, activated protein C, factor Xa, urokinase, and chymotrypsin, but not plasma kallikrein. The ability of glycosaminoglycans to accelerate proteinase inhibition appeared to depend on the formation of a ternary complex of inhibitor, proteinase, and glycosaminoglycan. The optimum heparin concentration for maximal rate stimulation varied from 10 to 100 micrograms/ml and was related to the apparent affinity of the proteinase for heparin. There was no obvious relationship between heparin affinity and maximum inhibition rate or degree of rate enhancement. The affinity of the resultant protein C inhibitor-proteinase complex was also not related to inhibition rate enhancement, and the results showed that decreased heparin affinity of the complex is not an important part of the catalytic mechanism of heparin. The importance of protein C inhibitor as a regulator of the protein C system may depend on the relatively large increase in heparin-enhanced inhibition rate for activated protein C compared to other proteinases.     

Mutation of the H-helix in antithrombin decreases heparin stimulation of protease inhibition

Blood clotting proceeds through the sequential proteolytic activation of a series of serine proteases, culminating in thrombin cleaving fibrinogen into fibrin. The serine protease inhibitors (serpins) antithrombin (AT) and protein C inhibitor (PCI) both inhibit thrombin in a heparin-accelerated reaction. Heparin binds to the positively charged D-helix of AT and H-helix of PCI. The H-helix of AT is negatively charged, and it was mutated to contain neutral or positively charged residues to see if they contributed to heparin stimulation or protease specificity in AT. To assess the impact of the H-helix mutations on heparin stimulation in the absence of the known heparin-binding site, negative charges were also introduced in the D-helix of AT. AT with both positively charged H- and D-helices showed decreases in heparin stimulation of thrombin and factor Xa inhibition by 10- and 5-fold respectively, a decrease in affinity for heparin sepharose, and a shift in the heparin template curve. In the absence of a positively charged D-helix, changing the H-helix from neutral to positively charged increased heparin stimulation of thrombin inhibition 21-fold, increased heparin affinity and restored a normal maximal heparin concentration for inhibition.     

Cysteine proteinase activity regulation. A possible role of heparin and heparin-like glycosaminoglycans.

Papain is considered to be the archetype of cysteine proteinases. The interaction of heparin and other glycosaminoglycans with papain may be representative of many mammalian cysteine proteinase-glycosaminoglycan interactions that can regulate the function of this class of proteinases in vivo. The conformational changes in papain structure due to glycosaminoglycan interaction were studied by circular dichroism spectroscopy, and the changes in enzyme behavior were studied by kinetic analysis, monitored with fluorogenic substrate. The presence of heparin significantly increases the alpha-helix content of papain. Heparin binding to papain was demonstrated by affinity chromatography and shown to be mediated by electrostatic interactions. The incubation of papain with heparin promoted a powerful increase in the affinity of the enzyme for the substrate. In order to probe the glycosaminoglycan structure requirements for the papain interaction, the effects of two other glycosaminoglycans were tested. Like heparin, heparan sulfate, to a lesser degree, was able to decrease the papain substrate affinity, and it simultaneously induced alpha-helix structure in papain. On the other hand, dermatan sulfate was not able to decrease the substrate affinity and did not induce alpha-helix structure in papain. Heparin stabilizes the papain structure and thereby its activity at alkaline pH.     

Inhibition of factor IXa and factor Xa by antithrombin III/heparin during factor X activation

We investigated the kinetics of the inhibitory action of antithrombin III and antithrombin III plus heparin during the activation of factor X by factor IXa. Generation and inactivation curves were fitted to a three-parameter two-exponentional model to determine the pseudo first-order rate constants of inhibition of factor IXa and factor Xa by antithrombin III/heparin. In the absence of heparin, the second-order rate constant of inhibition of factor Xa generated by factor IXa was 2.5-fold lower than the rate constant of inhibition of exogenous factor Xa. It appeared that phospholipid-bound factor X protected factor Xa from inactivation by antithrombin III. It is, as yet, unclear whether an active site or a nonactive site interaction between factor Xa and factor X at the phospholipid surface is involved. The inactivation of factor IXa by antithrombin III was found to be very slow and was not affected by phospholipid, calcium, and/or factor X. With unfractionated heparin above 40 ng/ml and antithrombin III at 200 nM, the apparent second-order rate constant of inhibition of exogenous and generated factor Xa were the same. Thus, in this case phospholipid-bound factor X did not protect factor Xa from inhibition. In the presence of synthetic pentasaccharide heparin, however, phospholipid-bound factor X reduced the rate constant about 5-fold. Pentasaccharide had no effect on the factor IXa/antithrombin III reaction. Unfractionated heparin (1 micrograms/ml) stimulated the antithrombin III-dependent inhibition of factor IXa during factor X activation 400-fold. In the absence of reaction components this stimulated was 65-fold. We established that calcium stimulated the heparin-dependent inhibition of factor IXa.     

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.     

Inhibition of factor X and factor V activation by dermatan sulfate and a pentasaccharide with high affinity for antithrombin III in human plasma

There is evidence that by catalyzing thrombin inhibition, several glycosaminoglycans can inhibit the thrombin-mediated amplification reactions of coagulation and thereby delay prothrombin activation. The two amplification reactions can apparently be catalysed by endogenously generated factor Xa and thrombin. This study provides evidence which suggests that on a molar basis, an agent which can only catalyse thrombin inhibition is approximately 10 times more effective than an agent which can only catalyse factor Xa inhibition in their ability to inhibit intrinsic prothrombin activation. We determined the concentrations of each of heparin, dermatan sulfate and a pentasaccharide with high affinity for antithrombin III, to delay intrinsic prothrombin activation for at least 15s. Heparin catalyses both thrombin and factor Xa inhibition; dermatan sulfate catalyses only thrombin inhibition, while the pentasaccharide only catalyses factor Xa inhibition. Efficient prothrombin activation, which coincided with both factor X activation and factor V proteolysis, was first observed 45s after CaC12 was added to contact-activated plasma. Heparin (approximately 0.1 microM) prolonged by at least 30 s the time required for the activation of the three clotting factors to begin. The minimum concentrations of the pentasaccharide and dermatan sulfate to delay the activation of prothrombin, factors X and V were approximately 50 microM and approximately 5 microM, respectively. Thus, each anticoagulant could inhibit intrinsic prothrombin activation only when it inhibited activation of both factors X and V. A combination of approximately 5 microM pentasaccharide and approximately 0.05 microM dermatan sulfate similarly delayed the activation of all three clotting factors. Thus, while catalysis of thrombin inhibition is a more effective pathway than catalysis of factor Xa inhibition for delaying prothrombin activation, the simultaneous catalysis of thrombin and factor Xa inhibition can synergistically improve the ability of a sulfated polysaccharide to delay prothrombin activation.     

Mechanism of catalysis of inhibition of factor IXa by antithrombin in the presence of heparin or pentasaccharide

Because of the homology between factor IXa and factor Xa (f.IXa and f.Xa, respectively), and the critical upstream position of f.IXa in the coagulation cascade, the contribution of the heparin-derived pentasaccharide to antithrombin-mediated inhibition of f.IXa was investigated. Pentasaccharide promotes inhibition of both f.IXa and f.Xa generated in recalcified plasma. This result demonstrates that antithrombin is the predominant inhibitor of f.IXa in plasma, and that the activity of antithrombin is promoted by pentasaccharide. Kinetic experiments reveal that pentasaccharide increases the rates of antithrombin-mediated inhibition of both f.IXa and f.Xa by 2 orders of magnitude. These findings indicate that pentasaccharide-induced conformational changes in antithrombin enhance its capacity to inhibit both f.IXa and f.Xa. In the presence of Ca2+, full-length heparin produces an additional approximately 10-fold increase in the rates of inhibition of both enzymes, consistent with a template role of heparin. Heparin binding to f.Xa was previously shown to be promoted in the presence of Ca2+. Binding studies with f.IXa reveal a 10-fold higher affinity for heparin in the presence of Ca2+ compared with its absence. Thus, Ca2+ promotes heparin-catalyzed inhibition of f.IXa and f.Xa by antithrombin by augmenting the template mechanism. These results indicate that heparin-mediated catalysis of f.IXa inhibition by antithrombin reflects both pentasaccharide-induced conformational changes and heparin-mediated bridging of antithrombin to f.IXa. Furthermore, our data suggest that the efficacy of pentasaccharide for prevention and treatment of thrombotic disorders may reflect its action at two sites in the coagulation system.     

Unfractionated heparin inhibits thrombin-catalysed amplification reactions of coagulation more efficiently than those catalysed by factor Xa.

We have proposed previously that the steps in coagulation most sensitive to inhibition by heparin are the thrombin-dependent amplification reactions, and that prothrombinase is formed in heparinized plasma only after Factor Xa activates Factor VIII and Factor V. These propositions were based on the demonstration that both heparin and Phe-Pro-Arg-CH2Cl completely inhibited 125I-prothrombin activation for up to 60 s when contact-activated plasma (CAP) was replenished with Ca2+. Furthermore, the addition of thrombin to CAP before heparin or Phe-Pro-Arg-CH2Cl completely reversed their inhibitory effects. Additional support for the above hypotheses is provided in this study by demonstrating that, when the activity of thrombin is suppressed by heparin (indirectly) or by Phe-Pro-Arg-CH2Cl (directly), exogenous Factor Xa reverses the ability of these two agents to inhibit prothrombin activation. Prothrombin activation was initiated by adding Factor Xa (1 nM) or thrombin (1 or 10 nM) simultaneously with CaCl2 to CAP. In the absence of heparin or Phe-Pro-Arg-CH2Cl, prothrombin activation was seen 15 s later in either case. Heparin failed to delay, and Phe-Pro-Arg-CH2Cl delayed for 15 s, prothrombin activation in CAP supplemented with Factor Xa. In contrast, heparin and Phe-Pro-Arg-CH2Cl completely inhibited prothrombin activation for at least 45 s in CAP supplemented with 1 nM-thrombin. Heparin failed to delay prothrombin activation in CAP supplemented with 10 nM-thrombin, whereas Phe-Pro-Arg-CH2Cl completely inhibited prothrombin activation in this plasma for 45 s. These results suggest that in CAP: (1) Factor Xa can effectively activate Factor VIII and Factor V when the proteolytic activity of thrombin is suppressed; (2) heparin-antithrombin III is less able to inhibit Factor Xa than thrombin; (3) suppression of the thrombin-dependent amplification reactions is the primary anticoagulant effect of heparin.     

Identification and characterization of a glycosaminoglycan recognition element of the C chemokine lymphotactin

Chemokine-mediated recruitment of leukocytes in vivo depends on interactions with cell surface glycosaminoglycans. Lymphotactin, the unique member of the "C" chemokine subclass, is a highly basic protein that binds heparin, a glycosaminoglycan, with high affinity (approximately 10 nm). We detected lymphotactin-heparin binding by NMR and mapped this interaction to a narrow surface that wraps around the protein. Substitutions in and around this binding site and surface plasmon resonance analysis of heparin binding affinity identified two arginine residues of lymphotactin as critical for glycosaminoglycan binding. Both arginine mutant proteins and the combined double mutant had dramatically diminished in vivo activity in a leukocyte recruitment assay, suggesting that the lymphotactin-glycosaminoglycan interactions detected in vitro are important for the function of this chemokine. Our results demonstrate that like other chemokines, lymphotactin utilizes highly specific glycosaminoglycan-binding sites that represent potential targets for drug development.     

Mechanisms of interactions of factor X and factor Xa with the acidic region in the factor VIII A1 domain

The 337-372 sequence of the factor VIIIa A1 subunit contains interactive sites for both zymogen factor X and the active enzyme, factor Xa. Solid phase binding studies indicated that factor Xa possessed a >20-fold higher affinity for the isolated A1 subunit of factor VIIIa compared with factor X. Heparin completely inhibited zero-length cross-linking of the 337-372 peptide to factor Xa but not to factor X. In the presence of calcium, factor Xa showed greater affinity for heparin than factor X. Studies using factor Xa mutants in which heparin-binding exosite residues were individually replaced by Ala showed that the R240A mutant was defective in recognition of the Lys36 cleavage site, generating the A137-372 intermediate with approximately 20% the catalytic efficiency of wild type. This defect likely resulted from an approximately 4-fold increase in Km for the A1 substrate because kcat values for the wild type and mutant were equivalent. Cleavage of the A1-A2 domain junction by factor Xa R240A was not blocked by the 337-372 peptide. Studies using mutant factor VIII where clustered acidic residues in the 337-372 segment were replaced by Ala showed that a factor VIIIa D361A/D362A/D363A mutant possessed a approximately 1.6-fold increase in Km for factor X compared with wild type. However, similar Km values were observed for recombinant factor X and R240A substrates. These results indicate that the binding regions of factor X and factor Xa for A1 domain overlap and that both utilize acidic residues 361-363. Furthermore, factor Xa but not factor X interacts with high affinity at this site via residues contained within the heparin-binding exosite of the proteinase.     

A peptide found by phage display discriminates a specific structure of a trisaccharide in heparin

A number of recent studies have shown that heparan sulfate can control several important biological events on the cell surface through changes in sulfation pattern. The in vivo modification of sugar chains with sulfates, however, is complicated, and the discrimination of different sulfation patterns is difficult. Heparin, which is primarily produced by mast cells, is closely approximated by the structural analog heparan sulfate. Screening of heparin-associating peptides using phage display and antithrombin-bound affinity chromatography identified a peptide, heparin-associating peptide Y (HappY), that acts as a target of immobilized heparin. The peptide consists of 12 amino acid residues with characteristic three arginines and exclusively binds to heparin and heparan sulfate but does not associate with other glycosaminoglycans. HappY recognizes three consecutive monosaccharide residues in heparin through its three arginine residues. HappY should be a useful probe to detect heparin and heparan sulfate in studies of glycobiology.     

Interactions between heparin and factor Xa inhibition of prothrombin activation

The effects of heparin on prothrombin activation have been examined. Heparin was found to inhibit the rate of prothrombin activation by Factor Xa, calcium and phospholipid. In the absence of phospholipid, heparin had no effect on the rate of prothrombin activation. In contrast, heparin was found to increase the rate of activation of prethrombin-1 and prethrombin-2. Initial velocity studies indicated that heparin blocks lipid stimulation of prothrombin activation. In accord with this, binding studies demonstrated that heparin could displace Factor Xa, and in separate experiments, prothrombin, from phospholipid vesicles.     

Interactions between heparin and factor Xa. Inhibition of prothrombin activation.

The effects of heparin on prothrombin activation have been examined. Heparin was found to inhibit the rate of prothrombin activation by Factor Xa, calcium and phospholipid. In the absence of phospholipid, heparin had no effect on the rate of prothrombin activation. In contrast, heparin was found to increase the rate of activation of prethrombin-1 and prethrombin-2. Initial velocity studies indicated that heparin blocks lipid stimulation of prothrombin activation. In accord with this, binding studies demonstrated that heparin could displace Factor Xa, and in separate experiments, prothrombin, from phospholipid vesicles.     

The N-terminal acidic domain of heparin cofactor II mediates the inhibition of alpha-thrombin in the presence of glycosaminoglycans

Heparin cofactor II (HCII) is a glycoprotein in human plasma that inhibits thrombin and chymotrypsin. Inhibition occurs when the protease attacks the reactive site peptide bond in HCII (Leu444-Ser445) and becomes trapped as a covalent 1:1 complex. Dermatan sulfate and heparin increase the rate of inhibition of thrombin, but not of chymotrypsin, greater than 1000-fold. The N-terminal portion of HCII contains two acidic repeats (Glu56-Asp-Asp-Asp-Tyr-Leu-Asp and Glu69-Asp-Asp-Asp-Tyr-Ile-Asp) that may bind to anion-binding exosite I of thrombin to facilitate covalent complex formation. To examine the importance of the acidic domain, we have constructed a series of 5' deletions in the HCII cDNA and expressed the recombinant HCII (rHCII) in Escherichia coli. Apparent second-order rate constants (k2) for inhibition of alpha-thrombin and chymotrypsin by each variant were determined. Deletion of amino acid residues 1-74 had no effect on the rate of inhibition of alpha-thrombin or chymotrypsin in the absence of a glycosaminoglycan. Similarly, the rate of inhibition of alpha-thrombin in the presence of a glycosaminoglycan was unaffected by deletion of residues 1-52. However, deletion of residues 1-67 (first acidic repeat) or 1-74 (first and second acidic repeats) greatly decreased the rate of inhibition of alpha-thrombin in the presence of heparin, dermatan sulfate, or a dermatan sulfate hexasaccharide that comprises the minimum high-affinity binding site for HCII. Deletion of one or both of the acidic repeats increased the apparent affinity of rHCII for heparin-Sepharose, suggesting that the acidic domain may interact with the glycosaminoglycan-binding site of native rHCII. The stimulatory effect of glycosaminoglycans on native rHCII was decreased by a C-terminal hirudin peptide which binds to anion-binding exosite I of alpha-thrombin. Furthermore, the ability of native rHCII to inhibit gamma-thrombin, which lacks the binding site for hirudin, was stimulated weakly by glycosaminoglycans. These results support a model in which the stimulatory effect of glycosaminoglycans on the inhibition of alpha-thrombin is mediated, in part, by the N-terminal acidic domain of HCII.     

Role of zymogen and activated factor X as scaffolds for the inhibition of the blood coagulation factor VIIa-tissue factor complex by recombinant nematode anticoagulant protein c2

Recombinant nematode anticoagulant protein c2 (rNAPc2) is a potent, factor Xa (fXa)-dependent small protein inhibitor of factor VIIa-tissue factor (fVIIa.TF), which binds to a site on fXa that is distinct from the catalytic center (exo-site). In the present study, the role of other fX derivatives in presenting rNAPc2 to fVIIa.TF is investigated. Catalytically active and active site blocked fXa, as well as a plasma-derived and an activation-resistant mutant of zymogen fX bound to rNAPc2 with comparable affinities (K(D) = 1-10 nm), and similarly supported the inhibition of fVIIa.TF (K(i)* = approximately 10 pm). The roles of phospholipid membrane composition in the inhibition of fVIIa.TF by rNAPc2 were investigated using TF that was either detergent-solubilized (TF(S)), or reconstituted into membranes, containing phosphatidylcholine (TF(PC)) or a mixture of phosphatidylcholine and phosphatidylserine (TF(PCPS)). In the absence of the fX derivative, inhibition of fVIIa.TF was similar for all three conditions (K(i) approximately 1 microm), whereas the addition of the fX derivative increased the respective inhibition by 35-, 150-, or 100,000-fold for TF(S), TF(PC), and TF(PCPS). The removal of the gamma-carboxyglutamic acid-containing domain from the fX derivative did not affect the binding to rNAPc2, but abolished the effect of factor Xa as a scaffold for the inhibition of fVIIa.TF by rNAPc2. The overall anticoagulant potency of rNAPc2, therefore, results from a coordinated recognition of an exo-site on fX/fXa and of the active site of fVIIa, both of which are properly positioned in the ternary fVIIa.TF.fX(a) complex assembled on an appropriate phospholipid surface.     

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.     

Serine 380 (P14) --> glutamate mutation activates antithrombin as an inhibitor of factor Xa

Heparin regulates the inhibitory activity of antithrombin. It has been proposed that residues P15 and P14 are expelled from beta-sheet A of antithrombin by heparin binding, permitting better interaction of the reactive center loop with factor Xa. We have made a P14 antithrombin variant (S380E) to create an activated inhibitory form of antithrombin in which P14 is already expelled from beta-sheet A. S380E antithrombin fluorescence is enhanced 35 +/- 5% compared with control antithrombin. There is minimal further increase in antithrombin fluorescence upon heparin binding. The variant has a 5 degrees C lower T(m) than control antithrombin. The variant is an inhibitor of proteinases and has a nearly 200-fold increased basal rate of inhibition of factor Xa, after correction for an increased stoichiometry of inhibition. This is comparable to that of antithrombin activated by high affinity heparin pentasaccharide. Full-length high affinity heparin causes only a 7-fold additional increase in rate and a large increase in stoichiometry of inhibition. In contrast, the basal rate of inhibition of thrombin is similar to that of control antithrombin but is increased 300-fold by heparin. These findings suggest that the native state of the S380E variant exists in a loop-expelled conformation that is consequently highly reactive toward factor Xa.     

Competitive, reversible, and potent antagonism of inositol 1,4,5-trisphosphate-activated calcium release by heparin

The action of inositol 1,4,5-trisphosphate (InsP3) in releasing intracellular Ca2+ is shown to be competitively and potently antagonized by the glycosaminoglycan, heparin. Using either permeabilized cells of the DDT1MF-2 smooth muscle cell line, or an isolated microsomal membrane fraction derived from intact cells, heparin (4-6 kDa) at 10 micrograms/ml was observed to completely block the action of InsP3 in releasing Ca2+ accumulated via the ATP-dependent Ca2+ pump. In permeabilized cells, heparin had no effect on Ca2+ pump activity or on passive Ca2+ fluxes contributing to equilibrium Ca2+ accumulation. Heparin up to 100 micrograms/ml had no effect on the GTP-activated Ca2+ translocation process previously characterized in this cell line. Half-maximal inhibition of Ca2+ release activated by 10 microM InsP3 occurred with heparin at approximately 0.6 and 0.2 microgram/ml in permeabilized cells and isolated microsomes, respectively. Using microsomes, InsP3 dose-response curves in the presence and absence of 0.2 microgram/ml heparin (approximately 40 nM) revealed a 10-fold increase in apparent Km for InsP3 (0.31 microM in the absence of heparin) with no change in Vmax, indicating a competitive action of heparin. The results revealed a very high apparent affinity of heparin for the InsP3 active site, with a calculated Ki value of 2.7 nM. Heparin was shown to rapidly (within 20 s) reverse prior full activation of InsP3-mediated Ca2+ release returning the Ca2+ equilibrium back to that observed without InsP3. This reversal occurs even after prolonged (6 min) InsP3 activation. These results indicate a specific, high affinity, and competitive antagonism of the InsP3 active site by heparin. The rapidly induced reversal of InsP3-activated Ca2+ release by heparin strongly suggests that InsP3 directly activates a channel which remains open only while InsP3 is associated and closes immediately upon InsP3 dissociation.     

Structural requirements for the neutralization of heparin-like saccharides by complement S protein/vitronectin

S protein, a major inhibitor of the assembly of the membrane attack complex of complement, has recently been shown to be identical to the serum spreading factor vitronectin. It also neutralizes the anticoagulant activities of heparin. We have studied the structural requirements for the heparin neutralizing properties of S protein/vitronectin using heparin, heparan sulfate, and heparin oligosaccharides with well defined anticoagulant specificities. The abilities of heparin fractions, Mr 7,800-18,800, with high affinity for antithrombin, and of the International Heparin Standard, to accelerate the inactivation of thrombin and Factor Xa by antithrombin were readily neutralized by S protein/vitronectin. Binding and neutralization of heparin by S protein/vitronectin was inhibited by heparin with low affinity for antithrombin, indicating that S protein/vitronectin can interact with a region on the heparin chain that might serve as a proteinase binding site. S protein/vitronectin efficiently neutralized oligosaccharides of Mr 2,400-7,200, unlike the two other physiologically occurring heparin neutralizing proteins histidine-rich glycoprotein and platelet factor 4. Furthermore, S protein/vitronectin neutralized the anti-Factor Xa activity of a synthetic pentasaccharide comprising the antithrombin-binding sequence of heparin. High molar excess of a synthetic tridecapeptide corresponding to part (amino acids 374-359) of the proposed glycosaminoglycan binding domain of S protein/vitronectin neutralized high affinity heparin and some oligosaccharides, but failed to neutralize the synthetic antithrombin-binding pentasaccharide. Like platelet factor 4, but unlike histidine-rich glycoprotein, S protein/vitronectin readily neutralized the anticoagulant activities of heparan sulfate of Mr approximately 20,000. These findings suggest that S protein/vitronectin may interact through its glycosaminoglycan binding domain(s) with various functional domains of the heparin (heparan sulfate) molecule, including the antithrombin-binding pentasaccharide sequence. Furthermore, the results suggest that S protein/vitronectin may be a physiologically important modulator of the anticoagulant activity of heparin-like material on or near the vascular endothelium.