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.     

Important role of arginine 129 in heparin-binding site of antithrombin III. Identification of a novel mutation arginine 129 to glutamine

An hereditary abnormal antithrombin III (ATIII Geneva) with defective heparin cofactor activity was characterized by DNA single strand amplification and subsequent direct sequencing. ATIII Geneva was found to have a G to A transition in Exon IIIa leading to an Arg-129 to Gln mutation. This amino acid is part of the ATIII region comprising residues 114-154, which contains the highest proportion of basic residues (Arg or Lys), and is known from chemical modification studies to be involved in heparin binding. The variant protein did not bind heparin-Sepharose and was isolated from the propositus plasma by immunoaffinity chromatography. High affinity (for ATIII) heparin had only a minimal effect on thrombin and activated factor X inhibition by the purified abnormal ATIII. Taken together, these results demonstrate an important role for Arg-129 in the binding and interaction of ATIII with heparin of high affinity. We propose that a cooperation between Lys-125, Arg-129, Lys-136, and Arg-47 exposed at the surface of the inhibitor allows the binding of the essential pentasaccharide domain of heparin which is specific for the ATIII interaction.     

Affinity chromatography of sulphated polysaccharides separately fractionated on antithrombin III and heparin cofactor II immobilized on concanavalin A—Sepharose

Three sulphated polysaccharides, dermatan sulphate, fucan and heparin, were fractionated according to their affinity towards antithrombin III (ATIII) and heparin cofactor II (HCII), the two main physiological thrombin (IIa) inhibitors. Both inhibitors were immobilized on concanavalin A—Sepharose, which binds to the glycosylated chains of the proteins while the protein-binding site for the polysaccharide remains free. Each polysaccharide was fractionated into bound and unbound fractions either for ATIII or HCII. The eluted fractions were tested for their ability to catalyse and interactions. The possible presence of a unique binding site for ATIII and HCII, on each sulphated polysaccharide, was also studied.     

A heparin binding site in antithrombin III. Identification, purification, and amino acid sequence

A heparin-binding peptide within antithrombin III (ATIII) was identified by digestion of ATIII with Staphylococcus aureus V8 protease followed by purification on reverse-phase high pressure liquid chromatography using a C-4 column matrix. The column fractions were assayed for their ability to bind heparin by ligand blotting with 125I-fluoresceinamine-heparin as previously described (Smith, J. W., and Knauer, D. J. (1987) Anal. Biochem. 160, 105-114). This analysis identified at least three fractions with heparin binding ability of which the peptide eluting at 25.4 min gave the strongest signal. Amino acid sequence analysis of this peptide gave a partially split sequence which was consistent with regions encompassing amino acids 89-96 and 114-156. These amino acids are present in a 1:1 molar ratio which is consistent with a disulfide linkage between Cys-95 and Cys-128. High affinity heparin competed more effectively for the binding of 125I-fluoresceinamine-heparin to this peptide than low affinity heparin. Chondroitin sulfate did not block the binding of 125I-fluoresceinamine-heparin to the peptide. These data strongly suggest that the isolated peptide represents a native heparin-binding region within intact ATIII. Computer generation of a plot of running charge density of ATIII confirms that the region encompassing amino acid residues 123-141 has the highest positive charge density within the molecule. A hydropathy plot of ATIII was generated using a method similar to that of Kyte and Doolittle (Kyte, J., and Doolittle, R. F. (1982) J. Mol. Biol. 157, 105-132). This plot indicates that amino acid residues 126-140 are exposed to the exterior surface of the molecule. Based on these data, we suggest that the region corresponding to amino acid residues 114-156 is a likely site for the physiological heparin-binding domain of ATIII. We also conclude that the proposed disulfide bridges within the protein are suspect and should be re-examined (Petersen, T. E., Dudek-Wojiechowska, G., Sottrup-Jensen, L., and Magnussun, S. (1979) in The Physiological Inhibitors of Coagulation and Fibrinolysis (Collen, D., Wiman, B., and Verstaeta, M., eds) pp. 43-54, Elsevier Scientific Publishing Co., Amsterdam).     

Specific interaction of vitronectin with the cell-secreted protease inhibitor glia-derived nexin and its thrombin complex.

Interaction of vitronectin with glia-derived nexin (GDN), thrombin, and the complex GDN-thrombin was demonstrated in direct binding assays that indicated the formation of binary and ternary complexes. The concentration of vitronectin necessary to obtain 50% saturation of the immobilized GDN-thrombin complex binding sites (EC50) was about 1 nM. Under similar experimental conditions, the EC50 of vitronectin for the immobilized antithrombin-III-thrombin complex was about fivefold higher. A tight complex was also formed between vitronectin and immobilized GDN (EC50 approximately 1.5 nM) but when vitronectin was immobilized, GDN displayed a reduced affinity for vitronectin (EC50 approximately 10 nM). These results suggest differences between the immobilized and free conformations of GDN and/or vitronectin. In contrast, vitronectin displayed negligible affinity for antithrombin III. Biotinylated GDN was used to characterize further the binding of GDN or the GDN-thrombin complex to vitronectin. The interaction of the biotinylated GDN-thrombin complex with immobilized vitronectin (EC50 approximately 2 nM) was completely blocked by nonbiotinylated complexes of thrombin with either GDN or antithrombin III, whereas free GDN, free thrombin and the GDN-trypsin complex were only weak competitors. Active-site-blocked urokinase and the complex GDN-urokinase also strongly competed for binding of the biotinylated GDN-thrombin complex to vitronectin. Binding of biotinylated GDN to immobilized vitronectin was specific, saturable and was competed with decreasing efficiency by the GDN-thrombin complex, free GDN and free antithrombin III. These interactions between the adhesive component vitronectin and the serine protease inhibitor GDN may relate to localized control of thrombin and/or urokinase action at certain extravascular sites. These results are discussed in terms of binding sites for vitronectin on GDN, thrombin, and the GDN-thrombin complex.     

A comparison of three heparin-binding serine proteinase inhibitors.

The purpose of this study was to compare three heparin-binding plasma proteinase inhibitors in order to identify common and unique features of heparin binding and heparin-enhanced proteinase inhibition. Experiments with antithrombin, heparin cofactor, and protein C inhibitor were performed under identical conditions in order to facilitate comparisons. Synthetic peptides corresponding to the putative heparin binding regions of antithrombin, heparin cofactor, and protein C inhibitor bound to heparin directly and interfered in heparin-enhanced proteinase inhibition assays. All three inhibitors obeyed a ternary complex mechanism for heparin-enhanced thrombin inhibition, and the optimum heparin concentration was related to the apparent heparin affinity of the inhibitor. The maximum inhibition rate and rate enhancement due to heparin appeared to be unique properties of each inhibitor. In assays with heparin oligosaccharides of known size, only the antithrombin-thrombin reaction exhibited a sharp threshold for rate enhancement at 14-16 saccharide units. Acceleration of antithrombin inhibition of factor Xa, heparin cofactor inhibition of thrombin, and protein C inhibitor inhibition of thrombin, activated protein C, and factor Xa did not require a minimum saccharide size. The differences in heparin size dependence and rate enhancement of proteinase inhibition by these inhibitors might reflect differences in the importance of the ternary complex mechanism and other mechanisms, alterations in inhibitor reactivity, and orientation effects in heparin-enhanced proteinase inhibition.     

Diversity-oriented chemical modification of heparin: Identification of charge-reduced N-acyl heparin derivatives having increased selectivity for heparin-binding proteins

The diversity-oriented chemical modification of heparin is shown to afford charge-reduced heparin derivatives that possess increased selectivity for binding heparin-binding proteins. Variable N-desulfonation of heparin was employed to afford heparin fractions possessing varied levels of free amine. These N-desulfonated heparin fractions were selectively N-acylated with structurally diverse carboxylic acids using a parallel synthesis protocol to generate a library of 133 heparin-derived structures. Screening library members to compare affinity for heparin-binding proteins revealed unique heparin-derived structures possessing increased affinity and selectivity for individual heparin-binding proteins. Moreover, N-sulfo groups in heparin previously shown to be required for heparin to bind specific proteins have been replaced with structurally diverse non-anionic moieties to afford identification of charge-reduced heparin derivatives that bind these proteins with equivalent or increased affinity compared to unmodified heparin. The methods described here outline a process that we feel will be applicable to the systematic chemical modification of natural polyanionic polysaccharides and the preparation of synthetic oligosaccharides to identify charge-reduced high affinity ligands for heparin-binding proteins.     

A fragment of antithrombin that binds both heparin and thrombin.

In order to identify the regions of antithrombin that interact with heparin and thrombin, it was degraded with CNBr and the activities of the isolated products were investigated. These fragments did not exhibit direct thrombin-neutralizing activity; however, one unique fragment was found to bind to heparin-Sepharose and also to interfere with the inhibition of thrombin by intact antithrombin. This fragment was identified as the one consisting of three disulphide-linked polypeptide chains containing residues 1-17, 104-251 and 424-432. At a concentration of 46 nM, this product decreased the heparin-enhanced thrombin-inhibitory activity of antithrombin by half, and completely abolished this inhibition when above 300 nM. In the absence of heparin, the action of antithrombin was not completely nullified by the fragment, even when present at relatively high concentrations. At a given fragment concentration, the extent of inhibition was independent of antithrombin concentration over the range tested. It was found that the fragment decreased the second-order rate constant for the antithrombin-thrombin reaction. Reduction and alkylation of the fragment showed that the above properties reside primarily in the peptide with residues 104-251. It is concluded that this peptide possesses portions of the antithrombin molecule that bind to heparin as well as to a site on thrombin.     

Kinetic analysis of various heparin fractions and heparin substitutes in the thrombin inhibition reaction

Kinetic characteristics of several heparin preparations and substitute heparins were determined to help understand the bases for activity differences. Several materials were highly active in factor Xa inhibition and the reaction rate at constant factor Xa concentration appeared to be predicted by the extent of intrinsic antithrombin III fluorescence change induced by the polysaccharide. Heparin fractions of different molecular weight and affinity for antithrombin III showed similar kinetic parameters in catalysis of the thrombin-antithrombin III reaction when these parameters were expressed on the basis of antithrombin III-binding heparin. The latter was determined by stoichiometric titration of the antithrombin III fluorescence change by the heparin preparation. However, the various heparin fractions showed very different specific activities per mg of total polysaccharide. This indicated that functional heparin molecules had similar kinetic properties regardless of size or antithrombin III-binding affinity and is possible because the Km for antithrombin III is determined by diffusion rather than by binding affinity. Substitute heparins and depolymerized heparin were poor catalysts for thrombin inhibition, due at least partially to their affinity for thrombin. This latter binary interaction inhibits thrombin reaction in the heparin-catalyzed reaction.     

Studies on the mechanism of the rate-enhancing effect of heparin on the thrombin-antithrombin III reaction.

The rate of the reaction between thrombin and antithrombin III is greatly increased in the presence of heparin. Several mechanisms for this effect are possible. To study the problems commercial heparin was fractionated into one fraction of high anticogulant activity and one of low anticoagulant activity by affinity chromatography on matrix-bound antithrombin III. The strength of the binding of the two heparin fractions to antithrombin III and thrombin, respectively, was determined by a crossed immunoelectrophoresis technique. As was to be expected, the high activity fraction was strongly bound to antithrombin III while the low activity fraction was weakly bound. In contrast, thrombin showed equal binding affinity for both heparin fractions. The ability of the two heparin fractions to catalyse the inhibition of thrombin by antithrombin III was determined and was found to be much greater for the high activity heparin fraction. A mechanism for the reaction between thrombin and antithrombin III in the presence of small amounts of heparin is suggested, whereby antithrombin III first binds heparin and this complex then inhibits thrombin by interaction with both the bound heparin and the antithrombin III.     

Expression and characterization of human antithrombin III synthesized in mammalian cells

Antithrombin III (ATIII) has been expressed in transiently transfected COS-1 monkey cells and in stably transformed Chinese hamster ovary cells, and the resultant protein has been characterized for biological activity. Both cell types efficiently secrete high levels of heterogeneous molecular weight forms of ATIII antigen. The heterogeneity results from differences in post-translational modifications. However, only a small percentage (5-10%) of the total antigen expressed is biologically active. The fraction of biologically active ATIII has been purified from total ATIII by affinity fractionation on heparin-Sepharose. This fractionation indicates that the differences in the active and inactive forms of expressed ATIII result from differences in their ability to bind heparin. Purified ATIII has a specific activity very similar to that of plasma-derived ATIII and exhibits typical heparin-accelerated ATIII activity. The biologically active fraction of ATIII appears to represent the higher molecular weight forms of the ATIII expressed and is likely not a result of altered asparagine-linked glycosylation; however, the nature of the post-translational modification required for ATIII activity remains unclear. The ability to express biologically active ATIII at such high levels should allow further investigations of the structural requirements for ATIII activity.     

Heparan sulphate with no affinity for antithrombin III and the control of haemostasis

Heparan sulphate with no affinity for antithrombin III (ATIII) was observed to cause acceleration of the factor Xa:ATIII interaction by 1100-fold (k2, 7 X 10(7) M-1.min-1) and the prothrombinase:ATIII interaction by 2900-fold (k2, 2.5 X 10(7) M-1.min-1). Although high-affinity heparan sulphate catalyzed higher acceleration and at lower concentration, in natural mixtures of the two forms the activity of the no affinity form predominated. Heparan sulphate had no significant effect on the thrombin:ATIII interaction but inhibited its potentiation by heparin (Kd 0.3 microM). From the estimated concentration of heparan sulphate on the endothelial cell surface it is proposed that the non-thrombogenic property of blood vessels is due to the acceleration of the factor Xa or prothrombinase:ATIII interaction by the greater mass of surface-bound heparan sulphate rather than by the much smaller proportion of heparin-like molecules (with high affinity for antithrombin III) which may be present.     

Role of ternary complexes, in which heparin binds both antithrombin and proteinase, in the acceleration of the reactions between antithrombin and thrombin or factor Xa

Oligosaccharides (10-20 monosaccharide units) with high affinity for antithrombin, as well as larger high-affinity heparin fractions (having relative molecular masses between 6,000 and 21,500), all markedly accelerated the inhibition of Factor Xa by antithrombin. Moreover, all high-affinity oligosaccharides and heparins enhanced, to a similar extent, the amount of free proteolytically modified antithrombin cleaved at the reactive bond by Factor Xa. In contrast, a minimum high-affinity heparin size of approximately 18 monosaccharide units was required to significantly accelerate the inactivation of thrombin by antithrombin and to enhance the production of modified antithrombin by this enzyme. All high-affinity fractions studied had similar affinities for antithrombin, as determined by fluorescence titrations. In competition experiments, binary complexes of antithrombin with octadecasaccharide or larger high-affinity heparins, but not with smaller oligosaccharides, displaced inactivated 125I-thrombin from matrix-linked low-affinity heparin. Moreover, similar binary complexes with 3H-labeled octadecasaccharide or larger chains, but not with smaller oligosaccharides, were capable of binding to matrix-linked inactivated thrombin. These results indicate that simultaneous binding of antithrombin and thrombin to high-affinity heparin is a prerequisite to the acceleration of the antithrombin-thrombin reaction and that the minimum heparin sequence capable of binding both proteins comprises approximately 18 monosaccharide units. Similar complex formation apparently is not required for the acceleration of the antithrombin-Factor Xa reaction.     

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.     

Dependence of antithrombin III and thrombin binding stoichiometries and catalytic activity on the molecular weight of affinity-purified heparin

Heparin was fractionated by affinity chromatography on immobilized antithrombin III followed by gel filtration on Sephadex G-100. Eighteen fractions were obtained ranging in molecular weight from 9,700 to 34,300 as determined by sedimentation equilibrium. The binding stoichiometries of antithrombin III and thrombin interactions with the heparin of these fractions were measured, using changes in intrinsic and extrinsic fluorescence. Catalytic activity also was measured for each of the heparin fractions. As the molecular weight of heparin varied from about 10,000 to 30,000, the average number of antithrombin and thrombin sites/heparin molecule varied from 1.0 to 2.1 and 2.4 to 6.8. In addition, the molar specific activity increased 5.7-fold, an increase which correlated directly with the product of the number of antithrombin III and thrombin molecules bound. Thus as the number of bound molecules increased with increased molecular weight, the rate of reaction/bound antithrombin III increased in proportion to the number of bound thrombin molecules and vice versa. This can be explained by assuming that heparin functions as a template for both proteins, that all bound thrombin and antithrombin III molecules are accessible to each other, and that the rate at which a bound molecule reacts is proportional to the number of molecules of its interacting counterpart bound. These observations and conclusions are similar to those of Hoylaerts et al. (Hoylaerts, M., Owen, W. G., and Collen, D. (1984) J. Biol. Chem. 259, 5670-5677), who demonstrated that the rate at which single molecules of antithrombin III, covalently attached to heparin, react increases as the thrombin binding capacity (chain length) of heparin increases.     

The heparin-accelerated neutralisation of bovine α and β thrombins by antithrombin III

The heparin-accelerated neutralisation of bovine α and β thrombins has been examined using a peptide substrate H-d-phenylalanyl-pipecolyl-arginine-paranitroanilide-HCl to measure thrombin amidase activity. α and β thrombins were both neutralised by antithrombin III and this neutralisation was further accelerated by the presence of small amounts of heparin. Low and high molecular weight heparin and heparins fractionated by their affinity for antithrombin III were all able to accelerate the neutralisation of α and β thrombin. This work is therefore unabel to confirm reports that α and β thrombins have different heparin sensitives.     

The heparin binding properties of heparin cofactor II suggest an antithrombin-like activation mechanism

The serpin heparin cofactor II (HCII) is a glycosaminoglycan-activated inhibitor of thrombin that circulates at a high concentration in the blood. The antithrombotic effect of heparin, however, is due primarily to the specific interaction of a fraction of heparin chains with the related serpin antithrombin (AT). What currently prevents selective therapeutic activation of HCII is the lack of knowledge of the determinants of glycosaminoglycan binding specificity. In this report we investigate the heparin binding properties of HCII and conclude that binding is nonspecific with a minimal heparin length of 13 monosaccharide units required and affinity critically dependent on ionic strength. Rapid kinetics of heparin binding indicate an induced fit mechanism that involves a conformational change in HCII. Thus, HCII binds to heparin in a manner analogous to the interaction of AT with low affinity heparin. A fully allosteric 2000-fold heparin activation of thrombin inhibition by HCII is demonstrated for heparin chains up to 26 monosaccharide units in length. We conclude that the heparin-binding mechanism of HCII is closely analogous to that of AT and that the induced fit mechanism suggests the potential design or discovery of specific HCII agonists.     

Antithrombin in vertebrate species: conservation of the heparin-dependent anticoagulant mechanism

Heparin is thought to regulate the rate of mammalian blood clotting by enhancing the activity of antithrombin, an inhibitor of coagulation enzymes. The present study establishes that this same inhibitor is present in the blood plasma of each of the terrestrial vertebrate groups including mammals, birds, reptiles, and amphibians. In each case, an inhibitor with remarkably similar properties to human antithrombin was isolated by affinity chromatography on immobilized porcine heparin. The purified vertebrate inhibitors all show the following physical and functional homologies to human antithrombin: (i) heparin-enhanced inhibition of both bovine thrombin and human Factor Xa, (ii) molecular masses of approximately 60,000, and (iii) heparin-induced increases in ultraviolet fluorescence. Also, the heparin-binding interaction of vertebrate antithrombins is highly selective with each demonstrating the same rigid specificity for heparin species fractionated on the basis of their affinity for human antithrombin. This common ability of vertebrate antithrombins to discriminate among heparins is accomplished by a nearly unvarying equilibrium binding constant for the high-affinity heparin species. Thus, the present results suggest that the anticoagulant relationship of heparin and antithrombin was established at an early point in the evolution of the coagulation system and has been highly conserved since that time.     

Primary structure of the heparin-binding site of type V collagen

The abilities of collagens, type I, II, III, IV, and V, to bind heparin were examined by heparin-affinity chromatography and binding studies with [35S]heparin. At a physiological pH and ionic strength, only type V collagen bound to heparin. Collagens type I and II showed higher affinities than types III and IV for heparin, but did not bind to a heparin column at a physiological ionic strength. The heparin binding site of type V collagen was located in a 30 kDa CNBr fragment of the alpha 1(V) chain, and the amino acid sequence of this fragment was determined. The 30 kDa fragment contained a cluster of basic amino acid residues, and enzymatic cleavage within this basic domain greatly reduced the heparin-binding activities of the resulting peptides. Thus this basic region is probably the heparin-binding site of type V collagen.