Accelerating ability of synthetic oligosaccharides on antithrombin inhibition of proteinases of the clotting and fibrinolytic systems. Comparison with heparin and low-molecular-weight heparin.

The abilities of three synthetic oligosaccharides to accelerate antithrombin inhibition of ten clotting or fibrinolytic proteinases were compared with those of unfractionated, fractionated high-affinity and low-molecular-weight heparins. The results show that the anticoagulant effects of the latter three heparins under conditions approximating physiologic are exerted almost exclusively by acceleration of the inactivation of thrombin, factor Xa and factor IXa to near diffusion-controlled rate constants of approximately 10(6) - 10(7) M(-1).s(-1). All other proteinases are inhibited with at least 20-fold lower rate constants. The anti-coagulant ability of the synthetic regular (fondaparinux) and high-affinity (idraparinux) pentasaccharides is due to a common mechanism, involving acceleration of only factor Xa inhibition to rate constants of approximately 10(6) M(-1).s(-1) . A synthetic hexadecasaccharide, containing both the pentasaccharide sequence and a proteinase binding site, exerts its anticoagulant effect by accelerating antithrombin inactivation of both thrombin and factor Xa to rate constants of approximately 10(6) - 10(7) M(-1).s(-1), although thrombin appears to be the more important target. In contrast, factor IXa inhibition is appreciably less stimulated. The conformational change of antithrombin induced both by the pentasaccharides and longer heparins contributes substantially, approximately 150-500-fold, to accelerating the inactivation of factors Xa, IXa and VIIa and moderately, approximately 50-fold, to that of factor XIIa and tissue plasminogen activator inhibition. The bridging effect due to binding of antithrombin and proteinase to the same, long heparin chain is dominating, approximately 1000-3000-fold, for thrombin inhibition and is appreciably smaller, although up to approximately 250-350-fold, for the inactivation of factors IXa and XIa. These results establish the proteinase targets of heparin derivatives currently used in or considered for thrombosis therapy and give new insights into the mechanism of heparin acceleration of antithrombin inhibition of proteinases.

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.

Heparin and calcium ions dramatically enhance antithrombin reactivity with factor IXa by generating new interaction exosites.

Blood coagulation factor IXa has been presumed to be regulated by the serpin, antithrombin, and its polysaccharide activator, heparin, but it has not been clear whether factor IXa is inhibited by the serpin with a specificity comparable to that for thrombin and factor Xa or what determinants govern this specificity. Here we show that antithrombin is essentially unreactive with factor IXa in the absence of heparin (k(ass) approximately 10 M(-1) s(-1)) but undergoes a remarkable approximately 1 million-fold enhancement in reactivity with this proteinase to the physiologically relevant range (k(ass) approximately 10(7) M(-1) s(-1)) when activated by heparin in the presence of physiologic levels of calcium. This rate enhancement is shown to derive from three sources: (i) allosteric activation of antithrombin by a sequence-specific heparin pentasaccharide (300-500-fold), (ii) allosteric activation of factor IXa by calcium ions (4-8-fold), and (iii) heparin bridging of antithrombin and factor IXa augmented by calcium ions (130-1000-fold depending on heparin chain length). Mutagenesis of P6-P3' reactive loop residues of antithrombin further reveals that the reactivity of the unactivated inhibitor is principally determined by the P1 Arg residue, whereas exosites outside the loop which are present on the activated serpin and on heparin are responsible for heparin enhancement of this reactivity. These results together with our previous findings demonstrate that exosites are responsible for the unusual specificity of antithrombin and heparin for three clotting proteases with quite distinct substrate specificities.