Abstract
The serpin, antithrombin, requires allosteric activation by a sequence-specific pentasaccharide unit of heparin or heparan sulfate glycosaminoglycans to function as an anticoagulant regulator of blood clotting proteases. Surprisingly, X-ray structures have shown that the pentasaccharide produces similar induced-fit changes in the heparin binding site of native and latent antithrombin despite large differences in the heparin affinity and global conformation of these two forms. Here we present kinetic evidence for similar induced-fit mechanisms of pentasaccharide binding to native and latent antithrombins and kinetic simulations which together support a three-step mechanism of allosteric activation of native antithrombin involving two successive conformational changes. Equilibrium binding studies of pentasaccharide interactions with native and latent antithrombins and the salt dependence of these interactions suggest that each conformational change is associated with distinct spectroscopic changes and is driven by a progressively better fit of the pentasaccharide in the binding site. The observation that variant antithrombins that cannot undergo the second conformational change bind the pentasaccharide like latent antithrombin and are partially activated suggests that both conformational changes contribute to allosteric activation, in agreement with a recently proposed model of allosteric activation.
Highlights
Antithrombin, a member of the serpin superfamily of protein protease inhibitors, performs a key anticoagulant function in vertebrates by regulating the activity of blood coagulation cascade proteases [1,2]
That the first binding step is in rapid equilibrium is supported by the observation that progress curves for heparin pentasaccharide binding to native antithrombin show no lags over a wide range of saccharide concentrations [21]
These findings suggest that native and latent antithrombins bind the pentasaccharide and undergo induced conformational changes that are highly similar but not identical
Summary
Antithrombin, a member of the serpin superfamily of protein protease inhibitors, performs a key anticoagulant function in vertebrates by regulating the activity of blood coagulation cascade proteases [1,2]. Rapid kinetic studies of heparin pentasaccharide binding to antithrombin have shown that allosteric activation is a two-step process in which the negatively charged pentasaccharide recognizes and binds to a positively charged site on the serpin and induces the protein into an activated conformational state that is reported by CD, UV and fluorescence changes [9,21].
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