Mammalian cell surfaces are modified by complex arrays of glycoproteins, glycolipids and polysaccharides, many of which terminate in sialic acid and have central roles in essential processes including cell recognition, adhesion and immunogenicity. Sialylation of glycoconjugates is performed by a set of sequence-related enzymes known as sialyltransferases (STs). Here we present the crystal structure of a mammalian ST, porcine ST3Gal-I, providing a structural basis for understanding the mechanism and specificity of these enzymes and for the design of selective inhibitors.
The binding of recombinant nematode anticoagulant protein c2 (NAPc2) to either factor X or Xa is a requisite step in the pathway for the potent inhibition of VIIa tissue factor. We have used NAPc2 as a tight binding probe of human Xa to investigate protein substrate recognition by the human prothrombinase complex. NAPc2 binds with high affinity (K d ϳ1 nM) to both X and Xa in a way that does not require or occlude the active site of the enzyme. In contrast, NAPc2 is a tight binding, competitive inhibitor of protein substrate cleavage by human Xa incorporated into prothrombinase with saturating concentrations of membranes and Va. By fluorescence binding studies we show that NAPc2 does not interfere with the assembly of human prothrombinase. These are properties expected of an inhibitor that blocks protein substrate recognition by targeting extended macromolecular recognition sites (exosites) on the enzyme complex. A weaker interaction (K d ؍ 260-500 nM) observed between NAPc2 and bovine X was restored to a high affinity one in a recombinant chimeric bovine X derivative containing 25 residues from the COOH terminus of the proteinase domain of human X. This region implicated in binding NAPc2 is spatially adjacent to a site previously identified as a potential exosite. Despite the weaker interaction with bovine Xa, NAPc2 was a tight binding competitive inhibitor of protein substrate cleavage by bovine prothrombinase as well. Extended enzymic surfaces elucidated with exosite-directed probes, such as NAPc2, may define a unique region of factor Xa that is modulated following its assembly into prothrombinase and in turn determines the binding specificity of the enzyme complex for its protein substrate.The proteolytic activation of prothrombin is catalyzed by the prothrombinase complex of coagulation (2-5). Prothrombinase assembles through membrane-dependent interactions between the serine proteinase, factor Xa, and the protein cofactor, factor Va (2, 3). Although solution-phase Xa is a competent enzyme, its incorporation into prothrombinase yields a profound increase in the rate of thrombin formation (2, 3).Prothrombin is the only known protein substrate cleaved efficiently by prothrombinase (2, 6). Such stringent selectivity is not evident in the action of factor Xa on oligopeptidyl substrates, nor is the rate of peptidyl substrate hydrolysis significantly enhanced upon assembly of factor Xa into prothrombinase (7,8). Thus, the narrow and defined specificity of prothrombinase toward its protein substrate is unlikely to be solely explained by the specific recognition of residues surrounding the scissile bond by the active site of factor Xa within the enzyme complex.Mechanistic studies of bovine prothrombinase function have borne out this suggestion (9 -11). A series of studies indicate that recognition of the biological substrate is achieved through stepwise interactions of the protein substrate at an extended macromolecular recognition site (exosite) in prothrombinase removed from the catalytic site of Xa, followed b...
The interaction of factor Xa with factor Va on membranes to form prothrombinase profoundly increases the rate of the proteolytic conversion of prothrombin to thrombin. We present the characterization of an RNA aptamer (RNA 11F7t ) selected from a combinatorial library based on its ability to bind factor Xa. We show that RNA 11F7t inhibits thrombin formation catalyzed by prothrombinase without obscuring the active site of Xa within the enzyme complex. Selective inhibition of protein substrate cleavage arises from the ability of the aptamer to bind to factor Xa and exclude interactions between the proteinase and cofactor within prothrombinase. Competition for enzyme complex assembly results from the binding of RNA 11F7t to factor Xa with nanomolar affinity in a Ca 2؉ -dependent interaction. RNA 11F7t binds equivalently to the zymogen factor X as well as derivatives lacking ␥-carboxyglutamic acid residues. We suggest that the ability of RNA 11F7t to compete for the Xa-Va interaction with surprisingly high affinity likely reflects a significant contribution from its ability to indirectly impact regions of Xa that participate in the proteinase-cofactor interaction. Thus, despite the complexity of the macromolecular interactions that underlie the assembly of prothrombinase, efficient inhibition of enzyme complex assembly and thrombin formation can be achieved by tight binding ligands that target factor Xa in a discrete manner.
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