Craig D. Dickinson

Active site modification of factor VIIa affects interactions of the protease domain with tissue factor.

In the initiation of coagulation, tissue factor (TF) allosterically activates the serine protease factor VIIa (VIIa) through specific interactions with protease domain residues. These interactions, and consequently affinity for TF, may be influenced by conformational changes in the protease domain that result from zymogen-enzyme transition or occupancy of the active site by tight binding inhibitors. In functional competition and direct binding analysis, we determined affinities for zymogen and enzyme species of wild-type VII and of mutants at protease domain residues that contact TF. We demonstrate that TF binding is not influenced by zymogen activation, indicating that the protease domain of zymogen and enzyme dock similarly with TF. In contrast, active site occupancy enhanced the affinity for TF by predominantly decreasing the dissociation rate of the TF·VIIa complex. Of the three interface residues studied, only Met306 played a major role in the inhibitor-induced increase in affinity. Met306 is also important for transmitting the allosteric changes from TF to the active site, resulting in enhanced catalysis. This study thus provides evidence for a bidirectional conformational interdependence of the interface residue Met306 and the active site of VIIa.

Macromolecular Substrate Affinity for the Tissue Factor-Factor VIIa Complex Is Independent of Scissile Bond Docking

The upstream coagulation enzymes are homologous trypsin-like serine proteases that typically function in enzyme-cofactor complexes, exemplified by coagulation factor VIIa (VIIa), which is allosterically activated upon binding to its cell surface receptor tissue factor (TF). TF cooperates with VIIa to create a bimolecular recognition surface that serves as an exosite for factor X binding. This study analyzes to what extent scissile bond docking to the catalytic cleft contributes to macromolecular substrate affinity. Mutation of the P1 Arg residue in factor X to Gln prevented activation by the TF·VIIa complex but did not reduce macromolecular substrate affinity for TF·VIIa. Similarly, mutations of the S and S′ subsites in the catalytic cleft of the enzyme VIIa failed to reduce affinity for factor X, although the affinity for small chromogenic substrates and the efficiency of factor X scissile bond cleavage were reduced. Thus, docking of the activation peptide bond to the catalytic cleft of this enzyme-cofactor complex does not significantly contribute to affinity for macromolecular substrate. Rather, it appears that the creation of an extended macromolecular substrate recognition surface involving enzyme and cofactor is utilized to generate substrate specificity between the highly homologous, regulatory proteases of the coagulation cascade.

Allosteric Regulation of the Cofactor-Dependent Serine Protease Coagulation Factor VIIa

The integration of structure and function analysis of the tissue factor-factor VIIa complex has provided a detailed view of the functional surface of the extrinsic activation complex. An incomplete zymogen to enzyme transition is responsible for the strict cofactor dependence of catalytic function of factor VIIa. The mutational analysis demonstrates that factor VIIa is allosterically regulated by specific conformational linkages that involve the cofactor binding site, the catalytic cleft, and the macromolecular substrate exosite. Regions of the flexible activation domain appear to play an important role in the allosteric regulation of this cofactor-dependent coagulation serine protease.

Ca2+ binding to the first epidermal growth factor module of coagulation factor VIIa is important for cofactor interaction and proteolytic function.

Epidermal growth factor-like (EGF) domain Ca2+ binding sites in the homologous coagulation factors VII, IX, and X stabilize the structural orientation of the γ-carboxyglutamic acid-rich (Gla) domain relative to EGF-1. Site-directed mutagenesis was employed here to analyze the functional importance of Ca2+ binding to EGF-1 in factor VIIa (VIIa), which initiates coagulation in complex with its cofactor, tissue factor (TF). Ala replacements for Asp63 or Gln49resulted in reduced TF affinity concordant with the number of eliminated Ca2+-coordinating oxygen atoms in the respective side chains. Ca2+ binding to EGF-1 had no major direct effect on contacts with TF residue Gln110 or on interactions of VIIa residues Arg79 and Phe40, suggesting that the stabilized Gla-EGF-1 orientation affects overall docking. Gly, Ala, and Glu replacements at Asp46, which is a Ca2+-coordinating residue at the Gla aromatic stack carboxyl terminus, are consistent with the notion that an increased flexibility of the Gla domain relative to EGF-1 contributes significantly to loss of function. Certain mutants in the EGF-1 Ca2+ site had reduced proteolytic function, suggesting the importance of the high affinity Ca2+ binding site for macromolecular substrate interaction.