Highly conserved residue arginine-15 is required for the Ca2+-dependent properties of the γ-carboxyglutamic acid domain of human anticoagulation Protein C and activated Protein C

Abstract

The function of the rigidly conserved amino acid residue R¹⁵ in the Ca²⁺/phospholipid-dependent properties of the γ-carboxyglutamic acid (Gla)-containing domain (GD) of human Protein C (PC) were investigated through site-directed mutagenesis strategies. A series of recombinant (r) mutants, namely r-[R¹⁵K]PC, r-[R¹⁵H]PC, r-[R¹⁵L]PC, and r-[R¹⁵W]PC, were constructed, expressed and purified, and their relevant properties investigated. As revealed by intrinsic fluorescence analysis, all of the variant proteins underwent Ca²⁺-dependent structural transitions. Nonetheless, they displayed altered binding properties to acidic phospholipid vesicles, and also did not interact with a monoclonal antibody specific for the type of Ca²⁺-dependent conformation of the GD that characterizes the wild-type protein. On conversion into their activated forms, these variant enzymes possessed less than 10% of the ex vivo plasma anticoagulant activity of wild-type r-PC. Similar activities were found when the r-active PC mutants were assayed directly for inactivation of factor Va and factor VIII, in the complete prothrombinase and tenase complexes respectively. We conclude that R¹⁵ is a critical residue in allowing the GD of PC, and probably of other proteins of this class, to adopt a Ca²⁺-dependent conformation that allows functional phospholipid binding, thus explaining the strict conservation of this amino acid residue in GD modules of various proteins. As a result of an analysis of structural models of the Ca²⁺ŐGD complex of PC, it is postulated that hydrogen bonds between the side chain of R¹⁵ and the functionally important Gla¹⁶ residue, as well as between the side chain of R¹⁵ and the carbonyl oxygen in the peptide bond of H¹⁰, are critical for adoption of a Ca²⁺-dependent conformation of the GD that allows functional phospholipid binding.