Expression, purification, and characterization of recombinant human factor X.

A system is described for producing recombinant factor X with properties very similar to human plasma factor X. Optimization of the expression system for factor X resulted in the finding that human kidney cells (293 cells) are superior to the widely utilized baby hamster kidney cells (BHK cells) for the expression of functional factor X. It was also determined that production of factor X by 293 cells requires the substitution of the -2 residue (Thr-->Arg) which affords the removal of the factor X propeptide. Purification of recombinant and plasma factor X is accomplished using a calcium-dependent monoclonal antibody directed against the gla domain. The proteins are comparable by sodium dodecyl sulfate polyacrylamide gel electrophoresis. The rate and extent of activation by the factor X coagulant protein from Russell's viper venom and by factors IXa and VIIIa are similar; activation of the recombinant protein by VIIa and tissue factor is mildly faster. The activated enzymes have the same activity toward a chromogenic substrate and the biologic substrate, prothrombin. Both enzymes have the same apparent affinity for the activated platelet surface as judged by their ability to activate prothrombin. Finally, inhibition by antithrombin, with or without heparin, and inhibition by the tissue factor pathway inhibitor are equivalent. Recombinant factor X produced by this method is therefore well suited for probing structure-function relationships by mutational analysis.

Factor XSt. Louis II. Identification of a glycine substitution at residue 7 and characterization of the recombinant protein.

A molecular defect in factor X (fX) results from a point mutation that causes glycine substitution for gamma-carboxylated glutamic acid at position 7. The variant (fXSt. Louis II) and wild type (fXWT) proteins were produced in a mammalian expression system and characterized. fXSt. Louis II has <1% and approximately 3% of normal clotting activity in modified prothrombin time and partial thromboplastin time assays, respectively. The rate of activation of fXSt. Louis II by factor VIIa and tissue factor is undetectable under conditions that result in complete activation of fXWT; activation by factors VIIIa and IXa is approximately 30% of normal activation. The X-activating protein from Russell's viper venom activates fXSt. Louis II completely but at a reduced rate. Thrombin generation on phoshopolipid vesicles or activated platelets is approximately 30% or approximately 5%, respectively. Membrane-dependent autolysis is markedly reduced for fXSt. Louis II. In reactions that are not surface-dependent, fXSt. Louis II is nearly identical to that of fXWT. The rate of inhibition by antithrombin is indistiguishable, as is the rate of thrombin formation in the absence of phospholipid, with or without factor Va.