Modification of the N-terminus of human factor IX by defective propeptide cleavage or acetylation results in a destabilized calcium-induced conformation: effects on phospholipid binding and activation by factor XIa.

The propeptide of human coagulation factor IX (FIX) directs the gamma-carboxylation of the first 12 glutamic acid residues of the mature protein into gamma-carboxyglutamic acid (Gla) residues. The propeptide is normally removed before secretion of FIX into the blood. However, mutation of Arg-4 in the propeptide abolishes propeptide cleavage and results in circulating profactor IX in the blood. We studied three such genetic variants, factor IX Boxtel (Arg-4-->Trp), factor IX Bendorf (Arg-4-->Leu) and factor IX Seattle C (Arg-4-->Gln). These variant profactor IX molecules bind normally to anti-FIX:Mg(II) antibodies, which indicates that the mutations do not seriously affect gamma-carboxylation. Metal ion titration of the binding of variant profactor IX to conformation-specific antibodies demonstrates that the calcium-induced conformation is destabilized in the variant molecules. Also the binding of FIX Boxtel to phospholipids and its activation by factor XIa requires a high (>5 mM) calcium concentration. The three-dimensional structure of the Gla domain of FIX in the presence of calcium indicates that the acylation of the amino-terminus, rather than the presence of the propeptide, was responsible for the destabilization of the calcium-induced conformation. In order to confirm this, the alpha-amino group of Tyr1 of FIX was acetylated. This chemically modified FIX showed a similar destabilization of the calcium-induced conformation to variant profactor IX. Our data imply that the amino-terminus of FIX plays an important role in stabilizing the calcium-induced conformation of the Gla domain of FIX. This conformation is important for the binding to phospholipids as well as for the activation by factor XIa. Our results indicate that mutations in FIX that interfere with propeptide cleavage affect the function of the protein mainly by destabilizing the calcium-induced conformation.