Activation loop 3 and the 170 loop interact in the active conformation of coagulation factor VIIa

Abstract

The initiation of blood coagulation involves tissue factor (TF)-induced allosteric activation of factor VIIa (FVIIa), which circulates in a zymogen-like state. In addition, the (most) active conformation of FVIIa presumably relies on a number of intramolecular interactions. We have characterized the role of Gly372(223) in FVIIa, which is the sole residue in activation loop 3 that is capable of forming backbone hydrogen bonds with the unusually long 170 loop and with activation loop 2, by studying the effects of replacement with Ala [G372(223)A]. G372A-FVIIa, both in the free and TF-bound form, exhibited reduced cleavage of factor X (FX) and of peptidyl substrates, and had increased K(m) values compared with wild-type FVIIa. Inhibition of G372A-FVIIa.sTF by p-aminobenzamidine was characterized by a seven-fold higher K(i) than obtained with FVIIa.sTF. Crystallographic and modelling data suggest that the most active conformation of FVIIa depends on the backbone hydrogen bond between Gly372(223) and Arg315(170C) in the 170 loop. Despite the reduced activity and inhibitor susceptibility, native and active site-inhibited G372A-FVIIa bound sTF with the same affinity as the corresponding forms of FVIIa, and burial of the N-terminus of the protease domain increased similarly upon sTF binding to G372A-FVIIa and FVIIa. Thus Gly372(223) in FVIIa appears to play a critical role in maturation of the S1 pocket and adjacent subsites, but does not appear to be of importance for TF binding and the ensuing allostery.