Prothrombin fragments. Ca2+ binding and activation kinetics.

The binding of Ca2+ to prothrombin and the intermediates of prothrombin activation was investigated by equilibrium dialysis using 45Ca2+ as the ligand. Scatchard plots of these data indicate that prothrombin (Mr = 70,000) has 10 to 11 Ca2+ binding sites which can be differentiated in terms of their binding affinity. Six of these Ca2+ binding sites have log Kassoc = 3.5 and all are found intact in the NH2-terminal segment (activation intermediate 3, Mr = 23,000) of the prothrombin molecule. Four or five additional weaker binding sites for Cz2+ with log Kassoc = 2.7 present in prothrombin are found intact in the remaining COOH-segment (activation intermediate 1, Mr = 51,000) of the prothrombin molecule. Upon further activation the Ca2+ binding sites residing in intermediate 1 are found intact in activation intermediate 4 (which constitutes the NH2-terminal segment of the intermediate 1 molecule). The remaining COOH-terminal portion (activation intermediate 2, Mr = 41,000) of the intermediate 1 molecule has no affinity for Ca2+. The activation of prothrombin and activation intermediates 1 and 2 was studied using these activators: Factor Xa alone, Factor Xa-Ca+, AND Factor Xa-Ca2+-phospholipid. The rate of thrombin production from prothrombin was progressively increased as Ca2+ and phospholipid were added to the system, whereas no significant increase in the rates of activation of intermediate 1 and 2 was observed. When Factor V was added to the Factor Xa-Ca2+-phospholipid system, the rate of activation of intermediate 1 was greatly enhanced. In the absence of Ca2+, Factor V had no effect on the rate of thrombin formation from intermediate 1. Factor V had no stimulatory effects on the rate of intermediate 2 activation. However, in the presence of an equimolar amount of intermediate 4, Factor V accelerated the conversion of intermediate 2 to thrombin. These studies indicate that the Ca2+ binding sites of the prothrombin molecule are contained in the "pro" fragment (intermediates 3 and 4) of the prothrombin molecule. Intermediate 1 and intermediate 2, both of which lack the strong Ca2+ binding sites of prothrombin, are poor substrates for the Factor Xa-Ca2+-phospholipid complex activation when compared to prothrombin. The addition of Factor V to the catalyst results in acceleration of the activation rate of intermediate 1 and an equimolar mixture if intermediates 2 and 4. These results lead us to conclude that the strong Ca2+ binding sites are the sites of phospholipid binding (intermediate 3), whereas the seak binding sites are the sites of Factor V binding (intermediate 4).