Clotting of bovine fibrinogen. Calcium binding to fibrin during clotting and its dependence on release of fibrinopeptide B

Abstract

Polymerization of bovine fibrinogen actedupon by thrombin is accompanied by binding of Ca2+ and a concomitant decrease of the free Ca2+ concentration. The latter can be recorded by a Ca2+-selective electrode as a shift in the electrode potential. The shift shows marked dependence on the initial free Ca2+ concentration, being maximal at about 104.1 M and decreasing sharply on either side of this. Thus, the effect is limited to the 10-3 - 10-5 M free Ca2+ concentration range. From the initial and the final value of the electrode potential during a clotting experiment, the amount of Ca2+ bound to fibrinogen and fibrin, respectively, can be calculated. The difference between the two, plotted against free Ca2+ concentration, gives a bell-shaped curve. This indicates that the reason for the Ca2+ binding is a shift of the pK of some groups from a lower to a higher value. The recordings can be used for evaluation of the kinetics of the Ca2+ uptake. However, they have to be corrected for the effect of the continuous shift in the free Ca2+ concentration during the experiment. The reaction does not follow simple kinetics, showing a lag period. Therefore, rates were estimated from inverse half-reaction times. Half-times of the corrected curves show that the reaction is first order with respect to thrombin. Moreover, the rate of Ca2+ uptake is identical with that of the conformational change seen in differential scanning calorimetry [Donovan, J. W., and Mihalyi, E. (1985) Biochemistry 24, 3434]. The inverse rate and the final corrected Ca2+ uptake increase linearly with the initial fibrinogen concentration. Concomitant estimates of fibrinopeptide A and B release showed that the Ca2+ uptake runs parallel to the release of fibrinopeptide B. Fibrinopeptide A was released largely during the lag period of the Ca2+ uptake. In agreement with this, clotting with Ancrod, an enzymatic that liberates only fibrinopeptide A, was not accompanied by binding of Ca2+. Thus, polymerization is not sufficient for the Ca2+ uptake to occur; liberation of fibrinopeptide B seems to be obligatory. Further support for this was obtained with experiments with the polymerization inhibitor Gly-Pro-Arg-Pro. The tetrapeptide inhibits polymerization and also, proportional to this, release of fibrinopeptide B [Hurlet-Jensen, A., Cummins, H. Z., Nossel, H. L., and Liu, C. Y. (1982) Thromb. Res. 27, 419; Lewis, S. D., Shields, P. P., and Shafer, J. A. (1985) J. Biol. Chem. 260, 10192]. Calcium uptake was also depressed by the tetrapeptide in a way similar to its effect upon fibrinopeptide B release.