SummaryA method is described that, on the basis of the time course of amidolytic activity after the triggering of thrombin generation in normal plasma, allows the calculation of the velocity of prothrombin conversion independent of thrombin inactivating processes.It is shown how the reaction constants for the α2M-dependent and the α2M-independent thrombin inactivation processes can be obtained in a sample of whole plasma.The method is verified by demonstrating that the experimentally observed time courses of residual prothrombin and of α2M-thrombin complex coincide with those calculated from the time course of amidolytic activity, and by showing that the course of prothrombin conversion in plasma without α2-macroglobulin or AT III is adequately described if the α2M or AT Ill-dependent breakdown constants are taken zero in the calculations.It appears that the inactivation of thrombin, endogenously generated in whole plasma, is about half as fast as that of exogenous thrombin added to the plasma.A computer program is presented that carries out the relevant calculations.
beta 2-Glycoprotein I (beta 2GPI) is an essential cofactor for the binding to lipids of anticardiolipin antibodies (ACA), isolated from patients with anti-phospholipid syndrome. We used ellipsometry to study the binding of beta 2GPI and the beta 2GPI-mediated binding of ACA to planar membranes composed of phosphatidylcholine (PC) and 5-20 mol % phosphatidylserine (PS). No binding of beta 2GPI was observed to neutral (PC) membranes. Maximal binding of beta 2GPI was 3.2-3.6 pmol.cm-2. Affinity decreased strongly with decreasing PS content; increasing the NaCl and CaCl2 concentrations also led to a decrease in affinity. At physiologic conditions (10 mol % PS, 120 mM NaCl, and 3 mM CaCl2), a Kd of 14 microM was observed. Binding constants were insensitive to the chemical composition of the negatively charged phospholipid headgroup. ACA (1.25-10 micrograms.mL-1) caused a 30-40-fold enhancement of beta 2GPI binding to PS/PC membranes (20 mol % PS), resulting in the binding of about 2 pmol.cm-2 divalent ACA-(beta 2GPI)2 complexes at 100 nM beta 2GPI. In the absence of beta 2GPI, binding of ACA was negligible. Ad- and desorption kinetics of ACA-beta 2GPI complexes indicate that the initial monovalent association of ACA to membrane-bound beta 2GPI is rapidly followed by formation of divalent ACA-(beta 2GPI)2 complexes. Experiments with monovalent Fab1 fragments of ACA showed no appreciable effect on the beta 2GPI binding to lipid, substantiating the notion that divalent interactions are essential for the high-affinity binding of ACA-beta 2GPI. The anticoagulant effect of ACA is rationalized by the observation that binding of ACA-beta 2GPI complexes to the PSPC membrane severely restricts the adsorption of blood coagulation factor Xa.
A chimeric protein was produced with the N-terminal domain (amino acids 1-45) of annexin I and the core of annexin V (amino acids 19-320). This protein, annexin IN-VC, has a similar Ca2+ requirement for binding to phospholipid bilayers of 20% phosphatidylserine (PS)/80% phosphatidylcholine (PC) as annexin V. In contrast to annexin V, this protein has a strong potency to aggregate phospholipid vesicles as is shown by turbidimetric measurements and cryo-electron microscopy. Ellipsometry was employed to study quantitatively the phenomenon of phospholipid vesicle adhesion to annexin IN-VC bound to a planar phospholipid bilayer. The amount of phospholipid vesicles bound by annexin IN-VC on the planar bilayer is proportional to its surface coverage and can be inhibited by coadsorption of annexin V on the planar bilayer or by shielding the phospholipid surface of the vesicles with blood coagulation factor Va. Annexin IN-VC, like annexin V, does not bind to pure PC bilayers, but its adsorption on anionic phospholipid bilayers brings about the capacity to bind pure PC vesicles. This suggests that annexin IN-VC generates or exposes after binding to anionic phospholipids another phospholipid binding site, that differs from the annexin V phospholipid binding site. Collectively, the data suggest that two-dimensional cluster formation of annexin IN-VC on a bilayer with anionic phospholipids is involved in vesicle adherence.
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