In the A alpha-chain gene coding for an abnormal fibrinogen (fibrinogen Marburg) we identified a single base substitution (A-->T) that changes the codon A alpha 461 AAA (Lys) to TAA (Stop). The propositus was found to be homozygous for the mutation, whereas the father and five siblings were heterozygous, and three other siblings contained only the normal sequence. The stop codon at position 461 results in the deletion of the carboxyl-terminal segment A alpha 461–610. Purified fibrinogen Marburg contained an A alpha-chain with a relative molecular weight of approximately 47,000. The FpA release by thrombin was not affected by this deletion, whereas the fibrin polymerization was strongly decreased. The binding of endothelial cells to immobilized fibrinogen Marburg was almost completely abolished compared with normal fibrinogen. Fibrinogen Marburg contained a substantial amount of albumin linked to the fibrinogen molecule by disulfide bonds, and these fibrinogen-albumin complexes were also present in plasma. The plasma fibrinogen concentration of the propositus was measured by three different methods: a functional method (< 0.25 mg/mL), an immunologic method using polyclonal antibodies (0.6 mg/mL), and an immunologic method based on two monoclonal antibodies specific for the amino- terminus and carboxyl-terminus of the A alpha-chain (< 0.05 mg/mL). Using the two immunologic methods, it appeared that only 10% to 15% of the plasma fibrinogen of the heterozygous siblings was abnormal.
SummaryWe studied the influence of Factor XIII a (F XIII a) activity on the lysis rate of fresh whole human blood clots, without using anticoagulants. Clotting was induced by exogenous thrombin, lysis by tissue-type Plasminogen Activator (t-PA) added before clotting. After various periods of time, lysis rates were determined by measuring the radioactivity in the supernatant of the clot originating from 125I-Fibrinogen added before clotting.Lysis rates were determined in the presence of endogenous F XHIa and compared with those obtained after specific inhibition of F XIII a activity. We used an IgG fraction of an antiserum quenching the F XIII a activity. Addition of increasing amounts of the antibodies to normal blood resulted in a dramatic increase in clot lysis rate, concomitant with loss of F XIII activity. Lysis of blood clots from a patient with a congenital, homozygous, functional α2-Antiplasmin (α2-AP) deficiency (α2-AP-Enschede) was not or slightly increased by the anti F XIII antibodies indicating that fibrin-fibrin crosslinking per se does not contribute essentially to resistance of the blood clot against fibrinolysis. Both active α2-AP and F XIII a are required for the major part of the F XIII-dependent resistance of whole blood clots against lysis.
The effect of purified human activated protein C (APC) and protein S on fibrinolysis was studied by using an in vitro blood clot lysis technique. Blood clots were formed from citrated blood (supplemented with 125I-fibrinogen) by adding thrombin and Ca2+-ions; lysis of the clots was achieved by adding tissue-type plasminogen activator. The release of labeled fibrin degradation products from the clots into the supernatant was followed in time. We clearly demonstrated that APC accelerates whole blood clot lysis in vitro. The effect of APC was completely quenched by antiprotein C IgG, pretreatment of APC with diisopropylfluorophosphate, and preincubation of the blood with antiprotein S IgG. This demonstrates that both the active site of APC and the presence of the cofactor, protein S, are essential for the expression of the profibrinolytic properties. At present, the substrate of APC involved in the regulation of fibrinolysis is not yet known. Analysis of the radiolabeled fibrin degradation products demonstrated that APC had no effect on the fibrin cross-linking capacity of factor XIII.
Balb/c mice were immunized with a mixture of fibrin degradation products (XDPs) prepared by complete lysis of a human blood clot by tissue-type plasminogen activator and purified by immunoaffinity chromatography. Spleen cells of the mice were fused with P3 X 63 Ag 8653 myeloma cells. A clone (FDP 14) was selected that produces monoclonal antibodies (MoAbs) of the IgG1 kappa type that react with a neoantigenic determinant exposed in these XDPs, but not in intact fibrinogen or in fibrin monomers. Furthermore, the MoAb is reactive with some pure, individual degradation products of fibrinogen (fragments X, Y, E, and the N-terminal disulphide knot) and with the fibrinogen B beta-chain but not with A alpha- and gamma-chains or with fragments D, FCB-2 and FCB-3. Comparison of the known primary structures of these fibrinogen fragments indicates that the stretch B beta 54–118 comprises at least an important part of the epitope recognized by FDP-14. Apparently, this stretch contributes importantly to a neoantigenic determinant that is not functional in intact fibrinogen and fibrin monomer and that can be made functional by reduction of fibrinogen, or by digestion with plasmin or CNBr.
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