Roman Procyk

Native fibrin gel networks observed by 3D microscopy, permeation and turbidity

Native fully hydrated fibrin gels formed at different fibrinogen and thrombin concentrations and at different ionic strengths were studied by confocal laser 3D microscopy, liquid permeation and turbidity. The gels were found to be composed of straight rod-like fiber elements that often came together at denser nodes. In gels formed at high fibrinogen concentrations, or with high amounts of thrombin, the spaces between the fibers decreased, indicating a decrease of gel porosity. The fiber strands were also shorter. Gel porosity decreased dramatically in gels formed at the high ionic strengths. Shorter fibers were observed and fiber swelling occurred at ionic strengths above 0.24. Quantitative parameters for gel porosity, fiber mass/length ratio and diameter were also derived by liquid permeation and turbidometric analyses of the gels. Permeation analysis showed that gel porosity (measured as Ks) decreased in gels formed at higher fibrin and thrombin concentrations in agreement with the porosity observed by microscopy. The turbidometric analysis showed good agreement with the permeation data for gels formed at various thrombin concentrations, but supported the permeation data more poorly in gels formed at different fibrinogen concentrations, especially above 2.5 mg/ml. Turbidometric analysis showed that the fiber mass/length ratio and diameter decreased in gels formed at ionic strength up to 0.24, as was seen in the permeation study. However, at higher ionic strengths swelling of the fibers was suggested from the gel turbidity data and this was also indicated by microscopy. These findings are discussed in relation to previous hydrodynamic and electron microscopic studies of fibrin gels.

FXIII induced gelation of human fibrinogen — An alternative thiol enhanced, thrombin independent pathway

Factor XIII induced gelation of human fibrinogen in the presence of calcium ions. At the end of this reaction between 95 and 100% of the fibrinogen was incorporated into the gel matrix. The gelation was dramatically enhanced by DTT. Cysteine and beta-mercaptoethanol also enhanced the reaction, but less efficiently. Thrombin activated factor XIII led to shortened gelation time and increased the rate of gelation. The reaction was inhibited by p-chloromercuribenzoate and iodoacetamide. Neither fibrinopeptide A, nor fibrinopeptide B were released during gelation, while quantitative release of FPA by thrombin was demonstrated from preformed gel matrices. SDS-PAGE showed the presence of gamma-dimers and alpha-polymers in the gel matrix. In the clot supernatants gamma-dimers were observed already before the gel point. We also observed that the clotting of fibrinogen by thrombin was perturbed by DTT. Preincubation of fibrinogen with calcium ions prevented this effect of DTT.

Native Fibrin Gel Networks and Factors Influencing their Formation in Health and Disease

Hydrated fibrin gels were studied by confocal laser 3D microscopy, liquid permeation and turbidity. The gels from normal fibrinogen were found to be composed of straight rod-like fiber elements which sometimes originated from denser nodes. In gels formed at increasing thrombin or fibrinogen concentrations, the gel networks became tighter and the porosity decreased. The fiber strands also became shorter. Gel porosity of the network decreased dramatically in gels formed at increasing ionic strengths. Shortening of the fibers were observed and fiber swelling occurred at ionic strength above 0.24. Albumin and dextran, when present in the gel forming system, affected the formation of more porous structures with strands of larger mass-length ratio and fiber thickness. This type of gels were also formed in plasma. Albumin and lipoproteins may be among the determinants for the formation of this type of gel structure in plasma. Gels formed when factor XIIIa instead of thrombin was used as catalyst for gelation showed a completely different structure in which lumps of polymeric material were held together by a network of fine fiber strands. Our studies have also shown that the methodologies employed may be useful in studies of gel structures in certain dysfibrinogenemias as well as in other diseases. We give examples of two patients with abnormal fibrinogen and of patients with ischaemic heart disease.

Factor XIII catalyzed formation of fibrinogen-fibronectin oligomers--a thiol enhanced process.

Fibrinogen and plasma fibronectin were shown to interact in the presence of factor XIIIa. The reaction was enhanced by dithiothreitol and was accompanied by an increase in the turbidity of the solution and the formation of particulate matter and gel structures. At a constant concentration of fibrinogen the turbidity increase was dependent on the fibronectin concentration and at a constant concentration of fibronectin, on the fibrinogen concentration. Kinetic experiments showed that an initial step in the reaction between fibrinogen and fibronectin was the formation of a transient intermediate containing 1 mole of fibrinogen and 1 mole of fibronectin. Transient intermediates of larger molecular weight and containing both fibrinogen and fibronectin were also formed. These heterooligomers eventually reached huge molecular sizes and at early times formed particulate matter that sedimented on centrifugation. The predominant molecular species formed in an equimolar mixture of fibrinogen and fibronectin were heteropolymers. Small amounts of homopolymers composed of fibrinogen and possibly also homopolymers of fibronectin were detected. The results are discussed in terms of reaction mechanism and potential importance of this novel oligomerization pathway in haemostasis, thrombosis and tissue repair.

Factor XIII-induced crosslinking in solutions of fibrinogen and fibronectin.

In solutions containing fibrinogen and fibronectin, factor XIIIa catalyzes the formation of two types of crosslinked polymers: hybrid oligomers consisting of equimolar amounts of fibrinogen and fibronectin, and fibrinogen oligomers. The two types of oligomers are produced in amounts proportional to the starting concentration of fibronectin and fibrinogen in the reaction mixture. Increasing the fibronectin concentration relative to the fibrinogen concentration results in the production of more hybrid and less fibrinogen type oligomers. The lowest molecular weight hybrid oligomer, a dimer, is formed by ligation of one molecule of fibrinogen and fibronectin. The A alpha-chain of fibrinogen and one fibronectin subunit participate in the crosslinking. Larger size hybrid oligomers form by the joining of two hybrid dimers to each other via gamma-chain dimerization in the fibronectin moiety of the dimers. In fibrinogen oligomer formation, fibrinogen molecules are ligated by gamma-chain dimerization in a step-wise fashion producing fibrinogen dimers, trimers, tetramers, etc. without A alpha-chain crosslinking. The hybrid type and the fibrinogen type of oligomer grow in size and eventually become crosslinked to each other yielding large molecular weight complexes that interact to form a gel network.

Fibrin - recombinant human factor XIII a-subunit association

The association of factor XIII a-subunits with fibrin was characterized using recombinant human placental factor XIII (rFXIII) and native fully hydrated fibrin clots formed from purified fibrinogen and thrombin. Binding was assessed using small columns containing fibrin and perfusing them with radioiodinated rFXIII. Results show that thrombin activation of rFXIII led to fibrin binding. The association was partially reversible since much of the bound enzyme could be removed by percolating clots with more buffer. Binding was blocked by antibody directed against the COOH-terminal part of fibrinogen A alpha-chain (A alpha 389-402) and also by the COOH-terminal A alpha-chain peptide fragment A alpha 241-476 (Hi2-DSK).

Flow and antibody binding properties of hydrated fibrins prepared from plasma, platelet rich plasma and whole blood.

Previous studies, using cross-linked fibrin prepared from purified fibrinogen, showed low binding of a fibrin-specific monoclonal antibody designated T2G1 (Procyk et al., Blood 77:1469-75, 1991). In this study we investigated the binding of T2G1 and one other antibody to clots prepared from platelet poor plasma (PPP), platelet rich plasma (PRP) and whole blood. In contrast to our previous study, we used unlabelled antibodies and quantitated the level bound by ELISA, measuring antibody concentration in the non-adsorbed fraction. Antibody T2G1 bound 1.35 +/- 0.10 pmol/pmol fibrin (n = 11) to whole blood columns, 1.64 +/- 0.18 (n = 10) to PRP columns and 1.58 +/- 0.13 (n = 8) to PPP columns. The binding of T2G1 to columns made from purified fibrinogen was 0.78 +/- 0.05 pmol/pmol fibrin (n = 15). An antibody to a conformation-dependent epitope on Fragment D (Fd4-7B3) bound in comparable amounts to the different fibrins. Flow data show that whole blood columns, and also, but to a lesser extent those made with plasma, had a higher flow rate, permeability and fiber mass-length ratio than columns prepared from fibrinogen indicating a more coarse fibrin network. These data show that the presence of other proteins and blood cells, similar to what might occur in vivo, not only lead to an increase in the permeability of gels but also allow for better exposure of some epitopes.

Fibrinogenemia Tampere. A dysfibrinogenemia with defective gelation and thromboembolic disease

Fibrinogen Tampere was found in a woman with severe thromboembolic disease. The thrombin induced clotting time of her plasma and purified fibrinogen was slightly prolonged. The activation of fibrinogen Tampere appeared to be normal but subsequent gelation was defective. We studied fibrin gels formed at different ionic strengths and at different fibrinogen and calcium concentrations by liquid permeation, turbidity, and 3D laser microscopy. Crosslinking was studied by SDS-gel electrophoresis. The gels formed from fibrinogen Tampere were at ionic strength above 0.2 much tighter and had lower fiber mass-length ratios than normal gels as judged by permeability and turbidity data. At ionic strength 0.15 and at different calcium concentrations analysis by permeability showed the same results for fibrinogen Tampere as for normal gels. Analysis by turbidity at ionic strength 0.15 suggested swelling of the fibers at low calcium concentrations. 3D microscopy revealed perturbed clot architecture under all conditions. In fibrin gels from fibrinogen Tampere, the gamma-chain crosslinking was normal but the crosslinking of alpha-chains was delayed at ionic strength 0.2 and also at lower ionic strengths on lowering the calcium concentration. The abnormal gelation may be due to a mutation in the fibrinogen molecule. Tendency to form tight fibrin gels and/or insufficient crosslinked fibrin matrix may be pathogenetic in this thrombotic disease.

Fibrinogen Aarhus and factor XIII induced polymerization and gel formation

Fibrinogen Aarhus is an abnormal fibrinogen for which the clotting time with thrombin is greatly prolonged both in plasma and in the isolated fibrinogen. The whole blood clotting time is only slightly prolonged. The patient with this fibrinogen has no bleeding tendency. In this report we have investigated fibrinogen Aarhus in two alternative, thrombin independent polymerization and gelation pathways. These pathways are the factor XIII dependent oligomerization and gelation of fibrinogen, and heteropolymer (fibrinogen‐fibronectin) formation which also is catalysed by factor XIII. Both of these reactions are qualitatively the same in fibrinogen Aarhus as in normal fibrinogen, but the rate of oligomerization is somewhat slower in fibrinogen Aarhus. This may depend on impaired association between factor XIII and fibrinogen Aarhus.