High Resolution Electrophoretic Analysis of Human Fibrinogen and Its Crosslinked Intermediates

Influence of a natural and a synthetic inhibitor of factor XIIIa on fibrin clot rheology

We investigated the origins of greater clot rigidity associated with FXIIIa-dependent cross-linking. Fibrin clots were examined in which cross-linking was controlled through the use of two inhibitors: a highly specific active-center-directed synthetic inhibitor of FXIIIa, 1,3-dimethyl-4,5-diphenyl-2[2(oxopropyl)thio]imidazolium trifluoromethylsulfonate, and a patient-derived immunoglobulin directed mainly against the thrombin-activated catalytic A subunits of thrombin-activated FXIII. Cross-linked fibrin chains were identified and quantified by one- and two-dimensional gel electrophoresis and immunostaining with antibodies specific for the alpha- and gamma-chains of fibrin. Gamma-dimers, gamma-multimers, alpha(n)-polymers, and alpha(p)gamma(q)-hybrids were detected. The synthetic inhibitor was highly effective in preventing the production of all cross-linked species. In contrast, the autoimmune antibody of the patient caused primarily an inhibition of alpha-chain cross-linking. Clot rigidities (storage moduli, G') were measured with a cone and plate rheometer and correlated with the distributions of the various cross-linked species found in the clots. Our findings indicate that the FXIIIa-induced dimeric cross-linking of gamma-chains by itself is not sufficient to stiffen the fibrin networks. Instead, the augmentation of clot rigidity was more strongly correlated with the formation of gamma-multimers, alpha(n)-polymers, and alpha(p)gamma(q)-hybrid cross-links. A mechanism is proposed to explain how these cross-linked species may enhance clot rigidity.

Intravascular Coagulation Activation in a Murine Model of Thrombomodulin Deficiency: Effects of Lesion Size, Age, and Hypoxia on Fibrin Deposition

We consecutively inactivated both alleles of the thrombomodulin (TM) gene in murine embryonic stem (ES) cells and generated TM-deficient (TM−/−) chimeric mice. Quantitation of an ES-cell marker and protein C cofactor activity indicates that up to 50% of pulmonary endothelial cells are ES-cell derived and therefore TM deficient. Infusions of 125I-fibrinogen into mice show a significant increase (fourfold, P < .005) in radiolabeled cross-linked fibrin in TM−/− chimeric mouse lung as compared with wild-type mice. However, only chimeric mice that exhibit at least a 30% reduction in protein C cofactor activity and are at least 15 months old display this phenotype. Immunocytochemical localization of TM in chimeras shows a mosaic pattern of expression in both large and small blood vessels. Colocalization of cross-linked fibrin and neo (used to replace TM) reveals that fibrin is deposited in TM−/− regions. However, the fibrin deposits were largely restricted to pulmonary vessels with a lumenal area greater than 100 μm2. The hypercoagulable phenotype can be induced in younger chimeric mice by exposure to hypoxia, which causes a fivefold increase in β-fibrin levels in lung. Our findings show that TM chimerism results in spontaneous, intravascular fibrin deposition that is dependent on age and the magnitude of the TM deficiency.

Intravascular Coagulation Activation in a Murine Model of Thrombomodulin Deficiency: Effects of Lesion Size, Age, and Hypoxia on Fibrin Deposition

We consecutively inactivated both alleles of the thrombomodulin (TM) gene in murine embryonic stem (ES) cells and generated TM-deficient (TM−/−) chimeric mice. Quantitation of an ES-cell marker and protein C cofactor activity indicates that up to 50% of pulmonary endothelial cells are ES-cell derived and therefore TM deficient. Infusions of 125I-fibrinogen into mice show a significant increase (fourfold, P &lt; .005) in radiolabeled cross-linked fibrin in TM−/− chimeric mouse lung as compared with wild-type mice. However, only chimeric mice that exhibit at least a 30% reduction in protein C cofactor activity and are at least 15 months old display this phenotype. Immunocytochemical localization of TM in chimeras shows a mosaic pattern of expression in both large and small blood vessels. Colocalization of cross-linked fibrin and neo (used to replace TM) reveals that fibrin is deposited in TM−/− regions. However, the fibrin deposits were largely restricted to pulmonary vessels with a lumenal area greater than 100 μm2. The hypercoagulable phenotype can be induced in younger chimeric mice by exposure to hypoxia, which causes a fivefold increase in β-fibrin levels in lung. Our findings show that TM chimerism results in spontaneous, intravascular fibrin deposition that is dependent on age and the magnitude of the TM deficiency.

Human fibrinogen

The structure and physical properties of human fibrinogen and fibrin are reviewed along with methods for the detection of products of their metabolism. Interactions of human fibrinogen with thrombin, factor XIII, plasminogen, glycoprotein IIb/IIIa, and other proteins are related to their relevance to thrombosis and hemostasis. To the extent information is available, the structural determinants of these interactions are delineated, and kinetic and thermodynamic parameters associated with the interactions are listed. Individual steps in the reaction pathway for the conversion of fibrinogen to cross-linked fibrin are characterized. The altered hemostatic properties of mutational variants of fibrinogen are related to their altered structure. The structures of the genes coding for the polypeptide chains of fibrinogen are discussed along with the current state of knowledge of the control and regulation of fibrinogen synthesis. Fibrinogen catabolism and fibrinolysis are also reviewed.

Modulation of lymphocyte responsiveness to phytohemagglutinin by micromolecular fibrinogen degradation products

The ability of fibrinogen degradation products (FDP) to influence the regulatory function of adherent cells from peripheral blood mononuclear cells (PBMC) was evaluated. FDP were prepared by digestion of fibrin clots with plasmin. These FDP were incubated overnight with glass-adherent cells following which these treated and untreated cells were cocultivated with fresh autologous responder PBMC in the presence of the T-cell mitogen, phytohemagglutinin (PHA). Lipid metabolism of FDP-treated monocytes was evaluated in cells that had been prelabeled with [3H]arachidonic acid (AA) prior to their overnight incubation with FDP; supernatants were analyzed for conversion of AA to cyclooxygenase and lipoxygenase products by thin-layer chromatography. Treatment of glass-adherent cells with the FDP digests converted these monocytes into suppressor cells. The suppression exerted by these cells in the PHA assay was dose dependent. The suppression exerted by FDP-pretreated monocytes was reversed by treating the PHA-stimulated cocultures with indomethacin and was associated with increased cyclooxygenase activity. These studies demonstrated that FDP can alter T-cell immune function through the induction of monocyte suppressor cells; the means by which that occurs is associated with stimulation of lipid metabolism and secretion of eicosanoids with immunoregulatory capacity.