Characterization of the terminal degradation products of canine fibrinogen by plasmin.

Fibrinogen, isolated from canine plasma by the successive procedures of (1) freezing and thawing, (2) fractional precipitation with 25% saturated (HN4)2SO4 and (3) Sepharose 6B gel-filtration, had a molecular weight of 282 000 by the rapid sedimentation equilibrium method. However, a molecular weight for canine fibrinogen of 332 000, which is closer to that reported for human and bovine fibrinogens (340 000 plus or minus 20 000), was obtained from the sum of the molecular weights of the Aalpha, Bbeta and gamma chains, determined from dodecylsulfate gel electrophoretic patterns of reduced fibrinogen. Canine fibrinogen, subjected to proteolysis by urokinase-activated plasminogen for 24 h, contained degradation fragments D and E which were isolated by starch block electrophoresis and Sephadex G-200 gel-filtration. The purified D and E fragments with sedimentation coefficients of 5.0 S and 2.5 S had weight average molecular weights of 89 000 and 42 000, respectively by the rapid sedimentation equilibrium method. The ratio of D to E was 2:1 per parent fibrinogen molecule. Antigenic analysis according to anti-fibrinogen antiserum showed that both D and E fragments were antigenically deficient to native fibrinogen and revealed a reaction of non-identity with each other. Upon immunoelectrophoresis at pH 8.2, D and E had different electrophoretic mobilities. Preliminary studies indicate that based on thrombin time alone, D has anticoagulant activity while E appears to be a coagulation potentiator. Canine fibrinogen apparently consist of two core fragments with dissimilar chemical characteristics in common with the fundamental structures of human and bovine fibrinogens.     

Terminal plasmin degradation products D and E of duck fibrinogen and their effect on polymerization of fibrin

Duck fibrinogen (Mr 320 000) treated with streptokinase-activated human plasminogen in the presence of calcium ions was hydrolysed to terminal core fragments D and E. They were isolated from the digest by: (1) ion-exchange chromatography on DEAE-cellulose, (2) gel filtration on Sephadex G-100, and (3) affinity chromatography with the use of fibrin monomers coupled to CNBr-activated Sepharose. When the native D fragment, D1 was additionally digested by plasmin in the presence of EDTA, more degraded forms D2 and D3 appeared. Molecular weight of D1, D2, D3 and E estimated on SDS-polyacrylamide gel electrophoresis is 100 000, 89 000, 80 000 and 50 000, respectively. It was found that after reduction with 2-mercaptoethanol the fragments D1 and D3 consisted each of three polypeptide chains: alpha, beta, gamma: the gamma-chain of D3 remnant was more degraded (Mr 24 000) as compared with the gamma-chain of D1 remnant (Mr 42 000). Polymerization of both duck and pig fibrin monomers was inhibited by fragments D1 but not by D3.     

The role of DL and DH degradation products in the reactions of the plasmin hydrolysis of fibrinogen and fibrin]

The mechanism of effect of plasmin hydrolysis degradation products, fragments DL and DH, on fibrinolysis and fibrinogenolysis processes was investigated on the basis of their various structural and functional characteristics. Using electrophoresis of unreduced samples and degradation products concentrations changing kinetics, DH was shown to be the only fragment which possessed an antifibrinolytic effect. Rauleigh's light scattering analysis indicated the ability of fragments DL and DH to co-form with plasminogen reversible equimolar complexes.     

The role of ligand-ligand interactions in competition by fibrinogen and fibrin degradation products for fibrinogen binding to human platelets

Binding to human platelets of radioiodinated human fibrinogen and fragments X, Y, D, D₁ dimer and E was studied to determine the domain of the fibrinogen molecule responsible for binding to the platelet receptor. Although the fragments did not bind, some wer able to complete for the binding of fibrinogen to platelets. It was postulated that the fragments bound to fibrinogen and subsequently interfered with its binding to the receptor. Two approaches were developed to test this hypothesis. In the first technique, molecular exclusion on Sephacryl S-200 superfine was utilized to examine the interaction of radiolabeled fragments with fibrinogen. In the second seties of studies, fibrinogen-Sepharose was prepared and the binding of degradation products directly determined. A spin dialysis apparatus was employed in each case to achieve rapid separation of bound and free radioligand. These studies demonstrated that fragments D and E bind to fibrinogen. Therefore, the mechanism by which degradation products interfere with fibrinogen binding to the platelet receptor is ligand-ligand interaction rather than binding of the fragments to the receptor. Since none of the radiolabeled degradation products bound to platelets, it appears that receptor recognition requires the intact molecule.     

Comparative evaluation of fibrinogen and fibrin hydrolysis with plasmin

A high-sensitive method is developed for determining the degree of plasmin-catalyzed fibrinogen hydrolysis by the released amino groups stained with trinitrobenzene sulphoacid. The method permits determining 0.02-0.08 casein units of plasmin. The method made it possible to establish that after streptokinase activation plasmin hydrolyzes equally fibrinogen and fibrin in solution and as gel. When a tissue activator is used, fibrin intensifies significantly the plasminogen activation. Inhibition of plasmin by an inhibitor produced from soya is considerably slowed down in fibrin gel.     

Origin of urinary fibrin/fibrinogen degradation products in glomerulonephritis.

To elucidate the origin of the fibrin/fibrinogen degradation products (F.D.P.) occurring in the urine in glomerulonephritis 28 patients with glomerulonephritis were examined for renal fibrinolytic activity, F.D.P. in urine and serum, and blood fibrinolytic activators and blood fibrinolytic activators and inhibitors. Unlike the glomerful of healthy kidneys, which were fibrinolyticly inactive, those of kidneys with glomerulonephritis constantly showed fibrinolytic activity. The presence or absence of fibrin in the glomeruli was almost always accompanied by, respectively, the presence or absence of urinary F.D.P., which suggested a renal origin of urinary F.D.P. in glomerulonephritis. The low fibrinolytic activity of the blood and the absence of F.D.P. in the serum of these patients make it unlikely that the urinary F.D.P. in glomerulonephritis result from glomerular filtration.     

Conventional detection method of fibrinogen and fibrin degradation products using latex piezoelectric immunoassay

We developed a conventional immunosensor for fibrinogen and fibrin degradation products (FDP) to combine a quartz crystal microbalance (QCM) with the agglutination reaction of immunized latex beads. FDP induced an immunoreaction due to anti-FDP antibody immobilized latex particles. We successfully measured FDP concentration of in human serum within 10 min by QCM method. The detection range of QCM immunosensor is covered with screening concentration of FDP in serum (<10 microg/ml of FDP). The time course of latex agglutination obtained from QCM immunosensor is synchronized to that of latex photometric immunoassay. SEM was used to observe the surface of QCM that applied FDP serum. The size of latex particles agglutinated on the QCM electrode increased concomitant with FDP concentration. Frequency shift on immunoreaction explains the increased adsorption amount of agglutinated latex on QCM.     

A re-examination of the cleavage of fibrinogen and fibrin by plasmin.

Three Fragment D species (D1, D2, D3) were isolated with time from a plasmin digest of fibrinogen and had molecular weights of 92,999, 86,000 and 82,000 by summation of subunit molecular weights from sodium dodecyl sulfate polyacrylamide gel electrophoresis. Their molecular weights by sedimentation equilibrium ultracentrifugation were 94,000 t87,000, 88,000 to 82, 000, and 76,000 to 70,000 depending on the values calculated for the partial specific volumes. Each of the Fragment D species contained three disulfide-linked subunits derived from the Aalpha, Bbeta, and gamma chains of fibrinogen and differed only in the extent of COOH-terminal degradation of their gamma chain derivatives. Plasmin cleaved Fragment D1 to release the cross-link sites from its gamma' subunit of 38,000 molecular weight; however, the beta' subunit of 42,000 molecular weight and the alpha' subunit of 12,000 molecular weight were resistant to further digestion by plasmin. Fragment D isolated from highly cross-linked fibrin had a dimeric structure due to cross-link formation between the gamma' subunits of two fibrinogen Fragment D species. The molecular weight of fibrin Fragment D was 184,000 by summation of subunit molecular weights and 190,000 to 175,000 by sedimentation equilibrium. Cross-linking the gamma chain, as well as incorporating the site-specific fluorescent label monodansyl cadaverine into the gamma chain cross-link acceptor site, prevented its COOH-terminal degradation by plasmin. Therefore, only one species of fibrin Fragment D, as well as only one species of monodansyl cadaverine-labeled fibrin Fragment D monomer, was generated during plasmin digestion. These results show unequivocally that each fibrinogen Fragment D contains only three subunit chains and therefore the digestion of fibrinogen by plasmin must result in the production of two Fragment D molecules from each fibrinogen molecule. The recently proposed model of fibrinogen cleavage that postulates the generation of a single Fragment D with three pairs of subunit chains from each fibrinogen molecule is incorrect. Incorporation of monodansyl cadaverine into the cross-link acceptor sites of the alpha chain did not alter its cleavage by plasmin detectably. A series of monodansyl cadaverine-labeled peptides, which ranged in molecular weight from 40,000 to 23,000, were cleaved from the alpha chain of monodansyl cadaverine-labeled fibrin monomer during the early stages of plasmin digestion. These peptides were degraded progressively to a brightly fluorescent plasmin-resistant peptide of 21,000 molecular weight and a weakly fluorescent peptide of 2,500 molecular weight. Thus both alpha chain cross-link acceptor sites are contained within a peptide segment of 23,000 molecular weight.