The interference of plasmic degradation products of human crosslinked fibrin with clot formation

The role of plasmic degradation products of human crosslinked fibrin on polymerization of fibrin monomer and clot formation was studied. Both reactions were inhibited by Fragment DD, which formed a complex with fibrin monomer in a molar ratio 1 : 1. The rate of polymerization was slightly increased by Fragment E but it was not affected by (DD)E complex and Fragment A. Approximately the same amount of fibrin was formed in the presence and absence of Fragments A, E and the complex. It was concluded that of the degradation products of crosslinked fibrin, only Fragment DD is a potent anticoagulant at physiologic pH. The (DD)E complex is inert and Fragments A and E have only marginal effects.     

The interference of plasmic degradation products of human crosslinked fibrin with clot formation.

The role of plasmic degradation products of human crosslinked fibrin on polymerization of fibrin monomer and clot formation was studied. Both reactions were inhibited by Fragment DD, which formed a complex with fibrin monomer in a molar ratio 1 : 1. The rate of polymerization was slightly increased by Fragment E but it was not affected by (DD)E complex and Fragment A. Approximately the same amount of fibrin was formed in the presence and absence of Fragments A, E and the complex. It was concluded that of the degradation products of crosslinked fibrin, only Fragment DD is a potent anticoagulant at physiologic pH. The (DD)E complex is inert and Fragments A and E have only marginal effects.     

Binding phenomena of isolated unique plasmic degradation products of human cross-linked fibrin.

Proteolysis of human cross-linked fibrin by plasmin results in the formation of a DD . E complex, and Fragments DD and E as the major degradation products. Three species of Fragment E, which differ both in molecular weights (E1, Mr = 60,000; E2, Mr = 55,000; E3, Mr = 50,000) and in charge, have been isolated from a digest of cross-linked fibrin. Each Fragment E species reacts with monospecific anti-E antiserum. Fragments E1 and E2 bind with Fragment DD to form a DD . E complex but Fragment E3 is inactive. This binding is specific since these Fragments E do not bind to fibrinogen or to degradation products of fibrinogen or of noncross-linked fibrin. Fragments E1 and E2 incubated with plasmin are degraded to Fragment E3, suggesting that the three species represent sequential degradation products. Plasmin-treated Fragments E1 and E2 no longer bind with Fragment DD; therefore, it appears that the peptides cleaved from Fragment E2 by plasmin contain or modify the sites responsible for complex formation. On the other hand, Fragment DD binds not only to Fragments E1 and E2, but also to fibrinogen, Fragments X (Stage 1), X (Stage 2), Y, and NH2-terminal disulfide knot, but only after thrombin treatment, suggesting that Fragment DD binds to complementary sites on the NH2-terminal region of fibrinogen which are exposed after thrombin treatment.     

Primary soluble plasmic degradation product of human cross-linked fibrin. Isolation and stoichiometry of the (DD)E complex.

The formation of the (DD)E complex and fragments DD and E upon proteolysis of human cross-linked fibrin was studied by timed digestions using varying amounts of plasmin. The (DD)E complex was the primary soluble degradation product released form cross-linked fibrin. This complex contained fragments DD and E1. Upon further digestion (DD)E1 complex was cleaved to (DD)E2 complex whereby only the fragment E moiety was affected. However, when fragment E2 was digested to fragment E3, dissociation of the complex occurred. Thus, fragments DD and E3 are the terminal plasmic digestion products of cross-linked fibrin. This pattern was consistent regardless of the plasmin to fibrin ratio; however, the rate of production of the terminal degradation products was directly dependent upon enzyme concentration. Digestion conditions were modified so that either the (DD)E complex or fragment DD was the predominant degradation product, allowing for the purification of these species by one-step gel filtration. The molar ratio of fragment DD to fragment E in the (DD)E complex was investigated by dissociation of the complex and by reassociation of the purified components. The (DD)E complex contains one molecule of fragment DD and one molecule of fragment E.     

Effects of fibrinopeptide cleavage on the plasmic degradation pathways of human cross-linked fibrin

The presence of fibrinopeptide B in human fibrin has a significant effect on plasmic degradation pathways of cross-linked clots. Two types of fibrin were obtained from fibrinogen by incubation either with thrombin, to remove both fibrinopeptides A and B, or with batroxobin, to cleave fibrinopepitde A only. Fibrins obtained after various incubation times were characterized by the determination of the NH2-terminal amino acids, the content of fibrinopeptides, and the extent of cross-linking. The fibrins were digested by plasmin and were analyzed by polyacrylamide gel electrophoresis. The presence and concentration of the (DD)E complex, as well as fragments E1 and E2, in the digests were dependent upon the loss of fibrinopeptide B from cross-linked fibrin. These degradation products, and also fragment DD, appear to be useful molecular markers of fibrinolysis.     

Electron microscopic studies of plasmic degradation products of fibrinogen. Implications for the disulfide structure of fibrinogen.

Fibrinogen, coagulable plasmic derivatives (Fragments X) and Fragments Y, D and E were studied by negative staining electron microscopy. Fragment X obtained from Stage 1 digests and fibrinogen were both globular, while Fragment X of Stage 2 digests appeared as a nodular filament. The Stage 1 and Stage 2 Fragment X preparations had approximately the same molecular weight, but could be differentiated by several subtle differences in polypeptide chain structure. Fragments Y and D were also filamentous, although shorter than Fragment X (Stage 2), and Fragment E appeared as a small, compact or folded filament. These results agree with the concept that fibrinogen consists of a strand of nodules connected by thin strands, folded into a compact, spherical shape. The molecule opens up when stabilizing bonds are disrupted or liberated by plasmin. The data are compatible with a fibrinogen molecule in which the two halves are linked by a single locus of disulfide bonds at the amino terminus and with the asymmetric hypothesis of plasmic degradation to Fragments X, Y, D and E.     

Structure of fragment E species from human cross-linked fibrin

Fragments E1, E2, and E3 are plasmic derivatives of fibrin encompassing the NH2-terminal region of the molecule. The first two species, but not the third, can bind to fragment DD, forming a (DD)E complex, and therefore probably contain binding sites involved in the polymerization of fibrin. For localization of these sites the structure of the fragments was determined by establishing the NH2- and COOH-terminal boundaries of the molecules and using the published amino acid sequence of fibrinogen. Fragment E1 encompasses Gly-alpha 17 to Lys-alpha 78, Gly-beta 15 to Lys-beta 122, and Tyr-gamma 1 to Lys-gamma 62, this representing the intact NH2-terminal region of fibrin. Fragment E2 is an asymmetric molecule which is lacking the sequence of Gly-beta 15 to Lys-beta 53 in one beta-chain remnant. This fragment E2 also lost Lys-beta 122 from the COOH terminal of the beta chain as compared with fragment E1. These cleavages did not affect the ability of fragment E2 to bind to fragment DD. Fragment E3 was heterogeneous, the main species encompassing Val-alpha 20 to Lys-alpha 78, Lys-beta 54 to Leu-beta 120, and Tyr-gamma 1 to Lys-gamma 53. Thus, the loss of the binding function involved in the formation of fibrin clot was associated with the removal of small fragments from all three polypeptide chains: alpha 17-19 (Gly-Pro-Arg), beta 15-53 from the remaining half of the molecule, beta 121 (Leu), and gamma 54-58 (Thr-Ser-Glu-Val-Lys).     

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.     

Expression of primary polymerization sites in the D domain of human fibrinogen depends on intact conformation

Fragments D1 and DD, plasmic degradation products of human fibrinogen and cross-linked fibrin, respectively, originate from the COOH-terminal domain of the parent molecule. Since a specific binding site for fibrin resides in the COOH-terminal region of the gamma chain, the primary structure of the two fragments was compared and their affinity for fibrin monomer measured. Fragments D1 and DD contained the same segments of the three fibrinogen chains, corresponding to the sequences alpha 105-206, beta 134-461, and gamma 63-411. Fragment DD had a double set of the same chain remnants. Fragments D1 and DD inhibited polymerization of fibrin monomer in a dose-dependent manner; 50% inhibition occurred at a molar ratio of fragment to monomer of 1:1 and 0.5:1, respectively. To prevent fibrin monomer polymerization and render it suitable for binding studies in the liquid phase, fibrinogen was decorated with Fab fragments isolated from rabbit antibodies to human fragment D1. Fibrinogen molecules decorated with 6 molecules of this Fab fragment did not clot after incubation with thrombin, and the decorated fibrin monomer could be used to measure binding of fragments D1 and DD in a homogeneous liquid phase. The data analyzed according to the Scatchard equation and a double-reciprocal plot gave a dissociation constant of 12 nM for fragment D1 and 38 nM for fragment DD. There were two binding sites/fibrin monomer molecule for each fragment. After denaturation in 5 M guanidine HCl, the inhibitory function on fibrin polymerization was irreversibly destroyed. Denatured fragments also lost binding affinity for immobilized fibrin monomer. The preservation of the native tertiary structure in both fragments was essential for the expression of polymerization sites in the structural D domain.     

A unique proteolytic fragment of human fibrinogen containing the A alpha COOH-terminal domain of the native molecule

The COOH-terminal portion of the A alpha chain of human fibrinogen is highly susceptible to proteolytic degradation. This property has prevented isolation of the COOH-terminal domain of fibrinogen for the direct investigation of its functional characteristics. Human fibrinogen was degraded with hementin, a fibrinogen-olytic protease from the posterior salivary glands of the leech, Haementeria ghilianii. Two initial fragments, Yhem1 and Dhem1, produced by cleavage through the three polypeptide chains in the connector region, were characterized and shown to retain the entire A alpha COOH-terminal domain. Late cleavages by hementin occurred in the A alpha chain COOH-terminal region to produce fragments Yhem and Dhem with shorter A alpha chain remnants. Fragments Dhem were isolated from an intermediate hementin digest of fibrinogen using anion-exchange chromatography. Fragment Dhem1 was separated further from Dhem fragments with shorter alpha chain remnants by affinity chromatography on immobilized plasma fibronectin. Fragment Dhem1 represents a unique proteolytic fragment of fibrinogen containing an intact A alpha chain COOH-terminal region. NH2-terminal sequence analysis of isolated chains from fragment Dhem1 located hementin cleavage sites in the connector region to A alpha Asn102-Asn103, B beta Lys130-Gln131, and gamma Pro76-Asn77. The specific interaction of fragment Dhem1 with immobilized fibronectin indicated that the binding site probably was located within the COOH-terminal 111 amino acids of the A alpha chain. The overall pattern of fibrinogen cleavage by hementin is similar to that of plasmin, yet hementin cleaves preferably in the coiled-coil connector, sparing the A alpha COOH-terminal domain.     

Lymphocyte suppressive peptides from fibrinogen are derived predominantly from the A alpha chain

Cellular immune responses can elicit local deposition of fibrin at the site of immunologic reactions, as well as the formation of intravascular fibrin in disseminated reactions. The subsequent physiologic proteolysis of fibrinogen and fibrin by plasmin results in small peptides that suppress lymphocyte functions in vitro and in the immune response in vivo. The intramolecular origin of lymphocyte suppressive activity and the proteolytic events responsible for the release of active peptides have been analyzed. Plasmic peptides from the isolated B beta and gamma constituent chains of fibrinogen did not inhibit mitogen-driven responses of human peripheral blood mononuclear cells. In contrast, plasmic digests of the A alpha chain, but not the intact A alpha chain were suppressive. Advanced plasmic digests of fibrinogen and the A alpha chain were suppressive at similar concentrations, suggesting that biological activity is derived predominantly from the A alpha chain. Limited plasmic digests of fibrinogen were fractionated to yield a heat-precipitable 250,000 dalton fragment X and heat-soluble proteolytic products containing fragments derived from the carboxyl-terminal region of the A alpha chain including a 42,000 dalton major A alpha chain derivative. Neither fragment X nor derivatives produced by its additional plasmic proteolysis were suppressive. In contrast, the heat-soluble fraction from limited plasmic cleavage was suppressive, and this activity was enhanced 10-fold by additional plasmic cleavage of this fraction. The isolated 42,000 dalton A alpha chain fragment was devoid of activity, but plasmic digestion of this derivative generated peptides of less than 8000 daltons that inhibited mitogen-stimulated thymidine uptake by lymphocytes. Two synthetic peptides corresponding to A alpha 220-230 and B beta 43-47, peptides with known vasoactive activities, suppressed lymphocyte thymidine uptake at very high concentrations. Based on their maximal yield from plasmic digests of fibrinogen, these two peptides would account for only 1% of the immunosuppressive activity of fibrinogen derivatives. In summary, the results indicate that the suppressive activity of fibrinogen is predominantly derived from the 42,000 dalton carboxyl terminal region of the A alpha chain of the molecule and is not attributable to the known vasoactive peptides. Initial proteolytic release of this region from the core of fibrinogen does not result in suppressive activity, but additional cleavage releases small peptides with the lymphocyte inhibitory function.     

New findings on an anti-proteinase in human plasma: l'inter-alpha-trypsin inhibitor]

Inter-alpha-trypsin inhibitor (I alpha I) has been purified from C.N.T.S. fraction III as starting material. The purification procedure includes D.E.A.E. cellulose chromatography and gel filtration on G 150 Sephadex in the presence of EDTA. The purified protein gives one precipitation line in immunoelectrophoresis against anti-whole human sérum. It reacts only with an anti I alpha I immune serum and possesses a strong antitryptic activity. When studied in starch or polyacrylamide gel electrophoresis 2 components are observed, each of them having the same antigenic structure and the same antitryptic activity as the crude preparation. The slower and less important component is dissociated by 0,1% SDS. The molecular weight estimation of I alpha I BY PAA/SDS is about 180,000. This result is not modified by the presence of 1% beta mercaptoethanol indicating that I alpha I consists of one polypeptide chain. Crude preparation reveals under the same electrophoretical conditions small amounts of low molecular weight components (135,000 52,000 and 26,000) which can be due to a proteolytic action on I alpha I. Indeed plasmin is able to produce such fragments having an antitryptic activity as shown by fibrin/polyacrylamide gel electrophoresis. The relationship between small molecular weight inhibitors of human serum and bronchial secretions and those obtained after degradation of I alpha I by plasmin is discussed.     

Inactivation of factor Va by plasmin

The inactivation of Factor Va by plasmin was studied in the presence and absence of phospholipid vesicles and calcium ions. The cleavage patterns of bovine Factor Va and its isolated subunits were analyzed using polyacrylamide gel electrophoresis, and the progress of inactivation was monitored by clotting assays and measurements of prothrombin activation using 5-dimethylaminonaphthalene-1-sulfonylarginine-N-(3-ethyl-1,5-penta nediyl)amide. In addition, the ability of prothrombin and Factor Xa to protect Factor Va from inactivation by human plasmin was examined. The data presented indicate that the cofactor Factor Va is inactivated rapidly upon its interaction with human plasmin. The rate of inactivation is significantly enhanced in the presence of phospholipid vesicles, suggesting that the inactivation process is a membrane-bound phenomenon. The isolated D component (heavy chain of factor Va) was found to be slowly degraded by human plasmin, giving rise to cleavage products different from those obtained with activated protein C and Factor Xa. However, the 48- and 30-kDa fragments obtained from human plasmin degradation of component E (light chain of Factor Va) appear to be similar to those obtained following the proteolysis of the same subunit by activated protein C and Factor Xa.     

The mechanism of blood cell sedimentation. XVIII. Sedimentation effect of fibrinogen plasminolysis products]

Various high molecular weight plasmin degradation products of fibrinogen were isolated by chromatographic procedures and investigated to what extent they influence the sedimentation rate of erythrocytes in heparinized serum. Among the early plasminolysis products Fragment X accelerated the sedimentation rate considerably although it was less effective than fibrinogen. Fragment Y showed a weaker but clearly demonstrable agglomerine activity. The late plasminolysis products D and E were ineffective, if applied alone and in concentrations equivalent to the fibrinogen content of plasma. However, they promoted the sedimentation effect of fibrinogen. If present in considerably higher concentrations are Fragments D and E, in absence of fibrinogen, also accelerated the sedimentation rate of erythrocytes significantly. A mixture of D and E was not more effective than the single compounds.     

Characterization of peptides cleaved by plasmin from the C-terminal polymerization domain of human fibrinogen

The C-terminal region of the fibrinogen gamma chain is known to participate in several functional interactions including fibrin polymerization. This part of the molecule is retained on the gamma chain of fragment D (FgD) when fibrinogen is digested by plasmin in the presence of calcium to produce the fragment D-fragment E (FgD X FgE) complex but is lost if FgD is prepared in the absence of calcium. In an attempt to characterize the C-terminal polymerization domain we have used three techniques to examine this further degradation of FgD following the addition of EDTA and plasmin. Analysis of the digestion by sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed a progressive cleavage of the gamma chain to two small remnants. The polymerization-inhibitory activity of the whole digest was studied using acid-solubilized fibrin. A progressive loss of inhibitory activity was associated with gamma chain shortening, reaching greater than a 120-fold reduction at the end of digestion. The cleavage of peptides was followed by reverse-phase high performance liquid chromatography and the release of a characteristic peptide triplet was associated with gamma chain cleavage. Manual sequencing, amino acid analysis, and fast atom bombardment mass spectrometry established the three peptides as gamma 303-356, 357-373, and 374-405. These peptides have sequences in common with those peptides recently reported by other investigators to be potent polymerization inhibitors. However, when a mixture of the three peptides was added in a 200-fold molar excess to polymerizing fibrin, no inhibitory activity could be demonstrated. It is concluded that the C-terminal polymerization domain of fibrinogen may be an extended region which includes the sequence gamma 303-405, when this is contiguous with the remainder of the gamma chain.     

Plasmic degradation of bovine fibrinogen and non-crosslinked fibrins in solution and in gel form.

1. Analysis of degradation processes of bovine fibrinogen by bovine plasmin using sodium dodecyl sulfate-polyacrylamide gel electrophoresis and a study on the mode of changes of the properties related to clotting of digestion products as a function of time were performed. Gross features and patterns very similar to those which had been reported with human fibrinogen-plasmin systems were obtained. 2. Based on the molecular size of the degradation products and the mode of appearance and disappearance of the degradation products, the processes could tentatively be divided into three stages: stage 1, where fibrinogen (mol. wt 370 000) was degraded to produce fragments X1 (330 000) and X2 (290 000); stage 2, fragment X2 was degraded with appearance of Y (210 000) and D1 (140 000); stage 3, appearance of fragments D1, D2 (110 000), and D3 (100 000) sequentially and E (68 000) with concomitant disappearance of Y. 3. A microseparation method, which is a combination of dansylation and sodium dodecylsulfate-polyacrylamide gel electrophoresis, was devised to analyze the events of stage 1 in detail, and a molecular model for the process was proposed. 4. The plasmic degradation processes of bovine non-cross-linked fibrins in solution and in gel form were compared with that of fibrinogen and it was found that the state of the substrates, fibrins, could cause differences in the degradation patterns. With the former substrate, essentially the same sodium dodecyl sulfate-polyacrylamide gel electrophoretic patterns as those with fibrinogen were obtained. With the latter substrate, however, a distinct difference in the mode of degradation of beta chains was observed.     

Involvement of both heparanase and plasminogen activator in lymphoma cell-mediated degradation of heparan sulfate in the subendothelial extracellular matrix

The effect of plasminogen on the ability of highly metastatic ESb mouse lymphoma cells to degrade heparan sulfate (HS) in the subendothelial extracellular matrix (ECM) was studied. A metabolically sulfate-labeled ECM was incubated with the lymphoma cells, and labeled degradation products were analyzed by gel filtration on Sepharose 6B. Heparanase-mediated release of low-Mr (0.5 less than Kav less than 0.85) HS cleavage products was stimulated fourfold in the presence of plasminogen. Incubation of plasminogen alone with the ECM resulted in its conversion into plasmin, which released high-Mr (Kav less than 0.33) labeled proteoglycans from the ECM. Heating the ECM (80 degrees C, 1 hr) abolished its ability to convert plasminogen into plasmin, yet plasminogen stimulated, through its activation by the ESb plasminogen activator, heparanase-mediated release of low-Mr HS fragments. Heparin inhibited both the basal and plasminogen-stimulated degradation of HS side chains but not the total amount of labeled material released from the ECM. In contrast, aprotinin inhibited the plasminogen-stimulated release of high- as well as low-Mr material. In the absence of plasminogen, degradation of heated ECM by ESb cells was completely inhibited by aprotinin, but there was only a partial inhibition of the degradation of native ECM and no effect on the degradation of soluble HS proteoglycan. These results demonstrate that proteolytic activity and heparanase participate synergistically in the sequential degradation of ECM HS and that the ESb proteolytic activity is crucial for this degradation when the ECM-associated protease is inactivated. Plasminogen may serve as a source for the proteolytic activity that produces a more accessible substrate to the heparanase.     

Factor XIII binds to the A alpha- and B beta- chains in the D-domain of fibrinogen: an immunoblotting study

The binding sites in fibrinogen for Factor XIII were localized using an immunoblotting technique. Platelet Factor XIII bound to fibrinogen and to plasmin degradation products of fibrin(ogen) including Fragments: X, D1-D3, and D-dimer, but did not bind to Fragment E. Binding of Platelet Factor XIII was independent of calcium ions but could be inhibited by the presence of 0.5 M NaCl. Binding could also be inhibited by preincubating Factor XIII with a 100-fold molar excess of fibrinogen but not by 100-fold molar excess of Fragment E. Binding of Factor XIII to fibrinogen was specific, since several other proteins tested (ovalbumin, bovine serum albumin, alpha 2-macroglobulin, beta-galactosidase, fructose kinase, lactic dehydrogenase, triose phosphate isomerase, fumarase and pyruvate kinase) did not bind Factor XIII. Furthermore, binding was not observed either when Factor XIII was left out or when antiFactor XIII antiserum was substituted with nonimmune serum. When fibrinogen was reduced prior to electrophoresis, Factor XIII bound to the A alpha and B beta chains of fibrinogen and des A,B fibrinogen, the B beta-chain of Fragment X, but not the gamma-chains. Localization of the Factor XIII binding sites to the carboxy terminal segments of the A alpha and B beta chains in the Fragment D-domain of fibrinogen could have important physiological consequences.     

Protective effect of divalent cations in the plasmin degradation of fibrinogen

Calcium limits the plasmic proteolysis of fibrinogen fragment D by binding to a specific site on the carboxy-terminal segment of the D gamma chain. Employing sodium dodecyl sulfate-polyacrylamide gel electrophoresis to visualize plasmic fragments, Sr2+, Ba2+, and Mn2+ were found to have an equivalent capacity to limit the degradation of fibrinogen fragment D (Mr 94,000). Mg2+, Fe2+, Co2+, and Zn2+ did not comparably limit the digestion of fragment D. Equilibrium dialysis demonstrated that Ba2+ competitively inhibited Ca2+ binding to fibrinogen, suggesting that the ions occupied the Ca2+ binding site of fibrinogen and thereby limited the plasmic digestion of fragment D. The results suggest that Ca2+, Sr2+, Ba2+, and Mn2+ limit plasmin digestion of fragment D by interacting with a Ca2+ binding site in the D domain of the fibrinogen molecule.     

Differential autolysis of human and canine plasmins

Plasmin, like trypsin, undergoes autolysis. The proteolytic activity of human plasmin was virtually abolished after incubation at 37° for 1 hour, whereas the activity of the canine plasmin remained relatively stable under the same conditions. After 23 hours of incubation at 25°, canine plasmin had lost only 12% of its proteolytic activity, while human plasmin had lost 72% of its activity. Gel electrophoretic analyses showed differences in the susceptibility to proteolysis of the light and heavy chain components of the two plasmin molecules. The light chain of canine plasmin was relatively stable to autolysis while the light chain of human plasmin underwent extensive proteolytic degradation. The patterns of digestion of the heavy chain components of the two plasmin species were also found to be different. The results obtained in this study suggest that significant differences exist in the structures of human and canine plasmins.