Plasma protein changes in horse after prolonged physical exercise: a proteomic study

Physical exercise induces various stress responses and metabolic adaptations that have not yet been completely elucidated. Novel biomarkers are needed in sport veterinary medicine to monitor training levels and to detect subclinical conditions that can develop into exercise-related diseases. In this study, protein modifications in horse plasma induced by prolonged, aerobic physical exercise were investigated by using a proteomic approach based on 2-DE and combined mass spectrometry procedures. Thirty-eight protein spots, associated with expression products of 13 genes, showed significant quantitative changes; spots identified as membrane Cu amine oxidase, α-1 antitrypsin, α-1 antitrypsin-related protein, caeruloplasmin, α-2 macroglobulin and complement factor C4 were augmented in relative abundance after the race, while haptoglobin β chain, apolipoprotein A-I, transthyretin, retinol binding protein 4, fibrinogen γ chain, complement factor B and albumin fragments were reduced. These results indicate that prolonged physical exercise affects plasma proteins involved in pathways related to inflammation, coagulation, immune modulation, oxidant/antioxidant activity and cellular and vascular damage, with consequent effects on whole horse metabolism.     

Human factor XIa cleaves fibrinogen: effects on structure and function

Factor XIa, the enzymatic form of the factor XI zymogen, is generated as a result of factor XII-dependent surface activation in plasma. Factor XIa degrades high molecular weight kininogen, its cofactor for activation (which binds factor XIa to the surface), as well as cleaves and activates coagulation factor IX. In this report, we present evidence that factor XIa can also cleave fibrinogen and decrease the thrombin-catalyzed formation of the fibrin clot. Furthermore, the products of factor XIa-digested fibrinogen markedly inhibited the rate of polymerization of fibrin monomers. Factor XIa initially cleaved the A alpha-chain of fibrinogen and subsequently degraded the B beta-chain. However, the cleavage sites on both chains were distinct from those susceptible to thrombin. The gamma-chain was degraded only after prolonged incubation with factor XIa. Furthermore, the profile of fibrinogen proteolysis by factor XIa was distinctly different from that of plasmin-catalyzed fibrinogenolysis. Unlike plasmin, factor XIa was not able to cleave the NH2-terminus of the B beta-chain of fibrinogen. Moreover, factor XIa, unlike plasmin, failed to hydrolyze fibrin. Further study of the proteolytic digests of fibrinogen produced by factor XIa may give additional insight into the mechanism of polymerization of this protein.     

Reversible cross-linking of alpha 2-plasmin inhibitor to fibrinogen by fibrin-stabilizing factor

alpha 2-Plasmin inhibitor, a primary inhibitor of fibrinolysis, is cross-linked to fibrin by plasma transglutaminase (glutaminyl-peptide:amine gamma-glutamyltransferase, EC 2.3.2.13, activated fibrin-stabilizing factor) when blood coagulation takes place. alpha 2-Plasmin inhibitor was found also to be cross-linked to fibrinogen by plasma transglutaminase. The inhibitor was corss-linked exclusively to the A alpha-chain of fibrinogen, and the cross-linking reaction proceeded very rapidly. The reaction was almost completed before the formation of the gamma-chain dimers of fibrinogen which precedes cross-linking polymerization of the A alpha-chain of fibrinogen. The maximum level of inhibitor cross-linking achieved was approx. 30% of the inhibitor present at the start of the reaction. The level of cross-linking of the inhibitor was not changed when the cross-linking reaction was preceded by dimerization of fibrinogen. The cross-linking reaction was found to be a reversible one, since the cross-linked complex of the inhibitor and fibrinogen was partly dissociated to each of its components when the complex was incubated with plasma transglutaminase. These results suggest that the self-limiting nature of the cross-linking reaction between alpha 2-plasmin inhibitor and fibrin(ogen) is due to the reaction equilibrium favoring dissociation of the complex, and not due to the development of structural hindrance in polymerizing fibrin(ogen).     

Fibrinogen Nagoya, a replacement of glutamine-329 by arginine in the gamma-chain that impairs the polymerization of fibrin monomer

Structural studies on a hereditary abnormal fibrinogen, fibrinogen Nagoya (Takamatsu, J., Ogata, K., Kamiya, T., Koie, K., Takagi, T., & Iwanaga, S. (1979) Thromb. Haemost. 42, 78), were performed to identify the abnormality responsible for the impaired polymerization of fibrin monomer. Upon sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing conditions, fibrinogen Nagoya showed the presence of an extra protein band with an apparent molecular weight of 49,500 in addition to the normal three subunit chains. Amino acid sequence analysis of a peptide isolated from a lysyl endopeptidase digest of one of the CNBr fragments derived from fibrinogen Nagoya indicated that Gln-329 in the gamma-chain had been replaced by Arg. This substitution can be explained by a single nucleotide change in the codon for Gln-329 (CAG----CGG). We conclude that Gln-329 in the gamma-chain is indispensable for the normal polymerization of fibrin monomer.     

Functional impact of oxidative posttranslational modifications on fibrinogen and fibrin clots

Fibrinogen is a circulating multifunctional plasma protein vital for hemostasis. Activation of the coagulation cascade converts soluble fibrinogen to insoluble polymerized fibrin, which, along with platelets, forms the hemostatic clot. However, inappropriate formation of fibrin clots may result in arterial and venous thrombotic disorders that may progress to life-threatening adverse events. Often thrombotic disorders are associated with inflammation and the production of oxidants. Fibrinogen represents a potential target for oxidants, and several oxidative posttranslational modifications that influence fibrinogen structure and function have been associated with disease pathogenesis. Here, we review various oxidative modifications of fibrinogen and the consequences of these modifications on protein structure and the ability to form fibrin and how the resulting alterations affect fibrin architecture and viscoelastic and biochemical properties that may contribute to disease.     

Characterization of an abnormal fibrinogen Osaka V with the replacement of gamma-arginine 375 by glycine. The lack of high affinity calcium binding to D-domains and the lack of protective effect of calcium on fibrinolysis.

Prolonged thrombin time was completely corrected by the addition of millimolar concentrations of calcium in a new abnormal fibrinogen, Osaka V. Analysis of lysyl endopeptidase digests of A alpha-, B beta-, or gamma-chains by high performance liquid chromatography, and the following amino acid sequence analysis of relevant peptides revealed that about 50% of the gamma-chain has a replacement of gamma-arginine 375 by glycine. When fibrinogen was digested with plasmin in the presence of millimolar concentration of calcium, the amount of fragment D1 was about 50% of the normal control, and the rest was further cleaved to fragment D2, D3, or D62 with an apparent Mr of 62,000. Plasmic digestion of cross-linked fibrin in the presence of calcium resulted in the appearance of an abnormal fragment with an apparent Mr of 123,000 as well as fragments D2, D3, and D62, concomitant with the decrease of D dimer. The gamma-remnant of the abnormal fragment proved to be a cross-linked complex of the normal D1 gamma-remnant and residues 374-406/411 of the abnormal gamma-chain. The number of high affinity Ca(2+)-binding sites for the normal fibrinogen and fibrinogen Osaka V obtained by equilibrium dialysis was 2.88 (about 3) and 1.85, respectively, and that for the abnormal molecules was calculated as 0.9 (about 1) from their relative amounts in the samples, suggesting the lack of two Ca(2+)-binding sites in the D-domains. These data suggest that the normal structure of the COOH-terminal portion of the gamma-chain including residue 375 is required for the full expression of high affinity calcium binding to D-domains, the ability to be protected by calcium against plasmic digestion, and fibrin polymerization. During these studies, we found that the NH2-terminal amino acid of the gamma-remnant in fragments D or D dimer which were obtained after prolonged digestion with plasmin is gamma-Met89.     

Post-translational modification of apolipoprotein B by transglutaminases.

The major form of cross-link found in apolipoprotein B was identified as N1N12-bis-(gamma-glutamyl)spermine, a product known to be formed through the catalytic action of transglutaminases (EC 2.3.2.13). N1-(gamma-Glutamyl)spermine was present in a trace amount but epsilon-(gamma-glutamyl)lysine cross-links, which are formed during fibrin formation in plasma, were not detected. In the presence of catalytic amounts of plasma Factor XIIIa (a thrombin-dependent extracellular transglutaminase) or cellular transglutaminase (a cytosolic enzyme), apolipoprotein B and other plasma apolipoproteins (A-I, A-II and C) underwent covalently bridged polymerization and served as amine acceptor substrates. These results suggests that transglutaminases may participate in the covalent modification of apolipoproteins, either in the physiological state or during pathogenesis.     

Effect of fungal polysaccharides on the modulation of plasma proteins in streptozotocin-induced diabetic rats

To search out novel biomarkers for monitoring diabetes prognosis, we examined the effect of hypoglycemic fungal exopolysaccharides (EPS) on the differential levels of plasma proteins in streptozotocin-induced diabetic rats. The orally administrated EPS exhibited an excellent hypoglycemic effect, lowering the average plasma glucose level, and increasing insulin secretion in diabetic rats. The 2-DE analysis of rat plasma demonstrated that about 500 visualized spots were differentially regulated, of which 20 spots were identified as principal diabetes-associated proteins. The distinct effect of diabetes induction on the pattern of rat plasma proteins includes the down-regulation of albumin, apolipoprotein E (Apo E), alpha1-inhibitor-3, fetuin beta, Gc-globulin, hemopexin, vitronectin, and transthyretin (TTR) monomer, and the up-regulation of Apo A-I, Apo A-IV, ceruloplasmin, alpha1-antitrypsin, serine protease inhibitor III, and transferrin. Those protein levels were interestingly restored to those of healthy rats by EPS treatment, although the order of magnitude of the changes differed widely. Two proteins of interest showed distinct differential expression with opposite trends: TTR tetramer was significantly down-regulated and immunoglobulin (Ig) kappa light chain was significantly up-regulated upon diabetes induction, both of which were also normalized to those of healthy groups after EPS treatment.     

A congenitally abnormal fibrinogen (Vlissingen) with a 6-base deletion in the gamma-chain gene, causing defective calcium binding and impaired fibrin polymerization

A congenitally abnormal fibrinogen (Vlissingen) was isolated from the blood of a young woman suffering from massive pulmonary embolism. Fibrinogen Vlissingen showed an abnormal clotting time with both thrombin and Reptilase. The release of the fibrino-peptides A and B by thrombin was normal, but fibrin polymerization was impaired both in the presence and absence of Ca2+ ions. On sodium dodecyl sulfate-polyacrylamide gel electrophoresis performed according to Laemmli the gamma-chain of fibrinogen Vlissingen showed two bands, one normal and one having an apparently lower molecular mass of about 1,500 daltons. The previously described protective effect of Ca2+ ions on plasmin degradation of the carboxyl terminus of the gamma-chain of normal fibrinogen was only partially detectable in fibrinogen Vlissingen. In addition the binding of Ca2+ ions was decreased. Fibrinogen Vlissingen bound 2.4 Ca2+ ions per fibrinogen molecule at pH 7.4, whereas normal fibrinogen bound 3.1 Ca2+ ions. At pH 5.8 fibrinogen Vlissingen bound 1.1 Ca2+ ions, whereas normal fibrinogen bound 2.0 Ca2+ ions per molecule fibrinogen in the D-domains, again indicating a structural change in the carboxyl terminus of fibrinogen. The structural defect was determined by sequence analysis of DNA amplified by use of the polymerase chain reaction. Exons VIII, IX, and X of the gamma-chain gene were amplified and the DNA sequence of the amplified fragments was determined. A 6-base deletion was found in 50% of the fragments corresponding to exon VIII, indicating that the patient was heterozygous for the mutation. This deletion codes for amino acids Asn-319 and Asp-320 in the normal fibrinogen gamma-chain. The data indicate that Asn-319 and Asp-320 are crucial for maintaining the integrity of the carboxyl-terminal polymerization sites, the protective effect of Ca2+ ions on plasmin degradation of the carboxyl terminus of the gamma-chain, and the calcium binding domain at the carboxyl terminus of fibrinogen.     

Factors influencing the structure of terminal plasmin degradation products of human fibrinogen and fibrin

Experiments have been carried out with fibrinogen and with purified degradation products of fibrinogen and fibrin which demonstrate that the structure of D fragments obtained after prolonged plasmin digestion is influenced by several factors in the media. The previously described protective effect of calcium ions on the gamma-chain carboxy-terminals of fibrinogen against attack has been confirmed by working at high plasmin concentrations and/or in the presence of 2 M urea. Several compounds such as EDTA, EGTA, citrate and iminodiacetic acid appear to have a separate effect. In the absence of calcium ions these compounds appear to make the gamma-chain carboxy-terminal ends of the D and D-dimer fragments more susceptible to plasmin digestion. Finally, as demonstrated by experiments with purified D-E complexes from fibrinogen and with whole fibrinogen digests, the E moiety of the D-E complexes appears to be capable of protecting the D moiety against low plasmin concentrations also in the absence of calcium ions.     

Characterization of an apparently lower molecular weight gamma-chain variant in fibrinogen Kyoto I. The replacement of gamma-asparagine 308 by lysine which causes accelerated cleavage of fragment D1 by plasmin and the generation of a new plasmin cleavage site

Congenitally abnormal fibrinogen Kyoto I with impaired fibrin monomer polymerization contains a normal gamma-chain and a gamma-chain variant (gamma Kyoto I) that has an apparently lower Mr on sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the Laemmli system (Laemmli, U. K. (1970) Nature 227, 680-685) but migrates with apparently normal Mr in the Weber and Osborn system (Weber, K., and Osborn, M. (1969) J. Biol. Chem. 244, 4406-4412). Reverse-phase high performance liquid chromatographic analyses of the cyanogen bromide or lysyl endopeptidase cleavage fragments of the purified gamma-chains of fibrinogen Kyoto I showed the presence of peptides not seen from normal fibrinogen. Amino acid sequence analysis of these peptides indicated that gamma Asn308 of the gamma-chain variant is replaced by lysine. Purified fragment D1 of fibrinogen Kyoto I also contains two types of D1 gamma-remnants: normal and apparently lower Mr types. Abnormal fragment D1 is cleaved faster to fragments D2 and D3 by plasmin in the presence of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid (EGTA) than normal fragment D1, as analyzed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, followed by immunoblotting using anti-gamma-chain monoclonal antibody. Analysis of peptides released from fragment D1 by plasmin in the presence of EGTA demonstrated the cleavage of the gamma Lys308-Gly309 bond. Fragment D1 of fibrinogen Kyoto I has normal calcium binding properties. The data suggest that a region or conformation containing gamma Asn308 affects the polymerization of fibrin monomers and that the gamma Asn308----Lys replacement causes a conformational change in the gamma-chain which results in the accelerated cleavage of gamma Lys356-Ala357 and gamma Lys302-Phe303 bonds by plasmin and also results in the generation of a new plasmin cleavage site between Lys308 and Gly309 in the presence of EGTA. During these studies, we found that part of the gamma Lys212-Glu213 bond in fragment D1 is cleaved by plasmin in the presence of EGTA.     

Characterization of the interaction of recombinant apolipoprotein(a) with modified fibrinogen surfaces and fibrin clots.

Elevated levels of lipoprotein(a) [Lp(a)] in plasma are a significant risk factor for the development of atherosclerotic disease, a property which may arise from the ability of this lipoprotein to inhibit fibrinolysis. In the present study we have quantitated the binding of recombinant forms of apolipoprotein(a) [17K and 12K r-apo(a); containing 8 and 3 copies, respectively, of the major repeat kringle sequence (kringle IV type 2)] to modified fibrinogen surfaces. Iodinated 17K and 12K r-apo(a) bound to immobilized thrombin-modified fibrinogen (i.e., fibrin) surfaces with similar affinities (Kd approximately 1.2-1.6 microM). The total concentration of binding sites (Bmax) present on the fibrin surface was approximately 4-fold greater for the 12K than for the 17K (Bmax values of 0.81 +/- 0.09 nM, and 0.20 +/- 0.01 nM respectively), suggesting that the total binding capacity on fibrin surfaces is reduced for larger apolipoprotein(a) (apo(a)) species. Interestingly, binding of apo(a) to intact fibrin was not detected as assessed by measurement of intrinsic fluorescence of free apo(a) present in the supernatants of sedimented fibrin clots. In other experiments, the total concentration apo(a) binding sites available on plasmin-modified fibrinogen surfaces was shown to be 13.5-fold higher than the number of sites available on unmodified fibrin surfaces (Bmax values of 2.7 +/- 0.3 nM and 0.20 +/- 0.01 nM respectively) while the affinity of apo(a) for these surfaces was similar. The increase in Bmax was correlated with plasmin-mediated exposure of C-terminal lysines since treatment of plasmin-modified fibrinogen surfaces with carboxypeptidase B produced a significant decrease in total binding signal as detected by ELISA (enzyme linked immunosorbent assay). Taken together, these data suggest that apo(a) binds to fibrin with poor affinity (low microM) and that the total concentration of apo(a) binding sites available on modified-fibrinogen surfaces is affected by both apo(a) isoform size and by the increased availability of C-terminal lysines on plasmin-degraded fibrinogen surfaces. However, the low affinity of apo(a) for fibrin indicates that Lp(a) may inhibit fibrinolysis through a mechanism distinct from binding to fibrin, such as binding to plasminogen.     

Fibrin but not adsorbed fibrinogen supports fibronectin assembly by spread platelets. Effects of the interaction of alphaIIb beta3 with the C terminus of the fibrinogen gamma-chain

We investigated the assembly of soluble fibronectin by lysophosphatidic acid-activated platelets adherent to fibrinogen or fibrin. More fibronectin was assembled by activated platelets spread on fibrin matrices than by platelets spread on adsorbed fibrinogen. The difference between platelets adherent to fibrinogen and fibrin occurred under both static and flow conditions. Similar differences were seen in binding of the 70-kDa N-terminal fragment of fibronectin that recognizes fibronectin assembly sites on adherent cells. Antibody and peptide blocking studies demonstrated that alphaIIb beta3 integrin mediates platelet adhesion to fibrinogen, whereas both alphav beta3 and alphaIIb beta3 mediate platelet adhesion to fibrin. The hypothesis that engagement of the C-terminal QAGDV sequence of the fibrinogen gamma-chain by alphaIIb beta3 inhibits the ability of the platelet to assemble fibronectin was tested by several experiments. Activated platelets adherent to adsorbed mutant fibrinogen lacking the QAGDV sequence (gammadelta5FG) were assembly-competent, as were platelets adherent to adsorbed normal fibrinogen that had been pretreated with the 7E9 antibody to the C terminus of the gamma-chain. Moreover, adsorbed normal fibrinogen but not gammadelta5FG suppressed the ability of co-adsorbed fibronectin to direct assembly of soluble fibronectin by spread platelets. The suppressive effect was lost when a surface of co-adsorbed fibronectin and fibrinogen was pretreated with 7E9. These results support a model in which the engagement of alphaIIb beta3 by the C-terminal sequence of the fibrinogen gamma-chain initiates signals that suppress subsequent fibronectin assembly by spread platelets. This interaction is less dominant when platelets adhere to fibrin, resulting in enhanced fibronectin assembly.     

Analysis of engineered fibrinogen variants suggests that an additional site mediates platelet aggregation and that "B-b" interactions have a role in protofibril formation

The C-terminal domain of the fibrinogen gamma-chain includes multiple functional sites that have been defined in high-resolution structures and biochemical assays. Calcium binds to this domain through the side chains of gammaD318 and gammaD320 and the backbone carbonyls of gammaF322 and gammaG324. We have examined variant fibrinogens with alanine at position gamma318 and/or gamma320 and found that calcium binding, fibrin polymerization, and fibrinogen-mediated platelet aggregation, but not FXIIIa-catalyzed cross-linking, were abnormal. When measured by turbidity, thrombin-catalyzed polymerization was severely reduced, and batroxobin-catalyzed polymerization was completely obliterated. Moreover, thrombin-catalyzed polymerization was abolished by the peptide GHRP, which binds to the polymerization site in the beta-chain but does not inhibit polymerization of normal fibrinogen. ADP-induced platelet aggregation was also severely impaired. In contrast, as measured by SDS-PAGE, FXIIIa introduced cross-links between gamma-chains for all three variants, as expected if the gamma-chain C-terminal sites were normal. In addition, binding of the monoclonal antibody 4A5, which recognizes the C-terminal residues, was not different from normal. These data suggest two specific conclusions: (1) a site in the gamma-module other than the C-terminus is critical for platelet aggregation and (2) "B-b" interactions have a role in protofibril formation.     

Localization of segments essential for polymerization and for calcium binding in the gamma-chain of human fibrinogen

We have isolated an intermediate plasmic degradation product, D2, of fibrinogen that does not inhibit the polymerization of fibrin monomer but does bind Ca2+. Fibrinogen was digested to a limited extent with plasmin in the presence of Ca2+, and a "large" fragment D (fragment D1A) was isolated with a gamma-chain remnant consisting of residues 63-411. Fragment D1A was digested further in the presence of Ca2+, yielding fragment D1 (with its gamma-chain containing residues 86-411). The digestion of fragment D1 [in the presence of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid (EGTA) to complex Ca2+] led to a gradual shortening of the carboxyl-terminal portion of the gamma-chain. Fragment D2 (with its gamma-chain containing residues 86-335/356) was isolated from an intermediate digest in the presence of EGTA. The Lys-338-Cys-339 peptide bond of the gamma-chain is intact in this preparation of D2, even though it is split in the isolated peptide gamma303-355 (with an intact disulfide bond at Cys-326-Cys-339). Fragment D2 does not interfere with the polymerization of fibrin monomer, whereas fragment D1 is a potent inhibitor of this polymerization. We conclude that the gamma-chain segment 356/357-411, present in fragment D1 but absent from fragment D2, is essential for maintenance of a polymerization site located in the outer (D) nodule of fibrinogen. This segment (356/357-411) is longer than two shorter ones reported earlier [Olexa, S.A., & Budzynski, A. Z. (1981) J. Biol. Chem. 256, 3544-3549; Horwitz, B.H., Váradi, A., & Scheraga, H.A. (1984) Proc. Natl. Acad. Sci. U.S.A. 81, 5980-5984]; the data for the earlier reports are reinterpreted here. Finally, fragment D2 possesses a single Ca2+ binding site, as revealed by equilibrium dialysis binding studies. Since fragment D3 (with its gamma-chain containing residues 86-302) fails to bind Ca2+, we conclude that segment gamma 303-355/356 plays a crucial role in Ca2+ binding.     

Identification of fibrin clot-bound plasma proteins

Several proteins are known to bind to a fibrin network and to change clot properties or function. In this study we aimed to get an overview of fibrin clot-bound plasma proteins. A plasma clot was formed by adding thrombin, CaCl(2) and aprotinin to citrated platelet-poor plasma and unbound proteins were washed away with Tris-buffered saline. Non-covalently bound proteins were extracted, separated with 2D gel electrophoresis and visualized with Sypro Ruby. Excised protein spots were analyzed with mass spectrometry. The identity of the proteins was verified by checking the mass of the protein, and, if necessary, by Western blot analysis. Next to established fibrin-binding proteins we identified several novel fibrin clot-bound plasma proteins, including α(2)-macroglobulin, carboxypeptidase N, α(1)-antitrypsin, haptoglobin, serum amyloid P, and the apolipoproteins A-I, E, J, and A-IV. The latter six proteins are associated with high-density lipoprotein particles. In addition we showed that high-density lipoprotein associated proteins were also present in fibrinogen preparations purified from plasma. Most plasma proteins in a fibrin clot can be classified into three groups according to either blood coagulation, protease inhibition or high-density lipoprotein metabolism. The presence of high-density lipoprotein in clots might point to a role in hemostasis.     

Aggregates Dramatically Alter Fibrin Ultrastructure

Among the many factors influencing fibrin formation and structure (concentration, temperature, composition, pH, etc.), it has been suggested that the polydispersity of fibrinogen may play an important role. We propose here a detailed investigation of the influence of this parameter on fibrin multiscale structure. Two commercial fibrinogen preparations were used, a monodisperse and a polydisperse one. First, the respective compositions of both fibrinogen preparations were thoroughly determined by measuring the fibrin-stabilizing factor; fibronectin; α, β, and γ intact chain contents; the γ/γ′ chains ratio; the N-glycosylation; and the post-translational modifications. Slight variations between the composition of the two fibrinogen preparations were found that are much smaller than the compositional variations necessary to alter significantly fibrin multiscale structure as observed in the literature. Conversely, multiangle laser light scattering-coupled size exclusion chromatography and dynamic light scattering measurements showed that the polydisperse preparation contains significant amounts of aggregates, whereas the other preparation is essentially monodisperse. The multiscale structure of the fibrins produced from those two fibrinogen preparations was determined by using x-ray scattering, spectrophotometry, and confocal microscopy. Results show that fibers made from the aggregate-free fibrinogen present a crystalline longitudinal and lateral structure and form a mikado-like network. The network produced from the aggregates containing fibrinogen looks to be partly built around bright spots that are attributed to the aggregate. The multiscale structure of mixtures between the two preparations shows a smooth evolution, demonstrating that the quantity of aggregates is a major determining factor for fibrin multiscale structure. Indeed, the effect of a few percent in the mass of aggregates is larger than any other effect because of compositional differences under the same reaction conditions. Finally, we propose a mechanistic interpretation of our results, which points at a direct role of the aggregates during polymerization, which disrupts the ideal ordering of monomers inside fibrin protofibrils and fibers.     

Interaction of fibrinogen and its derivatives with fibrin

The binding between complementary polymerization sites of fibrin monomers plays an essential role in the formation of the fibrin clot. One set of polymerization sites involved in the interaction of fibrin monomers is believed to pre-exist in fibrinogen, while the complementary set of binding sites is exposed after the cleavage of fibrinopeptides from fibrinogen. The polymerization sites present in fibrinogen and its derivatives mediate their binding to fibrin. Although the binding of fibrinogen and its derivatives to fibrin have been qualitatively studied, there has been no systematic, quantitative investigation of their interaction with forming or preformed clots. In the present study, the binding of fibrinogen and fragments DD, D1, and E1 was measured using a sonicated suspension of plasminogen- and thrombin-free human cross-linked fibrin as a model of a preformed clot. Dissociation constants of 0.056, 0.19, and 2.44 microM, and the number of binding sites corresponding to 0.10, 0.21, and 0.13/fibrin monomer unit of fibrin polymer were found for fibrinogen, fragment DD, and fragment D1, respectively. Fragment E1 did not bind to sonicated noncross-linked or cross-linked fibrin suspensions. However, it was bound to forming fibrin clots as well as to fibrin-Celite, suggesting that the binding sites on fibrin involved in the interaction with fragment E1 may have been altered upon sonication. Affinity chromatography of various fibrinogen derivatives on a fibrin-Celite column showed that only part of the bound fragment DD was displaced by arginine, whereas fragments D1 and E1 were completely eluted under the same conditions. The results indicate that interaction of fibrinogen with the preformed fibrin clots is characterized by affinity in the nanomolar range and that binding between fibrin monomers, in the process of clot formation, could be characterized by even a higher affinity.     

Soluble fibrin consists of fibrin oligomers of heterogeneous distribution

Soluble fibrin is observed in patients with intravascular coagulation and represents an intermediary product of conversion of fibrin monomers into a fibrin clot whereby the presence of fibrinogen may suppress fibrin clot formation. The interactions between fibrin and fibrinogen and the occurrence of fibrin oligomers in soluble fibrin were studied by sucrose density ultracentrifugation. Different concentrations of soluble fibrin, prepared by mixing 125I-fibrin (24 nM - 1.5 microM) with a constant concentration of 131I-fibrinogen (6 microM) were analyzed at 37 degrees C in stable linear sucrose density gradients containing a uniform concentration of unlabelled fibrinogen (6 microM) and calcium ions in order to mimic the physiological situation. At any fibrin concentration, 125I-fibrin sedimented faster than 131I-fibrinogen through 5-30% (w/v) sucrose gradients. Sedimentation rates of fibrin increased from 9 S to 23 S depending on the initial fibrin concentration. The relative amount of residual fibrin monomer not incorporated into oligomers was calculated from the sedimentation profiles. At any fibrin concentration, the portion of free monomer was always more than twofold higher for batroxobin-generated (desAA-) fibrin than for thrombin-generated (desAABB-) fibrin. Apparent association constants for desAABB-fibrin were 3-10 times higher than those for desAA-fibrin indicating a stronger interaction between monomers of the former type of fibrin. In the presence of excess fibrinogen the predominant species in soluble desAA-fibrin were monomers and dimers, whereas dimers, trimers and higher-molecular-mass oligomers were present in soluble desAABB-fibrin. Strong interactions between both types of fibrin were demonstrated from their cosedimentation, whereby the size of these copolymers were shown to be governed by the oligomer size of the desAABB-fibrin type. These results provide evidence for the occurrence of differently sized oligomers of fibrin in soluble fibrin and for the concept of a cooperative polymerization process between both types of fibrin devoid of any stable complexes between fibrin and fibrinogen.     

Glycolaldehyde induces fibrinogen post-translational modification, delay in clotting and resistance to enzymatic digestion

Glycolaldehyde (GA) is a highly reactive aldehyde that can be generated during inflammation and hyperglycemia. It can react with arginine and lysine residues impairing protein function. As inflammation and diabetes present haemostatic dysfunction, we hypothesized that GA could participate in this process. The aim of this study was to investigate if plasma incubated in the presence of GA presents alteration in the coagulation process. We also aimed to evaluate the role of fibrinogen in GA-induced haemostatic dysfunction. For this purpose, plasma and fibrinogen were each incubated separately, either in the presence or absence of 1 mM GA for 8 and 4 h, respectively. After that, plasma coagulation and fibrin polymerization kinetics were recorded, as well as the kinetic of plasma clot digestion and fibrinolysis protein carbonylation was quantified. An SDS-PAGE was run to check the presence of cross-linking between fibrinogen chains. GA induced a delay in plasma coagulation and in fibrin polymerization. Maximum absorbance decreased after GA treatment, indicating the generation of thinner fibers. Fibrin generated after complete coagulation showed resistance to enzymatic digestion, which could be related to the generation of thinner fibers. Protein carbonylation also increased after GA treatment. All parameters could be reversed with AMG (a carbonyl trap) co-treatment. The data presented herein indicate that GA causes post-translational modification of lysine and arginine residues, which are central to many events involving fibrinogen to fibrin conversion, as well as to fibrinolysis. These modifications lead to the generation of persistent clots and may contribute to mortality seen in pathologies such diabetes and sepsis.