Spectroscopic studies of fibrinogen and its plasmin-derived fragments.

The secondary structure of human fibrinogen and its plasmin-fragments have been studied by FTIR spectroscopy. The quantitative results for fibrinogen are in good agreement with previous studies using circular dichroism spectroscopy. After treatment of fibrinogen with plasmin in buffer containing Ca2+, two major fragments are produced: fragment E (Mw 45,000) and fragment D (Mw 100,000). Fragment E is shown to contain 50% alpha-helical values, attributed to its coiled-coil portions, and minor beta-strands and turn structures. Its deuteration gives evidence of the presence of solvent-exposed alpha-helical structures. On the other hand, fragment D contains a distribution of secondary structure values of 35% alpha-helix, 29% beta-sheet segments and 17% turn structures. Fragment D itself has two domains: a portion of the original coiled-coil and also a thermally labile globular domain. The coiled-coil portion (Mw 27,000) was isolated and showed a high alpha-helical content (around 70%). The globular domain is estimated to be rich in beta-sheet structures. The spectra of fibrin clots formed in Ca(2+)-containing buffer have a lower amide I/amide II ratio than fibrinogen spectra, which is interpreted as being due to aggregation.     

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.     

Domains in human plasminogen

Calorimetric studies of intramolecular melting of human plasminogen and of its fragments under various solvent conditions show that the intact plasminogen molecule consists of seven compact co-operative subunits, which can be regarded as structural domains. Five of these domains are formed by the homologous regions, the kringles, two domains are formed by the C-terminal part of the polypeptide chain that is split at activation, forming the light chain in plasmin, while the initial 76 amino acid residue peptide does not form any compact co-operative structure. The specific influence of epsilon-aminocaproic acid on the stability of the first, the fourth and, to a lesser extent, on the second kringle domain, provides evidence that these three domains in plasminogen possess lysine-binding ability. The first four kringle domains are almost independent in the molecule, while the fifth interacts with that part of the light chain not included in either of the two domains of this chain. These two domains are of different size and co-operate strongly in plasminogen, but at its activation into plasmin they decooperate and the stability of the smaller domain, which is formed by the N-terminal part of the light chain, decreases significantly. Since the light chain is responsible for the proteolytic activity of plasmin, it becomes clear that the active site of this protein is composed of two domains, as is the case for other serine proteases.     

Anticoagulant and calcium-binding properties of high molecular weight derivatives of human fibrinogen (plasmin fragments Y)

The present study was undertaken as a step to delineate further the localization of the calcium-binding sites in fibrinogen and to assess the anticlotting properties of fibrinogen degradation products. To this purpose, fragments Y were prepared by plasmin digestion of human fibrinogen in the presence of added Ca2+, and purified. We found that, on a molar basis, fragments Y exhibit twice as much anticlotting activity as fragments X. They possess two calcium-binding sites with Kd = 1.9 . 10(-5) M. Their predominant amino-terminal amino acids are alanine and tyrosine. It is known that one binding site in fragment Y is related to its D moiety. We conclude that the other calcium-binding site may be located in the central domain of the molecule.     

Zn2+ Mediates High Affinity Binding of Heparin to the αC Domain of Fibrinogen

The nonspecific binding of heparin to plasma proteins compromises its anticoagulant activity by reducing the amount of heparin available to bind antithrombin. In addition, interaction of heparin with fibrin promotes formation of a ternary heparin-thrombin-fibrin complex that protects fibrin-bound thrombin from inhibition by the heparin-antithrombin complex. Previous studies have shown that heparin binds the E domain of fibrinogen. The current investigation examines the role of Zn²⁺ in this interaction because Zn²⁺ is released locally by platelets and both heparin and fibrinogen bind the cation, resulting in greater protection from inhibition by antithrombin. Zn²⁺ promotes heparin binding to fibrinogen, as determined by chromatography, fluorescence, and surface plasmon resonance. Compared with intact fibrinogen, there is reduced heparin binding to fragment X, a clottable plasmin degradation product of fibrinogen. A monoclonal antibody directed against a portion of the fibrinogen αC domain removed by plasmin attenuates binding of heparin to fibrinogen and a peptide analog of this region binds heparin in a Zn²⁺-dependent fashion. These results indicate that the αC domain of fibrinogen harbors a Zn²⁺-dependent heparin binding site. As a consequence, heparin-catalyzed inhibition of factor Xa by antithrombin is compromised by fibrinogen to a greater extent when Zn²⁺ is present. These results reveal the mechanism by which Zn²⁺ augments the capacity of fibrinogen to impair the anticoagulant activity of heparin.     

Prion Domain of Yeast Ure2 Protein Adopts a Completely Disordered Structure: A Solid-Support EPR Study

Amyloid fibril formation is associated with a range of neurodegenerative diseases in humans, including Alzheimer’s, Parkinson’s, and prion diseases. In yeast, amyloid underlies several non-Mendelian phenotypes referred to as yeast prions. Mechanism of amyloid formation is critical for a complete understanding of the yeast prion phenomenon and human amyloid-related diseases. Ure2 protein is the basis of yeast prion [URE3]. The Ure2p prion domain is largely disordered. Residual structures, if any, in the disordered region may play an important role in the aggregation process. Studies of Ure2p prion domain are complicated by its high aggregation propensity, which results in a mixture of monomer and aggregates in solution. Previously we have developed a solid-support electron paramagnetic resonance (EPR) approach to address this problem and have identified a structured state for the Alzheimer’s amyloid-β monomer. Here we use solid-support EPR to study the structure of Ure2p prion domain. EPR spectra of Ure2p prion domain with spin labels at every fifth residue from position 10 to position 75 show similar residue mobility profile for denaturing and native buffers after accounting for the effect of solution viscosity. These results suggest that Ure2p prion domain adopts a completely disordered structure in the native buffer. A completely disordered Ure2p prion domain implies that the amyloid formation of Ure2p, and likely other Q/N-rich yeast prion proteins, is primarily driven by inter-molecular interactions.     

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.     

The effect of “aging” of fibrinogen molecule on the structure and properties of fibrin gel

The effect of molecular “aging” of fibrinogen stimulated by preincubation in solution on the fibrin three-dimensional architecture, its ability to crosslink fibrin-stabilizing factor, and the sensitivity of fibringel to plasmin hydrolysis have been studied. The method of elastic light scattering was used to demonstrate that fibrin generated from “defective” fibrinogen had a coarser structure with a higher mean mass-length ratio of polymeric fibers compared to native fibrinogen (2.24 × 10⁹ and 1.46 × 10⁹ g/(mol cm), respectively). Crosslinking had no effect on the architecture of both control and experimental fibrin samples. Spectrophotometric and electrophoretic analysis has shown a higher sensitivity of coarse fibrin gels to plasmin. A close correlation between spontaneous local conformational reconstructions in fibrinogen molecule and its functional activity is concluded.     

Primary structure of fibrinogen, its relation to conformation and function of the molecule

Data available in literature are generalized for the amino acid sequence of three fibrinogen chains, their homology and a possibility for their common precursor to exist. The primary structure of resistant products of fibrinogen splitting by plasmin, compactness of their space organization and mutual arrangement in the intact molecule are described. The relation between the primary structure of fibrinogen and its high specificity as a thrombin substrate is traced. Evidence is considered concerning localization of active molecule centres to provide spontaneous polymerization of fibrin.     

Human plasminogen catalytic domain undergoes an unusual conformational change upon activation

Activation of the serine protease plasmin from its zymogen, plasminogen, is the key step in fibrinolysis leading to blood clot dissolution. It also plays critical roles in cell migration, such as in tumor metastasis. Here, we report the crystal structure of an inactive S741A mutant of human plasminogen catalytic domain at 2.0 A resolution. This structure permits a direct comparison with that of the plasmin catalytic unit. Unique conformational differences are present between these two structures that are not seen in other zymogen-enzyme pairs of the trypsin family. The functional significance of these differences and the structural basis of plasminogen activation is discussed in the light of this new structure.     

Sites of D-domain interaction in fibrin-derived D dimer

We have examined the plasmic digestion products of fibrin formed in the presence of dansylcadaverine, the fluorescent D dimer, to determine whether they are held together not only by the cross-link region on the gamma chain but also by other interactions on the D domain. Antibodies to the D dimer reacted 8X more strongly with sites on the D dimer (purified or in the presence of E) than with sites on fibrinogen or plasmin-digested fibrinogen. The reactivity of this surface site was lost when the gamma chain was cleaved by plasmin after the molecule had been destabilized by the removal of calcium ions, thus breaking the covalent linkage of the homodimer. The noncovalent D dimer retained its dimeric structure by the criteria of molar volume, measured by fluorescence polarization, and molecular sieving. The noncovalently attached, cross-link-containing peptide bound tightly to the parent molecules at higher temperatures but rotated more freely below 15 degrees C, and could be lost from the parent molecules without destroying the dimeric structure. We therefore propose that the forces maintaining the dimeric structure of the noncovalently joined molecule are not solely located at the gamma-chain cross-link region. These other sites on the D domain are therefore candidates for the initial fibrinogen polymerization site and may also have a role in fibrinogen half-molecule assembly.     

Hydrodynamic and mass spectrometry analysis of nearly-intact human fibrinogen, chicken fibrinogen, and of a substantially monodisperse human fibrinogen fragment X

The shape and solution properties of fibrinogen are affected by the location of the C-terminal portion of the Aα chains, which is presently still controversial. We have measured the hydrodynamic properties of a human fibrinogen fraction with these appendages mostly intact, of chicken fibrinogen, where they lack 11 characteristic 13-amino acids repeats, and of human fragment X, a plasmin early degradation product in which they have been removed. The human fibrinogen/fragment X samples were extensively characterized by SDS-PAGE/Western blotting and mass spectrometry, allowing their composition to be precisely determined. The solution properties of all samples were then investigated by analytical ultracentrifugation and size-exclusion HPLC coupled with multi-angle light scattering and differential pressure viscometry detectors. The measured parameters suggest that the extra repeats have little influence on the overall fibrinogen conformation, while a significant change is brought about by the removal of the C-terminal portion of the Aα chains beyond residue Aα200.     

A Proline-Tryptophan Turn in the Intrinsically Disordered Domain 2 of NS5A Protein Is Essential for Hepatitis C Virus RNA Replication

Hepatitis C virus (HCV) nonstructural protein 5A (NS5A) and its interaction with the human chaperone cyclophilin A are both targets for highly potent and promising antiviral drugs that are in the late stages of clinical development. Despite its high interest in regards to the development of drugs to counteract the worldwide HCV burden, NS5A is still an enigmatic multifunctional protein poorly characterized at the molecular level. NS5A is required for HCV RNA replication and is involved in viral particle formation and regulation of host pathways. Thus far, no enzymatic activity or precise molecular function has been ascribed to NS5A that is composed of a highly structured domain 1 (D1), as well as two intrinsically disordered domains 2 (D2) and 3 (D3), representing half of the protein. Here, we identify a short structural motif in the disordered NS5A-D2 and report its NMR structure. We show that this structural motif, a minimal Pro³¹⁴–Trp³¹⁶ turn, is essential for HCV RNA replication, and its disruption alters the subcellular distribution of NS5A. We demonstrate that this Pro-Trp turn is required for proper interaction with the host cyclophilin A and influences its peptidyl-prolyl cis/trans isomerase activity on residue Pro³¹⁴ of NS5A-D2. This work provides a molecular basis for further understanding of the function of the intrinsically disordered domain 2 of HCV NS5A protein. In addition, our work highlights how very small structural motifs present in intrinsically disordered proteins can exert a specific function.     

Probing the gamma2 calcium-binding site: studies with gammaD298,301A fibrinogen reveal changes in the gamma294-301 loop that alter the integrity of the "a" polymerization site

To determine the significance of the gamma2 calcium-binding site in fibrin polymerization, we synthesized the fibrinogen variant, gammaD298,301A. We expected these two alanine substitutions to prevent calcium binding in the gamma2 site. We examined the influence of calcium on the polymerization of gammaD298,301A fibrinogen, evaluated its plasmin susceptibility, and solved 2.7 and 2.4 A crystal structures of the variant with the peptide ligands Gly-Pro-Arg-Pro-amide (GPRP) and Gly-His-Arg-Pro-amide (GHRP), respectively. We found that thrombin-catalyzed polymerization of gammaD298,301A fibrinogen was modestly impaired, whereas batroxobin-catalyzed polymerization was significantly impaired relative to normal fibrinogen. Notably, the influence of calcium on polymerization was the same for the variant and for normal fibrinogen. Fibrinogen gammaD298,301A was more susceptible to plasmin proteolysis in the presence of GPRP. This finding suggests structural changes in the near-by "a" polymerization site. Comparisons of the structures revealed minor conformational changes in the gamma294-301 loop that are likely responsible for the weakened "a" site. When considered altogether, the data suggest that the gamma2 calcium-binding site does not significantly modulate polymerization. We cannot, however, rule out the possibility that the weakened "a" polymerization site masks an important role for the gamma2 calcium-binding site in normal polymerization. Somewhat unexpectedly, the structure data showed that GPRP bound to the "b" site and induced the same local conformational changes as GHRP to this site. This structure shows that "A:b" interactions can occur and suggests that these may participate in normal polymerization.     

Modulation of the proteolytic activity of matrix metalloproteinase-2 (gelatinase A) on fibrinogen

The proteolytic processing of bovine fibrinogen by MMP-2 (gelatinase A), which brings about the formation of a product unable to form fibrin clots, has been studied at 37 degrees C. Catalytic parameters, although showing a somewhat lower catalytic efficiency with respect to thrombin and plasmin, indeed display values indicating a pathophysiological significance of this process. A parallel molecular modelling study predicts preferential binding of MMP-2 to the beta-chain of fibrinogen through its haemopexin-like domain, which has been directly demonstrated by the inhibitory effect in the presence of the exogenous haemopexin-like domain. However, the removal of this domain does not impair the interaction between MMP-2 and fibrinogen, but it dramatically alters the proteolytic mechanism, producing different fragmentation intermediates. The investigation at various pH values between 6.0 and 9.3 indicates a proton-linked behaviour, which is relevant for interpreting the influence on the process by environmental conditions occurring at the site of an injury. Furthermore, the action of MMP-2 on peroxynitrite-treated fibrinogen has been investigated, a situation possibly occurring under oxidative stress. The chemical alteration of fibrinogen, which has been shown to abolish its clotting activity, brings about only limited modifications of the catalytic parameters without altering the main enzymatic mechanism.     

Thrombin binding to the A alpha-, B beta-, and gamma-chains of fibrinogen and to their remnants contained in fragment E

In order to study thrombin interaction with fibrinogen, thrombin binding to fragments D and E (prepared by plasmin digestion of fibrinogen) and to intact S-carboxymethylated chains of fibrinogen (A alpha, B beta, and gamma) was analyzed by autoradiography, immunoblotting, and affinity chromatography. Complex formation was observed between late fragment E and thrombin but not with fragment D. The three reduced chain remnants of fragment E all formed complexes with thrombin. Also, thrombin bound to the intact, separated A alpha, B beta, and gamma chains of fibrinogen as well as to the alpha and beta chains of fibrin. In these experiments the extended substrate-binding site, but not the catalytic-binding site, was being examined because fragment E had as its amino-terminal amino acids Val20 in the alpha chain, Lys54 in the beta chain, and Tyr1 in the gamma chain. Also, thrombin inhibited in its active center by D-phenyl-alanyl-L-prolyl-L-arginine-chloromethyl ketone bound to fragment E and to the separated chains in the same manner as unmodified thrombin. A lysine residue to thrombin was essential for its binding to fibrinogen. Thrombin attached to CNBr-activated Sepharose through its amino groups did not bind to fragment E, but when thrombin was attached through its carboxyl groups, it bound fragment E.     

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.     

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.