Crystal structure of a recombinant alphaEC domain from human fibrinogen-420

Interplay of fibrinogen αEC globular domains and factor XIIIa cross-linking dictates the extensibility and strain stiffening of fibrin networks

BACKGROUND

Fibrinogen is a plasma protein forming the fibrin scaffold of blood clots. Its mechanical properties therefore affect the risk of bleeding as well as thrombosis. There has been much recent interest in the biophysical mechanisms controlling fibrin mechanics; however, the role of molecular heterogeneity of the circulating fibrinogen in determining clot mechanical function remains poorly characterized.

OBJECTIVES

By comparing 2 fibrinogen variants where the only difference is the Aα-chain length, with one variant having a globular domain at its C-terminus, this study aimed to reveal how the molecular structure impacts the structure and mechanics of fibrin networks.

METHODS

We characterized the mechanical response to large shear for networks formed from 2 recombinant fibrinogen variants: the most prevalent variant in circulation with a molecular weight of 340 kDa (recombinant human fibrinogen [rFib] 340) and a minor variant with a molecular weight of 420 kDa (rFib420).

RESULTS

We show that the elastic properties of the 2 variants are identical when fibrin is cross-linked with factor XIIIa but differ strongly in its absence. Uncross-linked rFib420 networks are softer and up to 3-fold more extensible than rFib340 networks. Electron microscopy imaging showed that the 2 variants formed networks with a comparable structure, except at 4 mg/mL, where rFib420 formed denser networks.

CONCLUSION

We propose that the αEC domains of rFib420 increase the extensibility of uncross-linked fibrin networks by promoting protofibril sliding, which is blocked by FXIIIa cross-linking. Our findings can help explain the functional role of different circulating fibrinogen variants in blood clot mechanics and tissue repair.

A genetic modifier of venous thrombosis in zebrafish reveals a functional role for fibrinogen AαE in early hemostasis

Plasma fibrinogen molecules comprise 2 copies of Aα, Bβ, and γ chains folded into a hexameric protein. A minor fibrinogen isoform with an extended Aα chain (AαE) is more abundant in newborn human blood than in adults. Larval zebrafish produce predominantly AαE-containing fibrinogen, but its functional significance is unclear. In 3-day-old zebrafish, when hemostasis is reliant on fibrinogen and erythrocyte-rich clotting but is largely thrombocyte-independent, we measured the time to occlusion (TTO) in a laser-induced venous thrombosis assay in 3 zebrafish strains (AB, TU, and AB × TL hybrids). AB larvae showed delayed TTO compared with the TU and AB × TL strains. Mating AB with TU or TL produced larvae with a TU-like TTO. In contrast to TU, AB larvae failed to produce fibrinogen AαE, due to a mutation in the AαE-specific coding region of fibrinogen α-chain gene (fga). We investigated whether the lack of AαE explained the delayed AB TTO. Transgenic expression of AαE, but not Aα, shortened the AB TTO to that of TU. AαE rescued venous occlusion in fibrinogen mutants or larvae with morpholino-targeted fibrinogen α-chain messenger RNA, but Aα was less effective. In 5-day-old larvae, circulating thrombocytes contribute to hemostasis, as visualized in Tg(itga2b:EGFP) transgenics. Laser-induced venous thrombocyte adhesion and aggregation is reduced in fibrinogen mutants, but transgenic expression of Aα or AαE restored similar thrombocyte accumulation at the injury site. Our data demonstrate a genetic modifier of venous thrombosis and a role for fibrinogen AαE in early developmental blood coagulation, and suggest a link between differentially expressed fibrinogen isoforms and the cell types available for clotting.

Fibrinogen splice variation and cross-linking: Effects on fibrin structure/function and role of fibrinogen γ' as thrombomobulin II

Fibrin is an important matrix protein that provides the backbone to the blood clot, promoting tissue repair and wound healing. Its precursor fibrinogen is one of the most heterogeneous proteins, with an estimated 1 million different forms due to alterations in glycosylation, oxidation, single nucleotide polymorphisms, splice variation and other variations. Furthermore, ligation by transglutaminase factor XIII (cross-linking) adds to the complexity of the fibrin network. The structure and function of the fibrin network is in part determined by this natural variation in the fibrinogen molecule, with major effects from splice variation and cross-linking. This mini-review will discuss the direct effects of fibrinogen αEC and fibrinogen γ' splice variation on clot structure and function and also discuss the additional role of fibrinogen γ' as thrombomodulin II. Furthermore, the effects of cross-linking on clot function will be described. Splice variation and cross-linking are major determinants of the structure and function of fibrin and may therefore impact on diseases affecting bleeding, thrombosis and tissue repair.

Clinical features and molecular basis of 102 Chinese patients with congenital dysfibrinogenemia

INTRODUCTION

Congenital dysfibrinogenemia (CD) is a rare qualitative disorder of fibrinogen (Fg) with heterogeneous clinical manifestations. We aimed to analyze clinical phenotype and molecular basis of 102 Chinese CD patients and to evaluate the application of thromboelastography (TEG).

MATERIALS AND METHODS

Clinical manifestations were recorded and quantified using the consensus ISTH bleeding assessment tool. Kaolin activated TEG and functional Fg TEG were applied in 30 patients. Genetic analysis of Fg genes were performed by direct sequencing.

RESULTS

27.5% patients experienced bleeding, 3.9% had thrombosis and 68.6% were asymptomatic. Females were more prone to experience bleeding (P=0.01). Significant difference (P<0.05) in TEG results were found between patients with hot-spot mutations at AαArg35(16) and γArg301(275), but were not identified between patients with and without bleeding. Normal TEG results were found in patients with mutations at AαArg35(16), AαPro37(18) or AαArg38(19). Six novel mutations were identified, including AαGly33(14)del, AαAsp57(38)_Trp60(41)delIVS2+1_+2GTdel, AαPhe742(723)Tyr, γAsn334(308)Thr, γGly335(309)Cys and γTrp395(369)Leu.

CONCLUSIONS

CD patients have similar clinical manifestations and hot-spot mutations worldwide with no ethnic difference. TEG results could not indicate the bleeding risk in patients, but priority of mutation screening at thrombin cleavage site or polymerization site on Aа chain may be given if TEG results are normal.

Correlating structure and function during the evolution of fibrinogen-related domains

Fibrinogen-related domains (FReDs) are found in a variety of animal proteins with widely different functions, ranging from non-self recognition to clot formation. All appear to have a common surface where binding of one sort or other occurs. An examination of 19 completed animal genomes--including a sponge and sea anemone, six protostomes, and 11 deuterostomes--has allowed phylogenies to be constructed that show where various types of FReP (proteins containing FReDs) first made their appearance. Comparisons of sequences and structures also reveal particular features that correlate with function, including the influence of neighbor-domains. A particular set of insertions in the carboxyl-terminal subdomain was involved in the transition from structures known to bind sugars to those known to bind amino-terminal peptides. Perhaps not unexpectedly, FReDs with different functions have changed at different rates, with ficolins by far the fastest changing group. Significantly, the greatest amount of change in ficolin FReDs occurs in the third subdomain ("P domain"), the very opposite of the situation in most other vertebrate FReDs. The unbalanced style of change was also observed in FReDs from non-chordates, many of which have been implicated in innate immunity.

Fibrinogen triggers astrocyte scar formation by promoting the availability of active TGF-beta after vascular damage

Scar formation in the nervous system begins within hours after traumatic injury and is characterized primarily by reactive astrocytes depositing proteoglycans that inhibit regeneration. A fundamental question in CNS repair has been the identity of the initial molecular mediator that triggers glial scar formation. Here we show that the blood protein fibrinogen, which leaks into the CNS immediately after blood-brain barrier (BBB) disruption or vascular damage, serves as an early signal for the induction of glial scar formation via the TGF-beta/Smad signaling pathway. Our studies revealed that fibrinogen is a carrier of latent TGF-beta and induces phosphorylation of Smad2 in astrocytes that leads to inhibition of neurite outgrowth. Consistent with these findings, genetic or pharmacologic depletion of fibrinogen in mice reduces active TGF-beta, Smad2 phosphorylation, glial cell activation, and neurocan deposition after cortical injury. Furthermore, stereotactic injection of fibrinogen into the mouse cortex is sufficient to induce astrogliosis. Inhibition of the TGF-beta receptor pathway abolishes the fibrinogen-induced effects on glial scar formation in vivo and in vitro. These results identify fibrinogen as a primary astrocyte activation signal, provide evidence that deposition of inhibitory proteoglycans is induced by a blood protein that leaks in the CNS after vasculature rupture, and point to TGF-beta as a molecular link between vascular permeability and scar formation.

[Molecular mechanisms of the polymerization of fibrin and the formation of its three-dimensional network]

The results of biochemical, immunochemical, and X-ray studies of the structures of fibrinogen and fibrin molecules were analyzed. The mechanisms of the successive formation of the fibrin three-dimensional network were described: the polymerization of monomeric molecules with the formation of bifilar protofibrils, the lateral association of protofibrils, and the embranchment of the forming fibrils. Data on the electron and confocal microscopy of the polymeric fibrin were considered. The role of the known polymerization centers of fibrin which participated in the formation of protofibrils and their lateral association was discussed. Data on the existence of the previously unknown polymerization centers were given. In particular, the experimental results demonstrated that one of such centers which participated in the formation of protofibrils was located in the Bbeta12-46 fragment, and did not require the cleavage of fibrinopeptide B for its functioning. The results of the computer modeling of the spatial structure of the fibrin(ogen) molecule and the intermolecular interactions in the course of the fibrin polymerization were presented. The location of the alphaC domains in the fibrin(ogen) molecule and their role in the polymerization process were discussed. Information on the structure of the calcium-binding sites of fibrin(ogen) and the functional role of Ca2+ in fibrin polymerization was published. The structure of factor XIII(a) and the mechanisms of fibrin stabilization by this factor were briefly described.

Crystal structure of human fibrinogen

A crystal structure of human fibrinogen has been determined at approximately 3.3 A resolution. The protein was purified from human blood plasma, first by a cold ethanol precipitation procedure and then by stepwise chromatography on DEAE-cellulose. A product was obtained that was homogeneous on SDS-polyacrylamide gels. Nonetheless, when individual crystals used for X-ray diffraction were examined by SDS gel electrophoresis after data collection, two species of alpha chain were present, indicating that some proteolysis had occurred during the course of operations. Amino-terminal sequencing on post-X-ray crystals showed mostly intact native alpha- and gamma-chain sequences (the native beta chain is blocked). The overall structure differs from that of a native fibrinogen from chicken blood and those reported for a partially proteolyzed bovine fibrinogen in the nature of twist in the coiled-coil regions, likely due to weak forces imparted by unique crystal packing. As such, the structure adds to the inventory of possible conformations that may occur in solution. Other features include a novel interface with an antiparallel arrangement of beta chains and a unique tangential association of coiled coils from neighboring molecules. The carbohydrate groups attached to beta chains are unusually prominent, the full sweep of 11 sugar residues being positioned. As was the case for native chicken fibrinogen, no resolvable electron density could be associated with alphaC domains.

The ultrastructure of fibrinogen-420 and the fibrin-420 clot

Fibrinogen-420 is a minor subclass of human fibrinogen that is so named because of its higher molecular weight compared to fibrinogen-340, the predominant form of circulating fibrinogen. Each of the two Aalpha chains of fibrinogen-340 is replaced in fibrinogen-420 by an Aalpha isoform termed alphaE. Such chains contain a globular C-terminal extension, alphaEC, that is homologous with the C-terminal regions of Bbeta and gamma chains in the fibrin D domain. The alphaEC domain lacks a functional fibrin polymerization pocket like those found in the D domain, but it does contain a binding site for beta2 integrins. Electron microscopy of fibrinogen-340 molecules showed the major core fibrinogen domains, D-E-D, plus globular portions of the C-terminal alphaC domains. Fibrinogen-420 molecules had two additional globular domains that were attributable to alphaEC. Turbidity measurements of thrombin-cleaved fibrinogen-420 revealed a reduced rate of fibrin polymerization and a lower maximum turbidity. Thromboelastographic measurements also showed a reduced rate of fibrin-420 polymerization (amplitude development) compared with fibrin-340. Nevertheless, the final amplitude (MA) and the calculated elastic modulus (G) for fibrin-420 were greater than those for fibrin-340. These results suggested a greater degree of fibrin-420 branching and thinner matrix fibers, and such structures were found in SEM images. In addition, fibrin-420 fibers were irregular and often showed nodular structures protruding from the fiber surface. These nodularities represented alphaEC domains, and possibly alphaC domains as well. TEM images of negatively shadowed fibrin-420 networks showed irregular fiber borders, but the fibers possessed the same 22.5-nm periodicity that characterizes all fibrin fibers. From this result, we conclude that fibrin-420 fiber assembly occurs through the same D-E interactions that drive the assembly of all fibrin fibrils, and therefore that the staggered overlapping molecular packing arrangement is the same in both types of fibrin. The alphaEC domains are arrayed on fiber surfaces, and in this location, they would very likely slow lateral fibril association, causing thinner, more branched fibers to form. However, their location on the fiber surface would facilitate cellular interactions through the integrin receptor binding site.

Multiple binding sites in fibrinogen for integrin alphaMbeta2 (Mac-1)

The leukocyte integrin alphaMbeta2 (Mac-1) is a multiligand receptor that mediates a range of adhesive reactions of leukocytes during the inflammatory response. This integrin binds the coagulation protein fibrinogen providing a key link between thrombosis and inflammation. However, the mechanism by which alphaMbeta2 binds fibrinogen remains unknown. Previous studies indicated that a model in which two fibrinogen gammaC domain sequences, P1 (gamma190-202) and P2 (gamma377-395), serve as the alphaMbeta2 binding sites cannot fully account for recognition of fibrinogen by integrin. Here, using surface plasmon resonance, we examined the interaction of the ligand binding alphaMI-domain of alphaMbeta2 with the D fragment of fibrinogen and showed that this ligand is capable of associating with several alphaMI-domain molecules. To localize the alternative alphaMI-domain binding sites, we screened peptide libraries covering the complete sequences of the gammaC and betaC domains, comprising the majority of the D fragment structure, for alphaMI-domain binding. In addition to the P2 and P1 peptides, the alphaMI-domain bound to many other sequences in the gammaC and betaC scans. Similar to P1 and P2, synthetic peptides derived from gammaC and betaC were efficient inhibitors of alphaMbeta2-mediated cell adhesion and were able to directly support adhesion suggesting that they contain identical recognition information. Analyses of recognition specificity using substitutional peptide libraries demonstrated that the alphaMI-domain binding depends on basic and hydrophobic residues. These findings establish a new model of alphaMbeta2 binding in which the alphaMI-domain interacts with multiple sites in fibrinogen and has the potential to recognize numerous sequences. This paradigm may have implications for mechanisms of promiscuity in ligand binding exhibited by integrin alphaMbeta2.

Determining the crystal structure of fibrinogen

Summary. I have enjoyed reading previous historical sketches that have appeared in Journal of Thrombosis and Haemostasis, and especially those by Ted Tuddenham on factor VIII and Bjorn Dahlback on activated protein C resistance. Like those authors, I have tried to capture some of the excitement-as well as the disappointments-that occurred along the way to a long-term goal.

A (13)-beta-d-glucan recognition protein from the sponge Suberites domuncula. Mediated activation of fibrinogen-like protein and epidermal growth factor gene expression

Sponges (phylum Porifera) live in a symbiotic relationship with microorganisms, primarily bacteria. Until now, molecular proof for the capacity of sponges to recognize fungi in the surrounding aqueous milieu has not been available. Here we demonstrate, for the demosponge Suberites domuncula (Porifera, Demospongiae, Hadromerida), a cell surface receptor that recognizes (1-->3)-beta-D-glucans, e.g. curdlan or laminarin. This receptor, the (1-->3)-beta-D-glucan-binding protein, was identified and its cDNA analysed. The gene coding for the 45 kDa protein was found to be upregulated in tissue after incubation with carbohydrate. Simultaneously with the increased expression of this gene, two further genes showed an elevated steady state level of expression; one codes for a fibrinogen-like protein and the other for the epidermal growth factor precursor. Expression of the (1-->3)-beta-D-glucan-binding protein and the fibrinogen-like protein occurred in cells on the sponge surface, in the pinacoderm. By Western blotting, the product of the fibrinogen-like protein gene was identified, the recombinant protein isolated, and antibodies raised to this protein. Their application revealed that a 5 kDa factor is produced, which is apparently processed from the 77 kDa epidermal growth factor precursor. Finally, we provided evidence that a tyrosine kinase pathway is initiated in response to exposure to D-glucan; its phosphorylation activity could be blocked by aeroplysinin. In turn, the increased expression of the downstream genes was suppressed. We conclude that sponges possess a molecular mechanism for recognizing fungi via the d-glucan carbohydrates on their surfaces.

X-ray crystallographic studies on fibrinogen and fibrin

More than a dozen crystal structures of fibrinogen and fibrin fragments have been reported, including a structure of a native fibrinogen. The majority of the other structures are fragments D and d-dimer crystallized in the presence or absence of synthetic peptide ligands patterned on the A and B 'knobs'. Overall, fibrinogens or their fragments from four different species--human, bovine, chicken and lamprey--have been studied so far, with only minor differences in the structures being observed. Although these studies have thrown much light on the details of the fibrinogen to fibrin conversion, much remains to be found out.

Structural basis of the fibrinogen-fibrin transformation: contributions from X-ray crystallography

During the past several years, a number of crystal structures have been determined of fragments from fibrinogen and fibrin and, most recently, a structure of a native fibrinogen. One feature of the fibrinogen molecule that has emerged from these studies has to do with its "loose ends," segments of the molecule that are extremely mobile and not discernable by X-ray crystallography. Some, if not all, of this flexibility is functionally important. Small synthetic peptides based on mobile parts of fibrinogen exposed by the action of thrombin have contributed significantly to these studies and may yet prove useful therapeutically. In the end, although crystal structures have added greatly to our understanding of fibrin formation, much still needs to be unraveled about how clots form.

Gamma371 Thr-->Ile substitution in the fibrinogen gammaD domain causes hypofibrinogenaemia

Six members of a family with hypofibrinogenaemia had fibrinogen concentrations ranging from 0.5 to 1.1 mg/ml and, after sequencing the entire coding region and the intron exon boundaries of all three fibrinogen genes, a single heterozygous ACT-->ATT mutation was identified in the gamma gene. This novel mutation was not detected in normal family members or unrelated controls. The gamma371 Thr-->Ile substitution occurs at a conserved threonine in the gammaD domain, but molecules containing the new isoleucine were not present in circulating fibrinogen. The evidence for this was that purified gamma chains had a normal mass of 48375 Da compared to a control of 48374 Da, and tryptic peptide maps were entirely normal. The mutation predicts a mass increase of 12 Da in peptide T-36, but on mass mapping only the normal [M+2H] ion was detected, at 948 m/z. There was no new signal at 954 m/z that would indicate expression of variant chains. Also the normal 948 m/z signal was at the same intensity in digests from the proposita and controls. Crystal structures show a hydrogen bond from the threonine hydroxyl to the main chain and this case suggests this bond is critical in maintaining the structure of the gammaD domain.

The alternatively spliced alpha(E)C domain of human fibrinogen-420 is a novel ligand for leukocyte integrins alpha(M)beta(2) and alpha(X)beta(2)

The interaction of human plasma fibrinogen with leukocyte integrins alpha(M)beta(2) (CD11b/CD18, Mac-1) and alpha(X)beta(2) (CD11c/CD18, p150,95) is an important component of the inflammatory response. Previously, it was demonstrated that binding of fibrinogen to these integrins is mediated by gammaC, the globular C-terminal domain of the gamma chain. In this study, evidence was found of another fibrinogen domain that can serve as a ligand for the 2 leukocyte integrins: alpha(E)C, a homologous domain that extends the alpha chains in a recently discovered subclass of fibrinogen known as fibrinogen-420. Recombinant alpha(E)C supported strong adhesion and migration of cells expressing alpha(M)beta(2) and alpha(X)beta(2), including nonactivated and activated U937 and THP-1 monocytoid cells, and neutrophils. Cells transfected with complementary DNA for these integrins also bound alpha(E)C. The specificity of interaction was substantiated by inhibition of cell adhesion with antibodies against alpha(M), alpha(X), and beta(2) subunits. Also, neutrophil inhibitory factor, a specific inhibitor of alpha(M)beta(2) and alpha(X)beta(2) function, efficiently blocked cell adhesion to alpha(E)C. In alpha(M)beta(2) and alpha(X)beta(2), the I domain is the binding site for alpha(E)C, since alpha(E)C bound to recombinant alpha(M) I and alpha(X)I domains in a dose-dependent and saturable manner. Synthetic peptides that duplicated sequences gamma190 to 202 and gamma377 to 395, previously considered putative binding sites in gammaC, effectively inhibited alpha(M)beta(2)- and alpha(X)beta(2)-mediated adhesion to alpha(E)C, suggesting that recognition of alpha(E)C by the I domain involves structural features in common with those of gammaC. These findings identify alpha(E)C as a second domain in fibrinogen-420 that binds alpha(M)beta(2) and alpha(X)beta(2) and can mediate leukocyte adhesion and migration.

Contribution of the alpha EC domain to the structure and function of fibrinogen-420

In addition to the conventional fibrinogen with its alpha, beta, and gamma subunit chains, there is a subclass of fibrinogen molecules, accounting for one percent of the total in human adults, in which both alpha chains have been replaced by extended alpha chains (alpha E) that sport a globular C-terminal domain (alpha EC) comparable to beta C and gamma C. Using nomenclature based on molecular weight, the subclass of alpha E-containing molecules has been named fibrinogen-420 to differentiate it from the better known fibrinogen, now referred to as fibrinogen-340. Review of the events leading to the discovery of fibrinogen-420 in the early 1990s and its subsequent characterization, culminating in the crystal structure of its unique alpha EC domains, highlights special aspects of its evolutionary history, outstanding features of its structure, and the perplexities of its biology. Various working hypotheses that have driven prior investigation are evaluated and practical insights are offered to spur further research into the role of fibrinogen-420.

Molecular mechanisms of hypo- and afibrinogenemia

Point mutations responsible for hypo- and afibrinogenemia are yielding new insights into amino acid side chains involved in the molecular processing, assembly, secretion, and domain stability of fibrinogen. Reverse phase chromatography, isoelectric focussing, electrospray mass spectrometry, and tryptic peptide mass mapping have shown that chains with heterozygous mutations of gamma 284 Gly-->Arg, B beta 316 Asp-->Tyr and gamma 371 Thr-->Ile are absent from plasma fibrinogen. The nonexpression of these mutations appears to result from perturbation of the five-stranded beta sheet of the D domain. We propose that this is due to retention of the variant in the endoplasmic reticulum and that in turn this leads to hypofibrinogenemia. Other mutations effect intracellular proteolysis and chain assembly. For example the mutation, A alpha 20 Val-->Asp, makes the protein a substrate for furin, which removes the first 19 residues of the A alpha chain as the mature molecule transits the trans golgi complex. Transient expression of gamma 153 Cys-->Arg chains together with A alpha and B beta chains suggests this mutation might perturb chain assembly, and the incorporation of mutations of B beta 353 Leu-->Arg or B beta 400 Gly-->Asp into intracellular fibrinogen precludes its subsequent export from host cells expressing fibrinogen genes. The graded severity of the hypo- and afibrinogenemias associated with homozygous A alpha chain truncations suggest the absolute minimal requirement for molecular assembly is the formation of the C terminal disulfide ring of the coiled coil.

Crystal structure studies on fibrinogen and fibrin

X-ray crystallography studies on fragments D and double-D from human fibrinogen and fibrin have revealed the details of knob-hole interactions between fibrin units, as well as the nature of the association at their ends. More recently, a lower-resolution structure of native chicken fibrinogen has provided details about the structure of the central domain, and particularly the arrangement of disulfide bonds. Parts of the fibrinogen molecule are so flexible that they have not been visualized in electron density maps. The elusive regions include the alpha C domain, the amino-terminal segments of the alpha and beta chains, and the carboxyl-terminal segments of the gamma chains. Nonetheless, when all the structural data are considered together, it is possible to construct a realistic model not only of a fibrinogen molecule but also of a fibrin protofibril.

Identification of residues in the Staphylococcus aureus fibrinogen-binding MSCRAMM clumping factor A (ClfA) that are important for ligand binding

Clumping factor A (ClfA) is a cell surface-associated protein of Staphylococcus aureus that promotes binding of this pathogen to both soluble and immobilized fibrinogen (Fg). Previous studies have localized the Fg-binding activity of ClfA to residues 221-559 within the A region of this protein. In addition, the C-terminal part of the A region (residues 484-550) has been implicated as being important for Fg binding. In this study, we further investigate the involvement of this part of ClfA in the interaction of this protein with Fg. Polyclonal antibodies generated against a recombinant protein encompassing residues 500-559 of the A region inhibited the interaction of both S. aureus and recombinant ClfA with immobilized Fg in a dose-dependent manner. Using site-directed mutagenesis, two adjacent residues, Glu(526) and Val(527), were identified as being important for the activity of ClfA. S. aureus expressing ClfA containing either the E526A or V527S substitution exhibited a reduced ability to bind to soluble Fg and to adhere to immobilized Fg. Furthermore, bacteria expressing ClfA containing both substitutions were almost completely defective in Fg binding. The E526A and V527S substitutions were also introduced into recombinant ClfA (rClfA-(221-559)) expressed in Escherichia coli. The single mutant rClfA-(221-559) proteins showed a significant reduction in affinity for both immobilized Fg and a synthetic fluorescein-labeled C-terminal gamma-chain peptide compared with the wild-type protein, whereas the double mutant rClfA-(221-559) protein was almost completely defective in binding to either species. Substitution of Glu(526) and/or Val(527) did not appear to alter the secondary structure of rClfA-(221-559) as determined by far-UV circular dichroism spectroscopy. These data suggest that the C terminus of the A region may contain at least part of the Fg-binding site of ClfA and that Glu(526) and Val(527) may be involved in ligand recognition.

Recombinant protein expression in Pichia pastoris

The methylotrophic yeast Pichia pastoris is now one of the standard tools used in molecular biology for the generation of recombinant protein. P. pastoris has demonstrated its most powerful success as a large-scale (fermentation) recombinant protein production tool. What began more than 20 years ago as a program to convert abundant methanol to a protein source for animal feed has been developed into what is today two important biological tools: a model eukaryote used in cell biology research and a recombinant protein production system. To date well over 200 heterologous proteins have been expressed in P. pastoris. Significant advances in the development of new strains and vectors, improved techniques, and the commercial availability of these tools coupled with a better understanding of the biology of Pichia species have led to this microbe's value and power in commercial and research labs alike.

Fibrinogen brescia: hepatic endoplasmic reticulum storage and hypofibrinogenemia because of a gamma284 Gly-->Arg mutation

The proposita suffered from liver cirrhosis and biopsy showed type 1 membrane-bound fiberglass inclusions. The hepatic inclusion bodies were weakly periodic acid-Schiff diastase-positive, and on immunoperoxidase staining reacted specifically with anti-fibrinogen antisera. Coagulation investigations revealed low functional and antigenic fibrinogen together with a prolonged thrombin time of 37 seconds (normal, 17 to 22 seconds) suggestive of a hypodysfibrinogenemia. DNA sequencing of all three fibrinogen genes showed a single heterozygous mutation of GGG (Gly)-->CGG (Arg) at codon 284 of the gamma-chain gene. However, examination of purified fibrinogen chains by sodium dodecyl sulfate-polyacrylamide gel electrophoresis, reverse-phase high-performance liquid chromatography, ion-exchange high-performance liquid chromatography, and isoelectric focusing, failed to show any evidence of the mutant gamma(Br) chain in plasma fibrinogen. This finding was substantiated by electrospray ionization mass spectrometry, which showed only a normal gamma (and Bbeta) chain mass, but a large increase in the portion of their disialo isoforms. We speculate that misfolding of the variant protein causes hepatic retention and the subsequent hypofibrinogenemia, and that the functional defect (dysfibrinogenemia) results from hypersialylation of otherwise normal Bbeta and gamma chains consequent to the liver cirrhosis. These conclusions were supported by studies on six other family members with hypofibrinogenemia, and essentially normal clotting times, who were heterozygous for the gamma284 Gly-->Arg mutation.

Identification of amino acid sequences in fibrinogen gamma -chain and tenascin C C-terminal domains critical for binding to integrin alpha vbeta 3

Integrin alpha(v)beta(3) recognizes fibrinogen gamma and alpha(E) chain C-terminal domains (gammaC and alpha(E)C) but does not require the gammaC dodecapeptide sequence HHLGGAKQAGDV(400-411) for binding to gammaC. We have localized the alpha(v)beta(3) binding sites in gammaC using gammaC-derived synthetic peptides. We found that two peptides GWTVFQKRLDGSV(190-202) and GVYYQGGTYSKAS(346-358) block the alpha(v)beta(3) binding to gammaC or alpha(E)C, block the alpha(v)beta(3)-mediated clot retraction, and induce the ligand-induced binding site 2 (LIBS2) epitope in alpha(v)beta(3). Neither peptide affects fibrinogen binding to alpha(IIb)beta(3). Scrambled or inverted peptides were not effective. These results suggest that the two gammaC-derived peptides directly interact with alpha(v)beta(3) and specifically block alpha(v)beta(3)-gammaC or alpha(E)C interaction. The two sequences are located next to each other in the gammaC crystal structure, although they are separate in the primary structure. Asp-199, Ser-201, Gln-350, Thr-353, Lys-356, Ala-357, and Ser-358 residues are exposed to the surface. This suggests that the two sequences are part of alpha(v)beta(3) binding sites in fibrinogen gammaC domain. We also found that tenascin C C-terminal fibrinogen-like domain specifically binds to alpha(v)beta(3). Notably, a peptide WYRNCHRVNLMGRYGDNNHSQGVNWFHWKG from this domain that includes the sequence corresponding to gammaC GVYYQGGTYSKAS(346-358) specifically binds to alpha(v)beta(3), suggesting that fibrinogen and tenascin C C-terminal domains interact with alpha(v)beta(3) in a similar manner.

The αEC domain of human fibrinogen-420 is a stable and early plasmin cleavage product

Human fibrinogen-420, (Eβγ)2, was isolated from plasma and evaluated for its ability to form clots and for its susceptibility to proteolysis. Clotting parameters, including cross-linking of subunit chains, of this subclass and of the more abundant fibrinogen-340 (βγ)2, were found to be similar, suggesting little impact of the unique EC domains of fibrinogen-420 on coagulation. Sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS-PAGE) analysis of plasmic digestion patterns revealed production from fibrinogen-420 of the conventional fibrinogen degradation products, X, Y, D, and E, to be comparable to that from fibrinogen-340 in all respects except the presence of at least 2 additional cleavage products that were shown by Western blot analysis to contain the EC domain. One was a stable fragment (ECX) comigrating with a 34-kd yeast recombinant EC domain, and the other was an apparent precursor. Their release occurred early, before that of fragments D and E. Two bands of the same mobility and antibody reactivity were found in Western blots of plasma collected from patients with myocardial infarction shortly after the initiation of thrombolytic therapy.

The αEC domain of human fibrinogen-420 is a stable and early plasmin cleavage product

Human fibrinogen-420, (Eβγ)2, was isolated from plasma and evaluated for its ability to form clots and for its susceptibility to proteolysis. Clotting parameters, including cross-linking of subunit chains, of this subclass and of the more abundant fibrinogen-340 (βγ)2, were found to be similar, suggesting little impact of the unique EC domains of fibrinogen-420 on coagulation. Sodium dodecyl sulfate–polyacrylamide gel electrophoresis (SDS-PAGE) analysis of plasmic digestion patterns revealed production from fibrinogen-420 of the conventional fibrinogen degradation products, X, Y, D, and E, to be comparable to that from fibrinogen-340 in all respects except the presence of at least 2 additional cleavage products that were shown by Western blot analysis to contain the EC domain. One was a stable fragment (ECX) comigrating with a 34-kd yeast recombinant EC domain, and the other was an apparent precursor. Their release occurred early, before that of fragments D and E. Two bands of the same mobility and antibody reactivity were found in Western blots of plasma collected from patients with myocardial infarction shortly after the initiation of thrombolytic therapy.

Hypofibrinogenemia in an individual with 2 coding (γ82 A→G and Bβ235 P→L) and 2 noncoding mutations

We investigated the molecular basis of hypofibrinogenemia in a man with a normal thrombin clotting time. Protein analysis indicated equal plasma expression of 2 different Bβ alleles, and DNA sequencing confirmed heterozygosity for a new Bβ235 P→L mutation. Protein analysis also revealed a novel γD chain, present at a ratio of 1:2 relative to the γA chain. Mass spectrometry indicated a 14 d decrease in the γD-chain mass, and DNA sequencing showed this was caused by a novel γ82 A→G substitution. DNA sequencing established heterozygosity for 2 further mutations: T→C in intron 4 of the A gene and A→C in the 3′ noncoding region of the Bβ gene. Studies on the man's daughter, together with plasma expression levels, discounted both the A and Bβ mutations as the cause of the low fibrinogen, suggesting that the γ82 mutation caused the hypofibrinogenemia. This was supported by analysis of 31 normal controls in whom the Bβ mutations were found at polymorphic levels, with an allelic frequency of 5% for the Bβ235 mutation and 42% for the Bβ 3′ untranslated mutation. The γ82 mutation was, however, unique to the propositus. Residue γ82 is located in the triple helix that separates the E and D domains, and aberrant packing of the helices may explain the decreased fibrinogen concentration.

Heterologous protein expression in the methylotrophic yeast Pichia pastoris

During the past 15 years, the methylotrophic yeast Pichia pastoris has developed into a highly successful system for the production of a variety of heterologous proteins. The increasing popularity of this particular expression system can be attributed to several factors, most importantly: (1) the simplicity of techniques needed for the molecular genetic manipulation of P. pastoris and their similarity to those of Saccharomyces cerevisiae, one of the most well-characterized experimental systems in modern biology; (2) the ability of P. pastoris to produce foreign proteins at high levels, either intracellularly or extracellularly; (3) the capability of performing many eukaryotic post-translational modifications, such as glycosylation, disulfide bond formation and proteolytic processing; and (4) the availability of the expression system as a commercially available kit. In this paper, we review the P. pastoris expression system: how it was developed, how it works, and what proteins have been produced. We also describe new promoters and auxotrophic marker/host strain combinations which extend the usefulness of the system.

Three-dimensional structural studies on fragments of fibrinogen and fibrin

Fibrinogen is a 340 kDa glycoprotein found in the blood plasma of all vertebrates. It is transformed into a fibrin clot by the action of thrombin. Recent X-ray structures of core fragments of both fibrinogen and fibrin have revealed many details about this polymerization event. These include structures of a 30 kDa recombinant gammaC domain, an 86 kDa fragment D from human fibrinogen and a cross-linked double-D fragment from fibrin.

The EC Domains of Human Fibrinogen420Contain Calcium Binding Sites But Lack Polymerization Pockets

The extended  (E) isoform unique to Fibrinogen420 (Fib420) is distinguished from the conventional  chain of Fibrinogen340 by the presence of an additional 236-residue carboxyl terminus globular domain (EC). A recombinant form of EC (rEC), having a predicted mass of 27,653 Daltons, was expressed in yeast (Pichia pastoris) and purified by anion exchange column chromatography. Purified rEC appears to be predominantly intact, as judged by N-terminal sequence analysis, mass spectral analysis of the C-terminal cyanogen bromide (CNBr) fragment, and comparison of recognition by epitope-specific monoclonal antibodies. Carbohydrate determination, coupled with analysis of CNBr digestion fragments, confirms N-linked glycosylation at Asn667, the site at which sugar is attached in E. Analysis of CNBr digestion fragments confirms that two disulfide bridges exist at cysteine pairs E613/644 and E780/793. In the presence of 5 mmol/L EDTA, rEC is highly susceptible to plasmic degradation, but Ca2+ (5 mmol/L) renders rEC resistant. No protective effect from plasmic degradation was conferred to rEC by the peptides GPRPamide or GHRP, nor did rEC bind to a GPR peptide column. These results suggest that the EC domain contains a calcium-binding site, but lacks a polymerization pocket. By analogy with the site elucidated in the γC domain, we predict that the EC calcium binding site involves residues E772-778: DADQWEE.

The EC Domains of Human Fibrinogen420Contain Calcium Binding Sites But Lack Polymerization Pockets

The extended  (E) isoform unique to Fibrinogen420 (Fib420) is distinguished from the conventional  chain of Fibrinogen340 by the presence of an additional 236-residue carboxyl terminus globular domain (EC). A recombinant form of EC (rEC), having a predicted mass of 27,653 Daltons, was expressed in yeast (Pichia pastoris) and purified by anion exchange column chromatography. Purified rEC appears to be predominantly intact, as judged by N-terminal sequence analysis, mass spectral analysis of the C-terminal cyanogen bromide (CNBr) fragment, and comparison of recognition by epitope-specific monoclonal antibodies. Carbohydrate determination, coupled with analysis of CNBr digestion fragments, confirms N-linked glycosylation at Asn667, the site at which sugar is attached in E. Analysis of CNBr digestion fragments confirms that two disulfide bridges exist at cysteine pairs E613/644 and E780/793. In the presence of 5 mmol/L EDTA, rEC is highly susceptible to plasmic degradation, but Ca2+ (5 mmol/L) renders rEC resistant. No protective effect from plasmic degradation was conferred to rEC by the peptides GPRPamide or GHRP, nor did rEC bind to a GPR peptide column. These results suggest that the EC domain contains a calcium-binding site, but lacks a polymerization pocket. By analogy with the site elucidated in the γC domain, we predict that the EC calcium binding site involves residues E772-778: DADQWEE.

Formation of the Human Fibrinogen Subclass Fib420: Disulfide Bonds and Glycosylation in Its Unique (EChain) Domains

COS cell transfection has been used to monitor the assembly and secretion of fibrinogen molecules, both those of the subclass containing the novel E chain and those of the more abundant subclass whose  chains lack E’s globular C-terminus. That region, referred to as the EC domain, is closely related to the ends of β and γ chains of fibrinogen (βC and γC). Transfection of COS cells with E, β, and γ cDNAs alone results in secretion of the symmetrical molecule (Eβγ)2, also known as Fib420. Cotransfection with cDNA for the shorter  chain yielded secretion of both (βγ)2 and (Eβγ)2 but no mixed molecules of the structure E(βγ)2. Exploiting the COS cells’ fidelity with regard to Fib420 production, identification was made of the highly conserved Asn667 as the sole site of N-linked glycosylation in the E chain. No evidence from Cys → Ser replacements was found for interchain disulfide bridges involving the four cysteines of the EC domain. However, for fibrinogen secretion, the E, β, and γ subunits do exhibit different requirements for integrity of the two intradomain disulfide bridges located at homologous positions in their respective C-termini, indicating dissimilar structural roles in the process of fibrinogen assembly.

© 1998 by The American Society of Hematology.

Formation of the Human Fibrinogen Subclass Fib420: Disulfide Bonds and Glycosylation in Its Unique (EChain) Domains

COS cell transfection has been used to monitor the assembly and secretion of fibrinogen molecules, both those of the subclass containing the novel E chain and those of the more abundant subclass whose  chains lack E’s globular C-terminus. That region, referred to as the EC domain, is closely related to the ends of β and γ chains of fibrinogen (βC and γC). Transfection of COS cells with E, β, and γ cDNAs alone results in secretion of the symmetrical molecule (Eβγ)2, also known as Fib420. Cotransfection with cDNA for the shorter  chain yielded secretion of both (βγ)2 and (Eβγ)2 but no mixed molecules of the structure E(βγ)2. Exploiting the COS cells’ fidelity with regard to Fib420 production, identification was made of the highly conserved Asn667 as the sole site of N-linked glycosylation in the E chain. No evidence from Cys → Ser replacements was found for interchain disulfide bridges involving the four cysteines of the EC domain. However, for fibrinogen secretion, the E, β, and γ subunits do exhibit different requirements for integrity of the two intradomain disulfide bridges located at homologous positions in their respective C-termini, indicating dissimilar structural roles in the process of fibrinogen assembly.

© 1998 by The American Society of Hematology.