Identification of covalently linked trimeric and tetrameric D domains in crosslinked fibrin.

Mosesson, Michael W.; Siebenlist, Kevin R.; Amrani, David L.; DiOrio, James P.

doi:10.1073/pnas.86.4.1113

Cited by 83 publications

(82 citation statements)

References 65 publications

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“…This ␥ chain flexibility would also help to explain the formation of interfibrillar crosslinked ␥ trimers and ␥ tetramers, occurring in a setting of previously formed ␥ dimers (24) and is consistent with the fact that neither Yee et al (27) nor Spraggon et al (21) visualized this segment of the ␥ chain in their crystal structures. The idea that this region is flexible also is strongly suggested by our present observation that C-terminal ␥ chains are situated in several locations in the D domain ranging from distal to proximal.…”

Section: Discussionmentioning

confidence: 62%

“…Recently, the ''end-to-end'' crosslinking idea received somewhat revised support from studies of crystals of crosslinked D dimer fragments (21), in which crosslinked C-terminal ␥ chains, though not situated at the extreme end of the molecule as originally envisioned, were inferred nevertheless to traverse the abutting D domains in an end-to-end alignment. However, several independent lines of evidence, beginning with reports by Selmayr et al (22,23), have indicated that the crosslinked ␥ chain segments in fibrin do not straddle the ends of adjacent D domains but rather tend to extend transversely between each fibril strand (1,(24)(25)(26). Evidence in favor of the transverse bond arrangement includes among the above cited articles, the electron microscopic demonstration of double-stranded crosslinked fibrinogen fibrils, visualization of bridging filaments representing transversely positioned ␥ chains within crosslinked fibrinogen fibrils (1) and in crosslinked D-fibrin-D complexes (26), and evidence indicating that the abutting ends of fibrin D domains where end-to-end intermolecular contacts are now recognized to occur (the so-called D:D site) (1,21,25), do not as first proposed (20), contain the C-terminal ␥ chain segment.…”

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confidence: 99%

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The location of the carboxy-terminal region of γ chains in fibrinogen and fibrin D domains

Mosesson

Siebenlist

Meh

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

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Fibrinogen molecules are Ϸ45 nm in length and are comprised of three major globular domains. There are two outer D domains, each connected by a ''coiled-coil'' region to the central E domain, within which the halves of each molecule are joined by disulfide bridges (Fig. 1). This article is concerned with precisely locating the carboxy-terminal segment of the ␥ chain, a region termed ''␥ XL '', that comprises one of several self-association sites in fibrinogen D domains (1). The ␥ XL sequence contains one factor XIIIa amine donor͞acceptor-crosslinking site between ␥406K and ␥398Q or ␥399Q [␥398͞ 399Q] (2-4), as well as an overlapping platelet fibrinogen receptor-binding site lying between ␥400 and ␥411 (5).To approach our objective, we prepared fibrinogen into which thioacetyl cadaverine amine donors had been covalently incorporated at glutamine acceptor sites in the presence of factor XIIIa (plasma transglutaminase) (Fig. 2). Subsequently, we labeled the thiol group on the cadaverine with an electron dense thiol-specific gold-cluster compound, undecagoldmonoaminopropyl maleimide (Au 11 ) (6). Au 11 -cadaverinelabeled fibrinogen was then examined by high resolutionscanning transmission electron microscopy (STEM) (7) to locate the Au 11 clusters that had been covalently attached at the amine acceptor site (␥398͞399Q) in the D domain. The relatively small diameter (0.8 nm) of the Au 11 cluster (6) provides a discriminating ultrastructural probe for pinpointing its position in the fibrinogen molecule. Gold cluster labeling has been applied to several proteins or nucleic acids for topographical molecular mapping of specific binding sites or domains (7-11 inter alia) and in particular has been used to determine precisely the location as well as the orientation of the amino terminal portions of the two A␣ chains within each fibrinogen E domain (12).The C-terminal region of each ␥ chain contains a single crosslinking site at which factor XIIIa catalyzes the formation of ␥ dimers (1, 13, 14) by incorporating intermolecular reciprocal -(␥-glutamyl) lysine bridges between a donor ␥406 lysine of one chain and a glutamine acceptor at ␥398͞399 of another (2-4). ␥ chain crosslinking occurs solely between these residues (2-4, 15, 16), whereas there are several amine donor lysine and amine acceptor glutamine sites in A␣ chains (16,17). Primary amine compounds like cadaverine are competitive amine donor substrates that become specifically incorporated in the presence of factor XIIIa at the single ␥ chain acceptor site or at one or more ␣ chain acceptor sites (2-4, 15, 18, 19).Noncovalent interaction between D and E domains in an assembling fibrin polymer facilitates the antiparallel intermolecular alignment of ␥ chain pairs in D domains, thereby accelerating the rate at which factor XIIIa-catalyzed crosslinking occurs at ␥ XL sites (1,14). Since the report by Fowler et al. (20), which involved electron microscopic observations on crosslinked fibrinogen dimers, it has been commonly held that the C-terminal ␥ chain crossl...

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Section: Discussionmentioning

confidence: 62%

mentioning

confidence: 99%

The location of the carboxy-terminal region of γ chains in fibrinogen and fibrin D domains

Mosesson

Siebenlist

Meh

et al. 1998

Proc. Natl. Acad. Sci. U.S.A.

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“…These findings indicate that the Tokyo II Fibrin polymerization begins after cleavage and release of two amino-terminal A fibrinopeptides from the central 'E' domain of fibrinogen molecules, exposing each of the 'A' polymerization sites they mask in precursor fibrinogen molecules ( 1-5 ). Each exposed 'A' site then combines noncovalently with a constitutive complementary 'a' site in the outer 'D' domain of a neighboring fibrin molecule, a necessary interaction ('D:E') for producing the half-staggered, end-to-middle domain pairing that results in twisting (6-10), double-stranded fibrils (6)(7)(8)(9)(10)(11)(12)(13)(14) (Fig. 1).…”

Section: Introductionmentioning

confidence: 99%

The role of fibrinogen D domain intermolecular association sites in the polymerization of fibrin and fibrinogen Tokyo II (gamma 275 Arg-->Cys).

Mosesson

Siebenlist²,

DiOrio³

et al. 1995

J. Clin. Invest.

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“…Factor XIIIa then introduces intermolecular covalent [ε-(␥-Glu)Lys] isopeptide bonds into these polymers, creating ␥-dimers. This is followed by the formation of crosslinks between complementary sites on ␣ chains and among ␥-dimers, completing the mature network structure (31). During fibrinolysis, the fibrin polymer is converted into soluble product by the action of plasmin, which is generated from plasminogen by urokinase and tissue plasminogen activator (tPA).…”

mentioning

confidence: 99%

Vibrio vulnificus Secretes a Broad-Specificity Metalloprotease Capable of Interfering with Blood Homeostasis through Prothrombin Activation and Fibrinolysis

et al. 2005

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Vibrio vulnificus is a causative agent of serious food-borne diseases in humans related to the consumption of raw seafood. It secretes a metalloprotease that is associated with skin lesions and serious hemorrhagic complications. In this study, we purified and characterized an extracellular metalloprotease (designated as vEP) having prothrombin activation and fibrinolytic activities from V. vulnificus ATCC 29307. vEP could cleave various blood clotting-associated proteins such as prothrombin, plasminogen, fibrinogen, and factor Xa, and the cleavage could be stimulated by addition of 1 mM Mn 2؉ in the reaction. The cleavage of prothrombin produced active thrombin capable of converting fibrinogen to fibrin. The formation of active thrombin appeared to be transient, with further cleavage resulting in a loss of activity. The cleavage of plasminogen, however, did not produce an active plasmin. vEP could cleave all three major chains of fibrinogen without forming a clot. It could cleave fibrin polymer formed by thrombin as well as the cross-linked fibrin formed by factor XIIIa. In addition, vEP could also cleave plasma proteins such as bovine serum albumin and gamma globulin, and its broad specificity is reflected in the cleavage sites, which include Asp 207 -Phe 208 and Thr 272 -Ala 273 bonds in prothrombin and a Tyr 80 -Leu 81 bond in plasminogen. Taken together, the data suggest that vEP is a broad-specificity protease that could function as a prothrombin activator and a fibrinolytic enzyme to interfere with blood homeostasis as part of the mechanism associated with the pathogenicity of V. vulnificus in humans and thereby facilitate the development of systemic infection.Proteolytic enzymes play various physiological roles and are essential factors for homeostatic control in both eukaryotes and prokaryotes. However, the enzyme produced by pathogenic microorganisms, particularly by opportunistic pathogens, can also act as toxic factors to the host. Vibrio vulnificus is an opportunistic organism pathogenic to humans that causes wound infection and septicemia (2,10,38,40). Like other Vibrio strains, this pathogen secretes a 45-kDa zinc metalloprotease that has been reported to have many biological functions. It causes the degradation of a variety of host proteins and enhancement of vascular permeability through the generation of inflammatory mediators (21, 26, 28). The only physiological inhibitor of this protease is ␣ 2 -macroglobulin, which has been shown to inhibit the enzyme's activity toward casein and elastin as well as its permeability-enhancing and hemorrhagic activities, but the peptidase activity toward certain peptide substrate was not reduced (27). The protease has been purified from the culture supernatant of two V. vulnificus strains, ATCC 29307 (16) and L-180 (20). The gene encoding the protease in both strains has also been cloned (11,37), and the enzyme from L-180 has been expressed as an active form in Escherichia coli (24).Fibrinogen and fibrin play essential roles in blood clotting, cellular and matr...

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Identification of covalently linked trimeric and tetrameric D domains in crosslinked fibrin.

Cited by 83 publications

References 65 publications

The location of the carboxy-terminal region of γ chains in fibrinogen and fibrin D domains

The location of the carboxy-terminal region of γ chains in fibrinogen and fibrin D domains

The role of fibrinogen D domain intermolecular association sites in the polymerization of fibrin and fibrinogen Tokyo II (gamma 275 Arg-->Cys).

Vibrio vulnificus Secretes a Broad-Specificity Metalloprotease Capable of Interfering with Blood Homeostasis through Prothrombin Activation and Fibrinolysis

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