Michael W. Mosesson

Disintegration and reorganization of fibrin networks during tissue-type plasminogen activator-induced clot lysis.

In this study, we investigated tissue-type plasminogen activator (tPA)-induced lysis of glutamic acid (glu)-plasminogen-containing or lysine (lys)-plasminogen-containing thrombin-induced fibrin clots. We measured clot development and plasmin-mediated clot disintegration by thromboelastography, and used scanning electron microscopy (SEM) to document the structural changes taking place during clot formation and lysis. These events occurred in three overlapping stages, which were initiated by the addition of thrombin, resulting first in fibrin polymerization and clot network organization (Stage I). Autolytic plasmin cleavage of glu-plasminogen at lys-77 generates lys-plasminogen, exposing lysine binding sites in its kringle domains. The presence of lys-plasminogen within the thrombin-induced fibrin clot enhanced network reorganization to form thicker fibers as well as globular complexes containing fibrin and lys-plasminogen having a greater level of turbidity and a higher elastic modulus (G) than occurred with thrombin alone. Lys-plasminogen or glu-plasminogen that had been incorporated into the fibrin clot was activated to plasmin by tPA admixed with the thrombin, and led directly to clot disintegration (Stage II) concomitant with fibrin network reorganization. The onset of Stage III (clot dissolution) was signaled by a sustained secondary rise in turbidity that was due to the combined effects of lys-plasminogen presence or its conversion from glu-plasminogen, plus clot network reorganization. SEM images documented dynamic structural changes in the lysing fibrin network and showed that the secondary turbidity rise was due to extensive reorganization of severed fibrils and fibers to form wide, occasionally branched fibers. These degraded structures contributed little, if anything, to the structural integrity of the residual clot, and eventually collapsed completely during the course of progressive clot dissolution. These results provide new perspectives on the major structural events that occur in the fibrin clot matrix during fibrinolysis.

Studies of fibronectin synthesized by cultured chick hepatocytes

We have adapted a chick embryo liver cell system for studying the synthesis of proteins secreted by hepatocytes. In primary liver cell cultures maintained for several days in arginine-deficient medium containing ornithine (0.7 mM) and carbamyl phosphate (1 mM), only hepatocytes demonstrated normal morphological and biosynthetic characteristics, indicating that they possessed a functional ornithine cycle as a source of arginine production. Non-parenchymal liver cells, such as fibroblasts, which lack the ornithine cycle were excluded. Hepatocytes in arginine-deficient or arginine-containing medium synthesized fibronectin (Fn) over several days at a constant rate of 3 micrograms +/- 1 microgram/mg cell protein per day, with fibronectin representing approximately 3% of the total secreted hepatocyte proteins during any culture period after the first 24 h. Pulse-chase experiments indicated that Fn synthesis and secretion was relatively rapid (t1/2 = 45 min) and represented approximately 95% of the intracellularly labelled Fn. This Fn is secreted predominantly as a 450 kD dimer with a subunit size that is indistinguishable from the plasma form as assessed by one-dimensional electrophoretic analysis. Continuous exposure of hepatocytes to insulin caused a moderate decrease (26%) in Fn synthesis, whereas there was no effect of short-term exposure. In contrast, dexamethasone stimulated Fn production 2-3-fold, consistent with its known ability to stimulate hepatocyte production of acute phase proteins. Under these conditions, electrophoretic analyses showed that an increased quantity of intact hepatocyte Fn was produced having the same molecular size of plasma Fn.

Cleavage of fibrinogen by human platelet calcium-activated protease

In lysates of washed human platelets produced by sonication or by addition of nonionic detergent, fibrinogen (Mr 340,000) was rapidly degraded, under conditions favorable to activation of the endogenous calcium-activated protease (CAP), to a core derivative (Mr 280-290,000) composed of partially degraded A alpha chains (Mr 47,000, 46,000, and 34,000) and B beta chains (Mr 56,000), and apparently intact gamma chains (Mr 53-54,000). Extensive degradation occurred within one minute at 4 degrees C, ambient temperature or at 37 degrees C, and was inhibited by leupeptin, EDTA, EGTA, or N-Ethylmaleimide, but not by soybean trypsin inhibitor, hirudin, aprotonin, benzamidine, phenylmethylsulfonyl fluoride or epsilon-aminocaproic acid. Purified plasma fibrinogen exposed to lysates containing active protease was cleaved in an identical fashion. The cleavage pattern of A alpha chains produced by this platelet protease activity is different from that produced by plasmin in vitro or that found in fibrinogen catabolites in vivo, and is unlike that produced by any cellular fibrinolytic enzyme yet described. In view of this finding, as well as the striking differential inhibitory effect of the agents cited above, we conclude that the degradation of platelet fibrinogen observed in these studies is due to direct proteolysis by platelet CAP.

Separation and analysis of the major forms of plasma fibronectin

Human plasma fibronectin exists in circulation in multiple molecular forms that are distinguishable by SDS-polyacrylamide gel electrophoresis (zone I, approx. 450 kDa dimers; zone II, 190-235 kDa; Zone III, 146-175 kDa). (Chen, A.B., Amrani, D.L. and Mosesson, M.W. (1977) Biochim. Biophys. Acta 493, 310-322). We report here on investigations of plasma fibronectin that had been purified from the heparin-precipitable fraction of plasma by DEAE-cellulose chromatography using buffers containing a chaotropic salt (KSCN). Zone I fibronectin and zone II fibronectin were subsequently separated by Sepharose CL-6B chromatography in the presence of 0.3 M KSCN. Electrophoresis of reduced zone I fibronectin dimers showed the presence of three types of subunits (i.e., 220 kDa, 215 kDa, 207 kDa), evidently all having the same NH2-terminal sequence. Subunits of this size were also found in reduced zone II fibronectin, as well as another polypeptide of 190 kDa, the latter amounting to under 5% of the total. Unreduced zone I fibronectin was resolved by gel electrophoresis into a doublet. The upper component amounted to approx. 90% of the total and was comprised of 220 kDa and/or 215 kDa subunits; the lower component contained 207 kDa plus a 220 kDa or 215 kDa subunit. Scanning transmission electron microscopy indicated that under physiologic conditions zone II fibronectin molecules, like those in zone I, exist as pleiomorphic, loosely folded structures (approx. 16 X 8-12 nm) that are somewhat smaller than dimeric zone I molecules (approx. 24 X 16 nm). Circular dichroic spectral analyses suggests that both types have similarly folded local domains. Affinity chromatography experiments revealed a relative decrease in the binding of zone II fibronectin to gelatin but no difference from zone I fibronectin with respect to heparin or fibrin binding.

Preparation of functionally intact monomers by limited disulfide reduction of human plasma fibronectin dimers

Most (90 to 95%) human plasma fibronectin (PFn) molecules exist as 450-kDa disulfide-rich dimers comprised of two major types of subunits (A, 220 kDa; B, 215 kDa) that are joined near the COOH terminus by two disulfide bonds. Smaller PFn species (Zone II; 190-235 kDa) consist mainly of monomers and/or a monomeric subunit joined covalently to a smaller peptide remnant presumably derived by proteolysis of a parent 450-kDa molecule. A relatively simple and selective method for preparing functionally active, partially reduced monomeric fibronectin subunits (PR-PFn) by limited and selective reduction of dimeric plasma fibronectin (PFn) has been developed. PR-PFn was prepared by incubating PFn in phosphate-buffered saline, pH 7.4, for 2 h at room temperature in the presence of 17 mM dithiothreitol (DTT). Following S-carboxymethylation or S-carboxyamidomethylation, the material was passed through a gelatin-Sepharose column and nonbinding material was discarded; gelatin-bound material was eluted using a 0 to 2 M KSCN gradient. Residual dimeric species (10-20%) could be separated from monomers in high yield by gel-sieving chromatography on a Sepharose 6B-Cl in the presence of a chaotropic salt, 0.3 M KSCN. Most new SH groups (74-81%) in that fraction of PR-PFn binding to gelatin were localized in proteolytic fragments containing the COOH terminus, thus suggesting that selective cleavage of the interchain disulfide bridges had taken place. The binding affinity of PR-PFn to gelatin- and fibrin-Sepharose was lower than that of dimeric PFn, but the same as that of Zone II PFn and other monomeric gelatin-binding proteolytic derivatives. PR-PFn also bound to heparin-Sepharose and promoted cell attachment and spreading. We conclude that PR-PFn monomers possess the same functional activities as those of the parent chains.

Near ultraviolet circular dichroism spectroscopy of plasma fibronectin and fibronectin fragments.

Abstract Comparison of the near uv CD spectrum of human plasma fibronectin with the spectra of the three major leukocyte elastase fragments 25 Kd, 60 Kd and 140 160 shows that the aromatic residues of these fragments are in different environments. In particular, the ellipticity bands associated with tryptophan in the 290–300 nm region differ for each fragment. The results also show that intrachain disulfide bridges are important in stabilizing regions of the fibronectin molecule against the structure-disrupting effects of 8M urea.

Amino acid sequences of the carboxyl-terminal regions of rat plasma fibrinogen γA and γ′ chains

Abstract Amino acid sequence analysis of human fibrinogen γ′ chains have shown that the larger size relative to the γ A chains is due to differences at the COOH-terminus. As shown by DNA sequencing, these differences as well as those in rat fibrinogen γ′ and γ A chains result from differential processing of the primary mRNA transcript. We isolated and sequenced carboxyl-terminal CNBr peptides from γ′ and γ A chains. As predicted by DNA sequencing, the γ A peptide has the carboxyl-terminal sequence Gl 1 y-Gl 2 y-Se 3 r-Ly 4 s, Gl 5 n-Va 6 l-Gl 7 y-As 8 p-Me 9 t-COOH. The y peptide is identical through residue 6 and terminates with Se 7 r-Va 8 l-Gl 9 u-Hi 10 s-Gl 11 u-Va 12 l-As 13 p-Va 14 l-Gl 15 u-Ty 16 r-Pr 17 o-COOH.

The dimeric Aα chain composition of dysfibrinogenemic molecules with mutations at Aα 16

Abstract In the last stage of fibrinogen synthesis, two Aα-Bβ-γ half-molecules are disulfide linked in their N-terminal regions to form a dimeric fibrinogen molecule. It is not known whether intracellular hepatocyte assembly of fibrinogen half-molecules occurs randomly or is a directed process. One analysis based on partitioning of coagulable components of fibrinogen from a heterozygous dysfibrinogenemic subject having a mutation at the thrombin cleavage site (Fibrinogen Louisville, Aα16 R→H), suggested that only homodimeric molecules containing two normal fibrinopeptides A (FPA, FPA) or two abnormal fibrinopeptides A (FPA ★ , FPA ★ ) were present in plasma, implying that fibrinogen dimer assembly is directed. The same type of analyses on Fibrinogen Birmingham (Aα16 R→H) indicated that there were heterodimers as well as homodimers, suggesting that fibrinogen dimer assembly is random. To examine this question more directly, the composition of fibrinogen molecules from seven dysfibrinogenemic families with either R→C (four) or R→H (three) Aα16 mutations was determined. Following treatment with Atroxin to release normal FPA from fibrinogen, N-terminal disulfide knot (‘N-DSK’) cleavage fragments were prepared and subsequently separated by SDS-PAGE to resolve ‘N-DSK’ components with two FPA ★ s (N-DSK homodimer), one FPA ★ (des A N-DSK heterodimer), or no FPAs (des AA N-DSK homodimer). Fibrinogen from subjects whose molecules contained both normal and abnormal Aα chains, yielded a heterodimeric des A N-DSK derivative, as well as smaller amounts of homodimeric N-DSK and des AA N-DSK. These results indicate that when both types of Aα chain are produced, both Aα chain alleles are expressed and the resulting fibrinogen dimers are assembled randomly.

The cleavage sequence of fibrinopeptide A from fibrinogen fragment E by thrombin, atroxin or batroxobin.

Calculations of data from fibrin polymerization and cross-linking experiments infer that thrombin-catalysed release of the second of the two fibrinopeptides A (FpA2) from fibrinogen is concerted, although other data suggest that FpA2 release is random. In the concerted pattern of FpA release, divalent monomer (des AA-fibrin) formation predominates throughout the enzymatic conversion of fibrinogen to fibrin, an effect leading to relatively rapid fibril assembly. Alternatively, random FpA2 release would result in a substantial population of monovalent monomer (des A-fibrin) intermediates during early and intermediate phases of the enzymatic conversion to fibrin. Their formation would cause a delay in fibrin fibril assembly. In order to address the question of the pattern of FpA release directly, we purified plasmic fibrinogen fragment E1 isoforms containing both FpA sequences and studied the sequence of FpA release by thrombin or batroxobin. Des A-fragment E1 intermediates formed by loss of one FpA (FpA1), and des AA-fragment E1 products (lacking both FpA1 and FpA2) were identified by analytical isoelectric focusing and quantified by densitometry. The catalytic rate of release of FpA1 (k1) and FpA2 (k2) by thrombin or batroxobin was similar. The ratio of these rates, k2:k1, was 1.10 +/- 0.42 for thrombin and 1.34 +/- 0.26 for batroxobin. These findings indicate that these enzymes cleave FpA2 randomly from fragment E1.

Evidence that rat platelet fibrinogen molecules lack the γ chain variant found in plasma fibrinogen molecules

Heterogeneity of rat plasma fibrinogen gamma chains (gamma A, gamma) is due to differential splicing of the primary mRNA transcript. Human gamma chains, which amount to 7% of the total gamma chain population of plasma (hepatic) fibrinogen, are not detectable in fibrinogen isolated from platelets. In this investigation, we extended our studies to rats and found that gamma chains, representing 30% of the rat plasma gamma chain population, are not detectable in their platelet fibrinogen.