Evidence for new endothelial cell binding sites on fibrinogen.

In vitro assays were used to characterize adhesion of human aortic, microvascular and umbilical vein endothelial cells to various forms of immobilized fibrinogen. All three types of endothelial cells adhered to fibrinogen in a manner that was independent of the Aalpha-chain 572-574 RGD cell binding site. In fact, all three adhered to a fragment of the molecule which is composed of only one D domain (D1) of fibrinogen. A time course study revealed that extensive adhesion of endothelial cells on the ligand coated surface occurred between one and two hours incubation. The anti-fibrinogen gammaA-chain monoclonal antibody 4A5 as well as 4A5 Fabs, blocked adhesion of endothelial cells to fibrinogen, not vitronectin. The inhibitory effects of 4A5 seemed to be indirect because the endothelial cells adhered to the recombinant fibrinogen gamma407 (which lacks the gamma-chain AGDV sequence of the carboxyl terminal 4A5 binding site) as well as they did to normal recombinant fibrinogen. A recombinant fibrinogen lacking the gamma-chain AGDV sequence, containing RGE in place of RGD at the gamma-chain 572-574 and 95-97 positions, also supported endothelial cell adhesion. The anti-alphavbeta3 antibody, LM609, blocked adhesion of endothelial cells to fibrinogen. The peptide GRGDSP inhibited endothelial cell adhesion on fibrinogen and vitronectin. These results demonstrate that alphavbeta3 mediated adhesion (attachment and spreading) of HUVECs to fibrinogen may use a site in the D domain of fibrinogen and is not dependent on the Aalpha-chain RGD (95-97 and 572-574) sequences, as has been shown in shorter term (where cells were rounded) experiments, or the alphaA-chain 408-411 cell binding sites. Thus, the data reveal the existence of another unidentified site(s) on fibrinogen which can support the irreversible adhesion (attachment and spreading) of endothelial cells.

Synergistic adhesive interactions and signaling mechanisms operating between platelet glycoprotein Ib/IX and integrin alpha IIbbeta 3. Studies in human platelets ans transfected Chinese hamster ovary cells.

This study investigates three aspects of the adhesive interaction operating between platelet glycoprotein Ib/IX and integrin alpha(IIb)beta(3). These include the following: 1) examining the sufficiency of GPIb/IX and integrin alpha(IIb)beta(3) to mediate irreversible cell adhesion on immobilized von Willebrand factor (vWf) under flow; 2) the ability of the vWf-GPIb interaction to induce integrin alpha(IIb)beta(3) activation independent of endogenous platelet stimuli; and 3) the identification of key second messengers linking the vWf-GPIb/IX interaction to integrin alpha(IIb)beta(3) activation. By using Chinese hamster ovary cells transfected with GPIb/IX and integrin alpha(IIb)beta(3), we demonstrate that these receptors are both necessary and sufficient to mediate irreversible cell adhesion under flow, wherein GPIb/IX mediates cell tethering and rolling on immobilized vWf, and integrin alpha(IIb)beta(3) mediates cell arrest. Moreover, we demonstrate direct signaling between GPIb/IX and integrin alpha(IIb)beta(3). Studies on human platelets demonstrated that vWf binding to GPIb/IX is able to induce integrin alpha(IIb)beta(3) activation independent of endogenous platelet stimuli under both static and physiological flow conditions (150-1800 s(-)(1)). Analysis of the key second messengers linking the vWf-GPIb interaction to integrin alpha(IIb)beta(3) activation demonstrated that the first step in the activation process involves calcium release from internal stores, whereas transmembrane calcium influx is a secondary event potentiating integrin alpha(IIb)beta(3) activation.

Activation of integrin-beta3-associated syk in platelets.

Published data suggest that the tyrosine kinase syk participates in platelet signalling through the integrin alphaIIbbeta3. Our data show an association of syk and integrin beta3 in immunoprecipitates from unstimulated and stimulated platelets. We detected syk in anti-beta3 precipitates and, conversely, beta3 in anti-syk precipitates. In vitro kinase assays with anti-beta3 precipitates demonstrated that syk activity was enhanced in ADP-stimulated platelets.

Substitution of tyrosine for phenylalanine in fibrinopeptide A results in preferential thrombin cleavage of fibrinopeptide B from fibrinogen.

Phenylalanine at residue 8 in the Aalpha chain of fibrinogen is a highly conserved amino acid that is believed to be critical for binding and catalysis by the serine protease thrombin. We have examined the requirement for Phe at this position by constructing a variant recombinant fibrinogen with a conservative substitution of tyrosine for phenylalanine, Aalpha F8Y fibrinogen. We found that the variant fibrinopeptide A (F8Y 1-16) was cleaved by thrombin, in contrast to the lack of cleavage of an Aalpha 1-23 peptide and an Aalpha 1-50 fusion protein with the same substitution. This result indicates that fibrinogen residues other than Aalpha 1-50 participate in thrombin binding and fibrinogen proteolysis. We found, for the first time, that thrombin-catalyzed lysis of the fibrinogen Bbeta chain preceded lysis of the Aalpha chain, such that fibrinopeptide B (FpB) was released prior to F8Y 1-16. Kinetic analysis demonstrated that F8Y 1-16 was a very poor substrate for thrombin, with a specificity constant 280-fold lower than normal fibrinopeptide A. FpB was also a poor substrate, but the specificity constant for FpB was only 4-fold lower than normal. Consequently, FpB was preferentially released from Aalpha F8Y fibrinogen. This "role reversal" had a dramatic effect on polymerization, such that the rate of Aalpha F8Y fibrinogen polymerization was 13% of the rate of normal recombinant fibrinogen. These results confirm the importance of phenylalanine at Aalpha chain residue 8 for efficient thrombin-catalyzed proteolysis of fibrinogen, and further demonstrate that sequential fibrinopeptide release has an important role in normal polymerization.

The contribution of the three hypothesized integrin-binding sites in fibrinogen to platelet-mediated clot retraction.

Fibrinogen is a plasma protein that interacts with integrin alphaIIb beta3 to mediate a variety of platelet responses including adhesion, aggregation, and clot retraction. Three sites on fibrinogen have been hypothesized to be critical for these interactions: the Ala-Gly-Asp-Val (AGDV) sequence at the C-terminus of the gamma chain and two Arg-Gly-Asp (RGD) sequences in the Aalpha chain. Recent data showed that AGDV is critical for platelet adhesion and aggregation, but not retraction, suggesting that either one or both of the RGD sequences are involved in clot retraction. Here we provide evidence, using engineered recombinant fibrinogen, that no one of these sites is critical for clot retraction; fibrinogen lacking all three sites still sustains a relatively normal, albeit delayed, retraction response. Three fibrinogen variants with the following mutations were examined: a substitution of RGE for RGD at position Aalpha 95-97, a substitution of RGE for RGD at position Aalpha 572-574, and a triple substitution of RGE for RGD at both Aalpha positions and deletion of AGDV from the gamma chain. Retraction rates and final clot sizes after a 20-minute incubation were indistinguishable when comparing the Aalpha D97E fibrinogen or Aalpha D574E fibrinogen with normal recombinant fibrinogen. However, with the triple mutant fibrinogen, clot retraction was delayed compared with normal recombinant fibrinogen. Nevertheless, the final clot size measured after 20 minutes was the same size as a clot formed with normal recombinant fibrinogen. Similar results were observed using platelets isolated from an afibrinogenemic patient, eliminating the possibility that the retraction was dependent on secretion of plasma fibrinogen from platelet alpha-granules. These findings indicate that clot retraction is a two-step process, such that one or more of the three putative platelet binding sites are important for an initial step in clot retraction, but not for a subsequent step. With the triple mutant fibrinogen, the second step of clot retraction, possibly the development of clot tension, proceeds with a rate similar to that observed with normal recombinant fibrinogen. These results are consistent with a mechanism where a novel site on fibrin is involved in the second step of clot retraction.

Role of beta1 and beta3 integrins in human smooth muscle cell adhesion to and contraction of fibrin clots in vitro.

The degree of lumen narrowing in advanced lesions correlates poorly with the amount of intimal mass accumulated in the atherosclerotic plaque. As an alternate mechanism of stenosis, we propose that human smooth muscle cells bind to fibrin deposited in the matrix and exert contractile forces to cause a narrowing of the lumen. In the present study we demonstrated in vitro that human newborn aortic smooth muscle cell lines can contract and adhere to fibrin clots composed of either fibronectin-depleted plasma ("plasma") or recombinant fibrin. By using neutralizing antibodies and RGD peptides, we showed that members of the integrin family mediated the interaction between human newborn smooth muscle cells and fibrin. Neutralizing antibodies against the integrin alphavbeta3 (c7E3 Fab and LM609) did not inhibit either plasma clot contraction or recombinant fibrin clot contraction by human newborn smooth muscle cells. In contrast, antibodies against alpha5, beta1, and alpha5/beta1 inhibited contraction of clots composed of either plasma or recombinant fibrin. Anti-alphavbeta3, anti-alphav, anti-alpha5, anti-beta1, and anti-alpha5beta1 antibodies inhibited human newborn smooth muscle cell adhesion to plasma clots; however, only anti-alpha5, anti-beta1, and anti-alpha5beta1 antibodies significantly inhibited adhesion to recombinant fibrin. While the linear RGD peptides had no effect, the cyclic peptide penRGD inhibited adhesion to plasma clots and recombinant fibrin. However, it did not block contraction of recombinant fibrin clots. These results suggest that during the interaction of human newborn smooth muscle cell lines with fibrin, alpha5beta1 plays a significant role. This interaction is of potential interest as a target for efforts to block vascular contraction.

Role of the gamma chain Ala-Gly-Asp-Val and Aalpha chain Arg-Gly-Asp-Ser sites of fibrinogen in coaggregation of platelets and fibrinogen-coated beads.

Fibrinogen (Fg) mediates platelet aggregation and adhesion to artificial surfaces. The carboxyl terminus of the gamma chain of Fg (residues AGDV at gamma408-411) is known to play an exclusive role in platelet aggregation, while there is no known role for the consensus RGD sites in the Aalpha chain. In this study, we used flow cytometry to measure the coaggregation (CA) of platelets with Fg-coated beads, and investigated which domains in surface-immobilized Fg support platelet adhesion. CA of platelets with Fg-beads was nearly abolished in the presence of 4A5, a monoclonal antibody (mAb) whose epitope includes AGDV, while Z69/8, a mAb that also binds to the gamma chain carboxyl terminus but does not cover AGDV, had little effect. When beads were coated with recombinant Fg (rFg) lacking AGDV, CA was similarly abolished. In contrast, beads coated with Fg that lacked the RGDS site, supported platelet CA as did intact Fg. These results were confirmed in experiments that measured the binding of activated soluble glycoprotein IIb and IIIa (GPIIbIIIa), the platelet membrane glycoprotein complex known to be the Fg receptor, to immobilized Fg. This binding was inhibited by mAb 4A5, but not by mAb Z69/8. Binding was totally retained when beads were coated with Fg lacking RGDS, but was completely lost when beads were coated with Fg lacking AGDV. These results demonstrated that the AGDV sequence on the carboxyl terminus of the gamma chain of Fg plays an exclusive role in platelet adhesion to surface-immobilized Fg, while the carboxyl terminus of the Aalpha chain, including a consensus RGD site, is not required.

The role of putative fibrinogen Aalpha-, Bbeta-, and GammaA-chain integrin binding sites in endothelial cell-mediated clot retraction.

In this study, endothelial cell-mediated clot retraction was supported by fibrin generated from several purified fractions of plasma fibrinogen, purified proteolytic fragments of plasma fibrinogen, recombinant normal fibrinogen, and recombinant variant fibrinogen. These results were surprising because some of these fibrinogens lack domains that are known binding sites for the integrin receptors that support clot retraction. Specifically, fibrinogens lacking Aalpha-chain RGD residues at 572-574 or lacking the gamma-chain residues AGDV 408-411 supported endothelial cell-mediated clot retraction as well as intact fibrinogen. Thus, clot retraction mediated by endothelial cells is not dependent on either of these sites. A variety of monoclonal antibodies against the integrin alphavbeta3 partially inhibited the endothelial cell-mediated retraction of clots formed from plasma fibrinogen. As expected, an antibody to the platelet integrin alphaIIbbeta3 did not inhibit endothelial cell-mediated clot retraction. These results indicate that this retraction is mediated at least in part by alphavbeta3. These results support the conclusion that (a) neither of the two fibrinogen cell binding sites described above is required to support clot retraction or that (b) either site alone or in conjunction with other fibrin(ogen) region(s) can support clot retraction. Thus, endothelial cell-mediated clot retraction appears to be dependent on fibrinogen cell binding sites other than those required to support adhesion of resting platelets to immobilized fibrinogen and platelet aggregation.

Dissecting clot retraction and platelet aggregation. Clot retraction does not require an intact fibrinogen gamma chain C terminus.

Fibrinogen mediates the processes of platelet aggregation and clot retraction. Previous studies have demonstrated that fibrinogen binding to the platelet receptor alphaIIbbeta3 requires the C-terminal residues of the fibrinogen gamma chain. We made a recombinant human fibrinogen that lacks the gamma chain C-terminal four residues (AGDV). As expected this fibrinogen did not support platelet aggregation. Unexpectedly, this variant did support clot retraction that was indistinguishable from retraction with normal recombinant or plasma fibrinogen. These results suggest that the site on fibrinogen that is required for platelet aggregation differs from the site on fibrin that is required for clot retraction.

Binding of fibrinogen A alpha 1-50-beta-galactosidase fusion protein to thrombin stabilizes the slow form.

The interaction of fibrinogen A alpha1-50-beta-galactosidase fusion protein with the slow and fast forms of thrombin was studied and compared to thrombin-fibrinogen interaction under identical solution conditions. At equilibrium, the affinity of the fusion protein for the slow form of thrombin is 3 times higher than its affinity for the fast form. The fusion protein and fibrinogen have the same affinity for the fast form. On the other hand, the affinity of the fusion protein for the slow form of thrombin is 40 times tighter than that of fibrinogen. In the transition state, binding of the fusion protein has the same properties as fibrinogen, with the fast form showing higher specificity. The N-terminal fragment of the fibrinogen A alpha chain thus contains residues that are responsible for the preferential binding of the fusion protein to the slow form at equilibrium and to the fast form in the transition state. If this fragment binds to thrombin in a similar way for fibrinogen and the fusion protein, then the N-terminal domains of the B beta and gamma chains of fibrinogen, that are not present in the fusion protein, must play a key role in the binding of fibrinogen to thrombin at equilibrium. These chains may destabilize binding to the slow form by nearly 2.4 kcal/mol, thereby favoring binding of fibrinogen to the fast form. We propose that the three chains of fibrinogen play different roles in the thrombin-fibrinogen interaction, with the A alpha chain containing residues for preferential binding to the fast form in the transition state and the B beta and gamma chains containing residues that destabilize binding to the slow form at equilibrium.