Specific binding of blood coagulation factor XIIIa to thrombin-stimulated platelets

We studied the binding of 125I-platelet and plasma Factor XIII (125I-Factor XIII) to human platelets. When 125I-Factor XIII was incubated with gel-filtered platelets, calcium chloride (5 mM) and thrombin (1 unit/ml) at 37 degrees C, saturable binding was observed. Half-maximal binding occurred at 1 min. Binding was inhibited 93% by a 100-fold molar excess of unlabeled ligand but not by other purified proteins. Greater than 87% of platelet-bound radioactivity migrated as thrombin-cleaved a-chains (a'-chains) in sodium dodecyl sulfate-polyacrylamide gels indicating that Factor XIIIa but not Factor XIII binds to platelets. 125I-Factor XIIIa does not bind to unstimulated platelets. When platelet secretion was blocked, binding was markedly inhibited. 125I-Factor XIIIa bound minimally to platelets stimulated with agonists other than thrombin. Thus, binding is dependent on platelet activation, as well as modification of platelets by thrombin. 125I-Factor XIIIa bound to gamma-thrombin-stimulated platelets, at concentrations which did not clot fibrinogen. Therefore, Factor XIIIa is not bound to fibrin associated with platelets. Binding was only partially reversible. Approximately 12,000 molecules of Factor XIIIa were bound per platelet. 125I-Factor XIIIa bound normally to platelets from patients with severe Glanzmann's thrombasthenia indicating that 125I-Factor XIIIa does not bind to platelet glycoproteins IIb or IIIa, or platelet-bound fibrinogen. Chymotrypsin treatment of platelets inhibited 125I-Factor XIIIa binding by 78% without inhibiting secretion. Methylamine and putrescine, Factor XIIIa substrates, and N-ethylmaleimide, an active site inhibitor, did not inhibit binding. Factor XIIIa bound to platelets was enzymatically active and catalyzed [3H]putrescine incorporation into platelet proteins. The specific binding of Factor XIIIa to platelets suggests it may play a role in physiologic reactions involving platelets.     

The binding sites on fibrin(ogen) for guinea pig liver transglutaminase are similar to those of blood coagulation factor XIII. Characterization of the binding of liver transglutaminase to fibrin

The present study represents detailed investigations into the nature of interactions between an intracellular "tissue" transglutaminase and a plasma protein, fibrinogen. We demonstrate a specific, saturable, and reversible binding of transglutaminase to fibrin(ogen). The binding was time- and temperature-dependent, was independent of divalent metal ions, did not require the release of either fibrinopeptide A or B, and was partially inhibited by the presence of sodium chloride or plasma proteins, properties similar to Factor XIII binding to fibrin(ogen). Both Factor XIII and liver transglutaminase also shared similar binding sites on fibrinogen, the A alpha- and the B beta-chains. The binding characteristics of liver transglutaminase were thus similar to Factor XIII binding to fibrin, but there were also important differences. Scatchard analyses of the binding data indicated that the affinity of liver transglutaminase (Kd = 4.17 x 10(-7) M) was at least 40-fold weaker compared with the affinity of Factor XIII to fibrinogen. Consequently, a 20-fold molar excess of Factor XIII a-chains specifically and completely inhibited the binding of liver transglutaminase to des-A-fibrinogen. The association between liver transglutaminase and fibrin(ogen) was also critically controlled by the conformational states of the two proteins. Substances capable of altering the conformation of either transglutaminase (such as guanosine 5'-triphosphate) or of fibrinogen (such as the tetrapeptide Gly-Pro-Arg-Pro and Fragment D) disrupted binding. Excess CaCl2 was able to counteract the effects of guanosine 5'-triphosphate on transglutaminase binding to fibrin. In contrast, Factor XIII binding to fibrin was unaffected by either guanosine 5'-triphosphate, CaCl2, or Gly-Pro-Arg-Pro, suggesting a more stable association between the two proteins. The physiologic implications of transglutaminase-fibrin(ogen) interactions are discussed.     

Characterization of the fibrin polymer structure that accelerates thrombin cleavage of plasma factor XIII

The effect of plasmin-derived fibrin(ogen) degradation products on alpha-thrombin cleavage of plasma Factor XIII was studied to identify the fibrin polymer structure that promotes Factor XIIIa formation. Fibrin polymers derived from fibrinogen and Fragment X enhanced the rate of thrombin cleavage of plasma Factor XIII in plasma or buffered solutions. The concentrations of fibrinogen and Fragment X that promoted half-maximal rates of Factor XIIIa formation were 5 and 40 micrograms/ml, respectively. Fragments Y, D, E, D-dimer, and photooxidized fibrinogen did not enhance thrombin cleavage of Factor XIII. Although purified Fragment D1 inhibited fibrin gelation, the soluble protofibrils promoted thrombin activation of Factor XIII. Noncrosslinked fibrin fibers failed to enhance thrombin cleavage of Factor XIII. In conclusion, soluble fibrin oligomers function to promote thrombin cleavage of plasma Factor XIII during blood clotting.     

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.     

Binding and degradation of blood coagulation factor XIII by cultured fibroblasts

The interaction of Factor XIII with cultured fibroblasts was examined using 125I-labeled protein and immunofluorescence. Platelet or plasma Factor XIII bound to confluent cell layers. Binding reached an apparent steady state after 8 h. Activation with thrombin increased the binding of both the platelet and plasma forms of the enzyme. After a 1-2 h lag, a chloroquine-inhibitable increase in trichloroacetic acid-soluble radioactivity was detected in the medium. Gel electrophoresis in sodium dodecyl sulfate indicated that approximately 16-fold more a subunit (catalytic) of 125I-plasma Factor XIII bound to the cell layer than b subunit (carrier) and that some large complexes containing Factor XIII were formed with the cell layer. Factor XIII binding increased linearly with concentrations of Factor XIII up to 230 micrograms/ml, whereas a component of the degradation of Factor XIII was saturable at about 20 micrograms/ml. Factor XIII associated with cell layers was catalytically active since it could cross-link fibronectin. By immunofluorescence the a subunit of Factor XIII was localized to fibronectin-containing extracellular fibrils and, in the presence of chloroquine, to intracellular granules. These results indicate that the a subunit of Factor XIII binds to the fibroblast extracellular matrix and matrix assembly sites, where it remains active, and to a putative cell-surface receptor which mediates its internalization and degradation.     

Thrombospondin interaction with fibrinogen. Evidence for binding to the A alpha- and B beta-chains of fibrinogen

Platelet thrombospondin interacts with fibrinogen in a specific and saturable manner. Thrombospondin was found to specifically bind to the A alpha- and B beta-chains of fibrinogen; binding was independent of divalent ions. Binding could be blocked either by preincubation of thrombospondin with 9.4 microM fibrinogen or by preincubation of fibrinogen with 1.1 nM thrombospondin. Thrombospondin bound only to the beta-chain component of the D and DD plasmin fragment of fibrinogen. Thrombospondin interaction with fibrinogen was not blocked by preincubation with synthetic peptides which have previously been identified as either the fibrinogen receptor (alpha 572-575, the synthetic tetrapeptide arginyl-glycyl-aspartyl-serine) or cell attachment (gamma 400-411) domains. Fibrinogen, therefore, possesses at least two unique and distinct sites, within the A alpha- and B beta-chains, for its interaction with thrombospondin.     

Binding of staphylococcal cell surface polysaccharide to human fibrinogen

The interaction between the binding site of a polysaccharide (called compact colony forming active substance (CCFAS)), obtained from the cell surface of a strain of Staphylococcus, and human fibrinogen (HF) was investigated. The CCFAS was found to bind specifically to both the B beta and gamma chains of HF at pH 7.0 and 8.0, and the A alpha chain at pH 5.0. The binding of CCFAS with fibrinogen fragments obtained by digestion with plasmin were also investigated. Fragments with Mr of 55,000, 24,000, and 19,000 were the major bands precipitated by CCFAS at pH 7.0 and 8.0. Fragments with Mr of 85,000 and 75,000 bound to CCFAS at pH 5.0. Binding of CCFAS (7 micrograms) with fibrinogen could be inhibited by 1.2 micrograms of B beta chain and 1.5 micrograms gamma chain at alkaline pH or 6.2 micrograms of the A alpha chain at pH 5.0. CCFAS was, therefore, assumed to be specifically bonded with HF molecules, in the alkaline range at least, resulting in compact colony forming activity in serum soft agar and paracoagulation.     

Tb(III)-ion-binding-induced conformational changes in platelet factor XIII.

Ca(II) ions are crucial during proteolytic conversion of Factor XIII zymogen into the active enzyme Factor XIIIa. Factor XIII proteolyzed by thrombin or trypsin in the presence of 5 mM-EDTA resulted in rapid inactivation of transglutaminase activity. Factor XIIIa formed by thrombin or trypsin in the presence of 40 microM-Tb(III) ions, however, was indistinguishable from Factor XIIIa formed in the presence of 2-5 mM-Ca(II) ions with respect to molecular mass and transglutaminase activity. Thrombin treatment of Factor XIII in the presence of 1-5 microM-Tb(III) ions resulted in three fragments (76 kDa, 51 kDa and 19 kDa) with simultaneous loss of transglutaminase activity. Tb(III) ions at concentrations greater than 40 microM made platelet Factor XIII resistant to proteolysis by either thrombin or trypsin. Other lanthanide(III) ions [Ln(III) ions] tested [Ce(III), La(III) and Gd(III) ions] functioned similarly to Tb(III) ions during proteolytic activation of Factor XIII. Ln(III) ions (10-100 microM) were unable to replace the Ca(II) ions required for transglutaminase activity of Factor XIIIa. Tb(III) ions also inhibited in a non-competitive manner the transglutaminase activity of Factor XIIIa (Ki 71 microM) even when measured in the presence of 200-fold molar excess of Ca(II) ions. Factor XIII selectively bound to a Tb(III)-chelate affinity column, and could not be eluted by 100 mM-CaCl2. Binding of Tb(III) ions to Factor XIII was demonstrated by fluorescence emission due to Forster energy transfer. A 10(4)-fold molar excess of CaCl2, but not NaCl, partially quenched Tb(III) fluorescence. Low concentrations (5-20 microM) of Tb(III) ions also inhibited the binding of Factor XIII to des-A-fibrinogen by about 43%, whereas higher concentrations (40-100 microM) promoted binding. Conformational changes in Factor XIII consequent to the binding of Tb(III) ions could be responsible for the observed effects on protein structure and function.     

Complex formation of platelet membrane glycoproteins IIb and IIIa with the fibrinogen D domain

Glycoprotein IIb (GPIIb) and glycoprotein IIIa (GPIIIa) form a macromolecular complex on the activated platelet surface which contains the fibrinogen-binding site necessary for normal platelet aggregation. To identify the specific region of the fibrinogen molecule responsible for its interaction with the GPIIb-GPIIIa complex, purified fragment D1 (Mr = 100,000) and fragment E (Mr = 50,000) were prepared from plasmin digests of purified human fibrinogen. In addition, the polypeptide chain subunits A alpha, B beta, and gamma of fibrinogen were prepared. Using an enzyme-linked immunosorbent assay we have demonstrated that isolated fragment D1 in a solid phase system forms a complex with a mixture of GPIIb and GPIIIa. The binding of the GPIIb-GPIIIa mixture to fragment D1-coated plates reached saturation at 8 nM and to fibrinogen-coated plates at 24 nM. Isolated A alpha, B beta, and gamma chains were not reactive with added glycoproteins. Fragment E coated directly on plastic plates or immobilized on antibody-coated plastic plates did not form a complex with GPIIb-GPIIIa. Only fluid phase fibrinogen and fragment D1 but not fragment E were inhibitory toward formation of a complex between solid phase fibrinogen and GPIIb-GPIIIa. Isolated A alpha, B beta, and gamma chains at concentrations equivalent to fluid phase fibrinogen were inactive. Binding of fragment D1 but not fragment E to the GPIIb-GPIIIa complex was also demonstrated by rocket immunoelectrophoresis of the membrane glycoprotein mixture through a gel containing the individual fragments and subsequent autoradiography of the complex following exposure to 125I-anti-fibrinogen. These observations with isolated platelet membrane glycoproteins provide strong evidence that each of the D domains of the fibrinogen molecule interacts directly with the GPIIb-GPIIIa complex on the activated platelet surface, thus allowing formation of a tertiary molecular "bridge" across the surface of two adjacent activated platelets.     

The binding of 35S-labeled recombinant factor VIII to activated and unactivated human platelets

Recombinant-derived human Factor VIII was labeled intrinsically with [35S]methionine, and its binding to washed human platelets was studied. Binding measurements were performed by incubating Factor VIII and platelets for 15 min at room temperature in Tyrode's solution supplemented with Ca2+ (5.0 mM), 4-(2-hydroxyethyl)-1-piperazineethanesulfonic acid (5.0 mM), 0.50% bovine serum albumin, and the Factor Xa and thrombin inhibitors 5-dimethylaminonaphthalene-1-sulfonylglutamylglycinylarginyl chloromethyl ketone and 5-dimethylaminonaphthalene-1-sulfonyl-arginine-N-(3-ethyl-1, 5-pentanediyl)amide. Separation of free from bound Factor VIII was accomplished by centrifugation through oil, and nonspecific binding was determined with excess unlabeled Factor VIII. Binding was saturable, reversible, and stimulated 20-fold after platelet activation with thrombin. Furthermore, binding was specific in that bound labeled Factor VIII could be displaced by excess unlabeled Factor VIII, but not by Factor V. Scatchard analysis indicated a single class of binding sites with Kd = 2.9 nM and 450 sites/activated platelet. The time course of displacement indicated a t1/2 of bound Factor VIII of approximately 5 min. When platelets were incubated in Ca2+, both the heavy and light chains of Factor VIII were bound, whereas exposure to EDTA resulted in the binding of the light chain only. These results demonstrate the specific reversible binding of Factor VIII to human platelets, likely mediated through the light chain.     

Assembly and secretion of fibrinogen. Degradation of individual chains.

Hep G2 cells produce surplus A alpha and gamma fibrinogen chains. These excess chains, which are not secreted, exist primarily as free gamma chains and as an A alpha-gamma complex. We have determined the intracellular location and the degradative fate of these polypeptides by treatment with endoglycosidase-H and by inhibiting lysosomal enzyme activity, using NH4Cl, chloroquine, and leupeptin. Free gamma chain and the gamma component of A alpha-gamma are both cleaved by endoglycosidase-H, indicating that the gamma chains accumulate in a pre-Golgi compartment. Lysosomal enzyme inhibitors did not affect the disappearance of free gamma chains but inhibited A alpha-gamma by 50%, suggesting that A alpha-gamma is degraded in lysosomes. The degradative fate of individual chains was determined in transfected COS cells which express but do not secrete single chains. Leupeptin did not affect B beta chain degradation, had very little affect on gamma chain, but markedly inhibited A alpha chain degradation. Antibody to immunoglobulin heavy chain-binding protein (GRP 78) co-immunoprecipitated B beta but not A alpha or gamma chains. Preferential binding of heavy chain-binding protein to B beta was also noted in Hep G2 cells and in chicken hepatocytes. Taken together these studies indicate that B beta and gamma chains are degraded in the endoplasmic reticulum, but only B beta is bound to BiP. By contrast A alpha chains and the A alpha-gamma complex undergo lysosomal degradation.     

Anti-idiotypic antibodies against an antibody to the platelet glycoprotein (GP) IIb-IIIa complex mimic GP IIb-IIIa by recognizing fibrinogen.

Binding of the adhesive ligand fibrinogen and the monoclonal antibody PAC1 to platelet glycoprotein (GP) IIb-IIIa is dependent on cell activation and inhibited by Arg-Gly-Asp (RGD)-containing peptides. Previously, we identified a sequence in a hypervariable region of PAC1 (mu-CDR3) that mimics the activity of the antibody. Here we examine whether monoclonal antibodies to this idiotypic determinant in PAC1 can mimic GP IIb-IIIa by binding to fibrinogen. Mice were immunized with a peptide derived from the mu-CDR3 of PAC1. Four antibodies were obtained that recognized fibrinogen as well as a recombinant form of the variable region of PAC1. However, they did not bind to other RGD-containing proteins, including von Willebrand factor, fibronectin, and vitronectin. Several studies suggested that these anti-PAC1 peptide antibodies were specific for GP IIb-IIIa recognition sites in fibrinogen. Three such sites have been proposed: two RGD-containing regions in the A alpha chain, and the COOH terminus of the gamma chain (gamma 400-411). Two of the antibodies inhibited fibrinogen binding to activated platelets, and all four antibodies bound to the fibrinogen A alpha chain on immunoblots. Antibody binding to immobilized fibrinogen was partially inhibited by monoclonal antibodies specific for the two A alpha chain RGD regions. However, the anti-PAC1 peptide antibodies also bound to plasmin-derived fibrinogen fragments X and D100, which contain gamma 400-411 but lack one or both A alpha RGD regions. This binding was inhibited by an antibody specific for gamma 400-411. When fragment D100 was converted to D80, which lacks gamma 400-411, antibody binding was reduced significantly (p less than 0.01). Electron microscopy of fibrinogen-antibody complexes confirmed that each antibody could bind to sites on the A alpha and gamma chains. These studies demonstrate that certain anti-PAC1 peptide antibodies mimic GP IIb-IIIa by binding to platelet recognition sites in fibrinogen. Furthermore, they suggest that the gamma 400-411 region of fibrinogen may exist in a conformation similar to that of an A alpha RGD region of the molecule.     

Regulation of fibrinogen assembly. Transfection of Hep G2 cells with B beta cDNA specifically enhances synthesis of the three component chains of fibrinogen

Previous studies indicated that synthesis of B beta chain may be a rate-limiting factor in the production of human fibrinogen since Hep G2 cells contain surplus pools of A alpha and gamma but not of B beta chains, and fibrinogen assembly commences by the addition of preformed A alpha and gamma chains to nascent B beta chains attached to polysomes. To test whether B beta chain synthesis is rate limiting Hep G2 cells were transfected with B beta cDNA, and its effect on fibrinogen synthesis and secretion was measured. Two sets of stable B beta cDNA-transfected Hep G2 cells were prepared, and both cell lines synthesized 3-fold more B beta chains than control cells. The B beta-transfected cells also synthesized and secreted increased amounts of fibrinogen. Transfection with B beta cDNA not only increased the synthesis of B beta chain but also increased the rate of synthesis of the other two component chains of fibrinogen and maintained surplus intracellular pools of A alpha and gamma chains. Transfection with B beta cDNA did not affect the synthesis of albumin, transferrin, or anti-chymotrypsin and had a small inhibitory effect on the synthesis of C-reactive protein. Taken together these studies demonstrate that increased B beta chain synthesis specifically causes increased production of the other two component chains of fibrinogen and that unequal and surplus amounts of A alpha and gamma chains are maintained intracellularly.     

Is spectrin a calmodulin-binding protein?

The binding of calmodulin to spectrin from human erythrocytes has been studied by affinity chromatography on sepharose-calmodulin column. The alpha and beta spectrin chains, dissociated in 6-7 M urea, both bound to the sepharose-calmodulin column, but with different affinities. Both chains were eluted together by EGTA. Binding sites for calmodulin are, therefore, present in both alpha and beta chains. However, intact purified spectrin dimers did not bind to the sepharose-calmodulin column, which renders a physiological role of calmodulin-binding to spectrin rather unlikely.     

ATP-sensitive potassium channels are altered in ventricular myocytes from diabetic rats

The affinities of Factor XIII (FXIII), Factor XIIIa (FXIIla), and cellular transglutaminase (Tg) for fibrinogen (Fgn), fibrin (Fbn), and fibronectin (Fn) were compared using a solid-phase binding assay. Initial rates of binding were as follows: FXIII bound Fbn 3-fold more than Fgn. FXIII did not bind Fn till 20 min. Increasing the ligands concentrations and binding time, resulted in weak binding of FXIII to Fn. FXIIla bound Fbn 2-fold more than Fgn and 28-fold more than Fn. Tg bound Fn 130-fold more than either Fgn or Fbn. At equilibrium, the extent of binding was determined to be as follows: FXIII bound Fbn 3–15-fold more than Fgn and 8-fold more than Fn. FXIIIa bound Fgn and Fbn equally and 12–25-fold more than Fn. FXIIla bound Fgn or Fbn 2-fold and 25-fold greater than FXIII-Fbn and FXIII-Fgn interactions, respectively. Tg bound about equally to Fgn and Fbn and 10–20-fold less than Fn. The K _d s for FXIIla binding to Fn, Fgn, and Fbn were 100, 23, and 19 nM, respectively. The K _d for Tg binding to Fn was 6.5 nM. The binding hierarchies are: [Tg-Fn]>[FXIIIa-Fgn]=[FXIIIa-Fbn]>[FXIII-Fbn]>[FXIIIFgn]=[FXIIIa-Fn]>[Tg-Fbn]=[Tg-Fgn]>[FXIII-Fn]. Such hierarchies could regulate the cross-linkings by FXIIIa and Tg during hemostasis, wound healing, and cell adhesion.Abbreviations Tg cellular transglutaminase - FXIII coagulation factor XIII - FXIIla factor XIIIa (thrombin-activated FXIII) - Fgn human plasma fibrinogen - Fn human plasma fibronectin - Fbn human plasma fibrin (thrombin-cleaved fibrinogen) - ECM extracellular matrix     

Folding and function of I domain-deleted Mac-1 and lymphocyte function-associated antigen-1

In those integrins that contain it, the I domain is a major ligand recognition site. The I domain is inserted between beta-sheets 2 and 3 of the predicted beta-propeller domain of the integrin alpha subunit. We deleted the I domain from the integrin alpha(M) and alpha(L) subunits to give I-less Mac-1 and lymphocyte function-associated antigen-1 (LFA-1), respectively. The I-less alpha(M) and alpha(L) subunits were expressed in association with the wild-type beta(2) subunit on the surface of transfected cells and bound to all the monoclonal antibodies mapped to the putative beta-propeller and C-terminal regions of the alpha(M) and alpha(L) subunits, suggesting that the folding of these domains is independent of the I domain. I-less Mac-1 bound to the ligands iC3b and factor X, but this binding was reduced compared with wild-type Mac-1. In contrast, I-less Mac-1 did not bind to fibrinogen or denatured bovine serum albumin. Binding to iC3b and factor X by I-less Mac-1 was inhibited by the function-blocking antibody CBRM1/32, which binds to the beta-propeller domain of the alpha(M) subunit. I-less LFA-1 did not bind its ligands intercellular adhesion molecule-1 and -3. Thus, the I domain is not essential for the folding, heterodimer formation, and surface expression of Mac-1 and LFA-1 and is required for binding to some ligands, but not others.     

Factor XIII cross-linking of fibronectin at cellular matrix assembly sites

We describe the effect of activated Factor XIII (Factor XIIIa, plasma transglutaminase) on the incorporation of plasma fibronectin into extracellular matrix by cultured human fibroblasts. In the absence of added Factor XIIIa, fibronectin binds to cultured fibroblast cell layers and is assembled into disulfide-bonded multimers of the extracellular matrix. When Factor XIIIa was included in the binding medium of skin fibroblasts, accumulation of 125I-fibronectin in the deoxycholate-insoluble matrix was increased. Fibronectin accumulating in the cell layer was cross-linked into nonreducible high molecular weight aggregates. The 70-kDa amino-terminal fragment of fibronectin inhibited the binding and cross-linking of 125I-fibronectin to cell layers, whereas fibrinogen had little effect. When 125I-fibronectin was incubated with isolated matrices or with cell layers pretreated with cytochalasin B, it did not bind and could not be cross-linked by Factor XIIIa into the matrix. HT-1080 human fibrosarcoma cells bound exogenous fibronectin following treatment with dexamethasone; Factor XIIIa cross-linked the bound fibronectin and caused its efficient transfer to the deoxycholate-insoluble matrix. These results indicate that exogenous fibronectin is susceptible to Factor XIIIa-catalyzed cross-linking at cellular sites of matrix assembly. Thus, Factor XIIIa-mediated fibronectin cross-linking complements disulfide-bonded multimer formation in the stabilization of assembling fibronectin molecules and thus enhances the formation of extracellular matrix.     

Functional characterization of human erythrocyte spectrin alpha and beta chains: association with actin and erythrocyte protein 4.1

Human erythrocyte spectrin alpha and beta chains were purified by preparative sodium dodecyl sulfate gel electrophoresis and also by DEAE-cellulose chromatography in the presence of urea. The purified chains behaved as individual monomers on sucrose gradients and did not form homodimers. Recombination of the chains led to the formation of alpha-beta heterodimers with sedimentation characteristics identical with native alpha-beta dimers. The binding of 125I-labeled band 4.1 to alpha and beta chains was measured by sucrose gradient rate zonal sedimentation and by quantitative immunoassay. It was found that both alpha and beta chains associated with 125I-labeled band 4.1 in a nearly identical manner over the range of band 4.1 concentration studied. The association was abolished by heat denaturation of the spectrin chains or by denaturation of band 4.1 with a 40-fold molar excess of N-ethylmaleimide. As expected, purified beta chains but not alpha chains bound to 125I-labeled ankyrin as measured by a quantitative radioimmunoassay. The binding of purified alpha chains, beta chains, and recombinant alpha-beta heterodimers to F-actin was measured in the presence of band 4.1. We found that alpha or beta chains separately exhibited no band 4.1 dependent association with F-actin but that alpha-beta heterodimers formed by recombination of the chains did. We conclude that spectrin binding to F-actin in the presence of band 4.1 requires the participation of both of spectrin's polypeptide chains.     

Specific binding of integrin alpha v beta 3 to the fibrinogen gamma and alpha E chain C-terminal domains

Integrin alpha v beta 3, a widely distributed fibrinogen receptor, recognizes the RGD572-574 motif in the alpha chain of human fibrinogen. However, this motif is not conserved in other species, nor is it required for alpha v beta 3-mediated fibrin clot retraction, suggesting that fibrinogen may have other alpha v beta 3 binding sites. Fibrinogen has conserved C-terminal domains in its alpha (E variant), beta, and gamma chains (designated alpha EC, beta C, and gamma C, respectively), but their function in cell adhesion is not known, except that alpha IIb beta 3, a platelet fibrinogen receptor, binds to the gamma C HHLGGAKQAGDV400-411 sequence. Here we used mammalian cells expressing recombinant alpha v beta 3 to show that recombinant alpha EC and gamma C domains expressed in bacteria specifically bind to alpha v beta 3. Interaction between alpha v beta 3 and gamma C or alpha EC is blocked by LM609, a function-blocking anti-alpha v beta 3 mAb, and by RGD peptides. alpha v beta 3 does not require the HHLGGAKQAGDV400-411 sequence of gamma C for binding, and alpha EC does not have such a sequence, indicating that the alpha v beta 3 binding sites are distinct from those of alpha IIb beta 3. A small fragment of gamma C (residues 148-226) supports alpha v beta 3 adhesion, suggesting that an alpha v beta 3 binding site is located within the gamma chain 148-226 region. We have reported that the CYDMKTTC sequence of beta 3 is responsible for the ligand specificity of alpha v beta 3. gamma C and alpha EC do not bind to wild-type alpha v beta 1, but do bind to the alpha v beta 1 mutant (alpha v beta 1-3-1), in which the CYDMKTTC sequence of beta 3 is substituted for the corresponding beta 1 sequence CTSEQNC. This suggests that gamma C and alpha EC contain determinants for fibrinogen's specificity to alpha v beta 3. These results suggest that fibrinogen has potentially significant novel alpha v beta 3 binding sites in gamma C and alpha EC.     

Interaction of integrins alpha v beta 3 and glycoprotein IIb-IIIa with fibrinogen. Differential peptide recognition accounts for distinct binding sites

Glycoprotein (GP) IIb-IIIa is the major fibrinogen receptor on platelets and participates in platelet aggregation at the site of a wound. Integrin alpha v beta 3, which contains an identical beta-subunit, is expressed on endothelial cells and also serves as a fibrinogen receptor. Here, we demonstrate by several criteria that purified GPIIb-IIIa and integrin alpha v beta 3 bind to distinct sites on fibrinogen. First, a plasmin-generated fragment of fibrinogen lacking the RGD sequence at residues 572-574 retained the ability to bind GPIIb-IIIa, but failed to bind integrin alpha v beta 3. Second, a monoclonal antibody which exclusively recognizes the RGD sequence at fibrinogen A alpha chain residues 572-574 abolished interaction between integrin alpha v beta 3 and fibrinogen, but had only a minimal effect on fibrinogen binding to GPIIb-IIIa. Finally, we show that the difference in recognition of sites on fibrinogen by these two integrins is probably a consequence of their remarkably different ligand binding properties. Peptides corresponding to fibrinogen gamma chain residues 400-411 effectively blocked RGD sequence and fibrinogen binding by GPIIb-IIIa, but had no effect on the ability of integrin alpha v beta 3 to bind these ligands. We also show that integrin alpha v beta 3 has a higher affinity than GPIIb-IIIa for a synthetic hexapeptide containing the RGD sequence. In fact, this RGD-containing peptide was 150-fold more effective at blocking fibrinogen binding to integrin alpha v beta 3 than to GPIIb-IIIa. Collectively, our results demonstrate that integrins alpha v beta 3 and GPIIb-IIIa display qualitative and quantitative differences in their ligand binding properties, as is evident by their ability to interact with synthetic peptides. The ultimate result of these differences is the recognition of distinct sites on fibrinogen by the two integrins. These observations may have relevance in the processes of hemostasis and wound healing.