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.     

Studies of extracellular fibronectin matrix formation with fluoresceinated fibronectin and fibronectin fragments

Fluorescein isothiocyanate conjugated human plasma fibronectin, 70-kDa collagen-binding, 60-kDa central, 60-kDa heparin-binding, 180-kDa heparin, collagen-binding fibronectin fragments and gelatin were used to study extracellular fibronectin matrix formation. Exogenous fibronectin, gelatin, 70-kDa collagen-binding and 180-kDa heparin, collagen-binding fragments were shown to be able to bind specifically to preexisting extracellular matrix of living fibroblasts. The results suggest that: (i) Fibronectin matrix formation may occur through a self-assembly process; (ii) the NH2-terminal part of fibronectin is responsible for fibronectin-fibronectin interaction during fibronectin fibril formation; (iii) plasma fibronectin may be the source for tissue fibronectin.     

Cell surface molecules that bind fibronectin's matrix assembly domain

The assembly of fibronectin into disulfide cross-linked extracellular matrices requires the interaction of mesenchymal cells with two distinct sites on fibronectin, the Arg-Gly-Asp cell adhesive site and an amino-terminal site contained within the first five type I homologous repeats (Quade, B. J., and McDonald, J. A. (1988) J. Biol. Chem. 263, 19602-19609). Proteolytically derived 29-kDa fragments of fibronectin (29kDa) containing these repeats bind to monolayers of cultured fibroblasts and inhibit fibronectin matrix assembly. The cell surface molecules interacting with fibronectin's 29-kDa matrix assembly domain have resisted purification using conventional methods such as affinity chromatography. Accordingly, in order to identify molecules which bind this fragment, 125I-labeled 29kDa was allowed to bind to fibroblast monolayers and chemically cross-linked to the cell surface with bis(sulfosuccinimidyl) suberate. Extraction of the cross-linked cell layer yielded radiolabeled complexes of 56, 150, and 280 kDa. Formation of these cross-linked complexes was specifically inhibited by the addition of excess unlabeled 29kDa but was unaffected by the presence of fibronectin fragments containing other type I repeats outside of the 29kDa matrix assembly domain. The cross-linked complexes were insoluble in nondenaturing detergents but soluble when denatured and reduced, suggesting that 29kDa may be cross-linked to components of the pericellular matrix. Immunoprecipitation of cross-linked cell extracts with a polyclonal antibody to fibronectin that does not recognize the amino terminus demonstrate that the 280-kDa band contains 29kDa cross-linked to fibronectin present on the cell surface. Formation of the 150-kDa complex was inhibited by EDTA, suggesting that divalent cations are required for its formation. Although the molecular mass and divalent cation requirement suggest that the 150-kDa complex may be related to an integrin, this complex was not immunoprecipitated by polyclonal antibodies generated to the alpha 5 beta 1 integrin fibronectin receptor.     

Transglutaminase-sensitive glutamine residues of human plasma fibronectin revealed by studying its proteolytic fragments

The sites of transglutamination of fibronectin and fibronectin fragments, by coagulation factor XIIIa and tissue transglutaminase, were studied. It was shown that the intact fibronectin molecule has two sites sensitive to coagulation factor XIIIa and four sites sensitive to tissue transglutaminase: 180--190-kDa gelatin/heparin-binding fragments, 2 and 5--6 sites; 29-kDa heparin-I/fibrin-I-binding N-terminal fragments, 1 and 2 sites; 70-kDa gelatin-binding fragments, 0 and 1 site; 60-kDa cell-binding central fragments, 1 and 3--4 sites; 60-kDa, 45-kDa, 30-kDa heparin-II-binding C-terminal fragments, 1 and 2 sites. Thus, we have found a new coagulation-factor-XIIIa-sensitive site localized in the cell-binding central fragment, inaccessible to enzyme in the intact fibronectin molecule. Tissue transglutaminase appeared to interact with all of the three coagulation-factor-XIIIa-sensitive sites and, in addition, some others which are either available on the intact molecule or can be revealed only in proteolytic fragments of the fibronectin. We suggest that interdomain and intersubunit interactions in the intact fibronectin molecule account for the masking of glutamine residues potentially accessible to transglutaminases.     

Model of fibronectin tertiary structure based on studies of interactions between fragments

Human plasma fibronectin aggregates in solution and is thought to form fibrils on cell surfaces, perhaps by self-associating and by interacting with other components such as proteoglycans. We have localized the self-association domains by testing the ability of various fragments of fibronectin to interact with each other. Complexation between fluorescamine-labeled fragments and unlabeled fragments or whole molecules was assessed by gel filtration high-performance liquid chromatography. The fragments studied included nonoverlapping fragments that are situated on the fibronectin polypeptide chain in the following order, beginning from the amino terminus: the 29-, 50-, 120-, 35-, and 25-kDa fragments, as well as multiple-domain fragments of 72 kDa containing the 29- and 50-kDa segments, a fragment of 150 kDa containing the 120- and 35-kDa segment, a fragment of 190 kDa containing the 120- and 35-kDa segments, a fragment of 190 kDa containing the 50-, 150-, and 25-kDa segments, and a 45-kDa fragment containing the 35-kDa segment. The amino-terminal 29-kDa fragment bound to the carboxyl-terminal heparin-binding (Hep II) 35-kDa fragment as well as the 150- and 190-kDa fragments that contain the 35-kDa segment. On the other hand, carboxyl-terminal 35- and 45-kDa Hep II containing fragments bound to each other as well as to amino-terminal 29- and 72-kDa fragments and to the 190-kDa fragment. Further, the 25-kDa carboxyl-terminal fibrin-binding fragment bound the 190-kDa fragment, the only fragment containing the 25-kDa segment.(ABSTRACT TRUNCATED AT 250 WORDS)     

Dissociation of fibrinogen and fibronectin binding from transglutaminase-mediated cross-linking at the hepatocyte surface

The interaction of fibrinogen and fibronectin with hepatocytes has been dissociated into distinct binding and cross-linking steps. Binding and cross-linking of 125I-labeled ligands were both decreased by transglutaminase inhibitors, but not by heparin or hirudin. Transglutaminase activity was manifest by Ca2+-dependent incorporation of [14C]putrescine into cells. Preferential cross-linking of fibrinogen A alpha over gamma chains, and lack of inhibition by heparin or hirudin indicates the involvement of tissue transglutaminase, and not Factor XIIIa. Hepatic transglutaminase activity, as well as binding and cross-linking of fibrinogen and fibronectin, were maximally supported by Ca2+, partially supported by Mn2+ and Sr2+, and markedly decreased by Mg2+ and Ba2+. In contrast, Co2+ supported binding but not cross-linking or transglutaminase activity, indicating that binding and cross-linking are dissociable events. This conclusion was corroborated by the finding that fibrinogen fragments D95 and D78 both inhibited Ca2+-dependent fibrinogen binding without being cross-linked themselves. Ligand binding in the presence of either cation was localized to the cell surface as evidenced by its trypsin sensitivity. Thus, fibrinogen and fibronectin binding to hepatocytes is independent of transglutaminase activity, whereas cross-linking of these adhesive macromolecules requires an enzymatically active cellular transglutaminase. In addition, fibrinogen binding appears to be mediated by molecular determinants present in fragment D78.     

The core protein of the matrix-associated heparan sulfate proteoglycan binds to fibronectin

The extracellular matrix of cultured human lung fibroblasts contains one major heparan sulfate proteoglycan. This proteoglycan contains a 400-kDa core protein and is structurally and immunochemically identical or closely related to the heparan sulfate proteoglycans that occur in basement membranes. Because heparitinase does not release the core protein from the matrix of cultured cells, we investigated the binding interactions of this heparan sulfate proteoglycan with other components of the fibroblast extracellular matrix. Both the intact proteoglycan and the heparitinase-resistant core protein were found to bind to fibronectin. The binding of 125I-labeled core protein to immobilized fibronectin was inhibited by soluble fibronectin and by soluble cold core protein but not by albumin or gelatin. A Scatchard plot indicates a Kd of about 2 x 10(-9) M. Binding of the core protein was also inhibited by high concentrations of heparin, heparan sulfate, or chrondroitin sulfate and was sensitive to high salt concentrations. Thermolysin fragmentation of the 125I-labeled proteoglycan yielded glycosamino-glycan-free core protein fragments of approximately 110 and 62 kDa which bound to both fibronectin and heparin columns. The core protein-binding capacity of fibronectin was very sensitive to proteolysis. Analysis of thermolytic and alpha-chymotryptic fragments of fibronectin showed binding of the intact proteoglycan and of its isolated core protein to a protease-sensitive fragment of 56 kDa which carried the gelatin-binding domain of fibronectin and to a protease-sensitive heparin-binding fragment of 140 kDa. Based on the NH2-terminal amino acid sequence analyses of the 56- and 140-kDa fragments, the core protein-binding domain in fibronectin was tentatively mapped in the area of overlap of the two fragments, carboxyl-terminally from the gelatin-binding domain, possibly in the second type III repeat of fibronectin. These data document a specific and high affinity interaction between fibronectin and the core protein of the matrix heparan sulfate proteoglycan which may anchor the proteoglycan in the matrix.     

Interaction of the 70,000-mol-wt amino-terminal fragment of fibronectin with the matrix-assembly receptor of fibroblasts

Plasma fibronectin binds saturably and reversibly to substrate-attached fibroblasts and is subsequently incorporated into the extracellular matrix (McKeown-Longo, P.J., and D. F. Mosher, 1983, J. Cell Biol., 97:466-472). We examined whether fragments of fibronectin are processed in a similar way. The amino-terminal 70,000-mol-wt catheptic D fragment of fibronectin bound reversibly to cell surfaces with the same affinity as intact fibronectin but did not become incorporated into extracellular matrix. The 70,000-mol-wt fragment blocked binding of intact fibronectin to cell surfaces and incorporation of intact fibronectin into extracellular matrix. Binding of the 70,000-mol-wt fragment to cells was partially abolished by cleavage into 27,000-mol-wt heparin-binding and 40,000-mol-wt gelatin-binding fragments and more completely abolished by reduction and alkylation of disulfide bonds. Binding of the 70,000-mol-wt fragment to cells was not blocked by gelatin or heparin. When coated onto plastic, the 70,000-mol-wt fragment did not mediate attachment and spreading of suspended fibroblasts. Conversely, fibronectin fragments that had attachment and spreading activity did not block binding of exogenous fibronectin to substrate-attached cells. These results indicate that there is a cell binding site in the 70,000-mol-wt fragment that is distinct from the previously described cell attachment site and is required for assembly of exogenous fibronectin into extracellular matrix.     

Fibronectin's cell-adhesive domain and an amino-terminal matrix assembly domain participate in its assembly into fibroblast pericellular matrix

Fibroblasts organize the modular cell-adhesive glycoprotein fibronectin into a highly structured pericellular matrix by poorly understood mechanisms. Previous studies implicated an amino-terminal domain in matrix assembly and suggested that fibronectin's cell-adhesive domain and the corresponding fibroblast receptor were not involved in this process. To further elucidate the fibronectin region(s) involved in matrix assembly, we mapped a library of proteolytic fragments and antibodies to various fibronectin domains. The fragments and antibodies were used to probe the role of fibronectin's amino-terminal and cell-adhesive domains in a fibroblast matrix assembly assay. We found that fibronectin fragments including the first 25-kDa sequence of fibronectin and antibodies to amino-terminal domains inhibited pericellular matrix assembly. Polyclonal antibodies to the 40-kDa collagen binding domain following the 25-kDa amino-terminal domain also inhibited matrix assembly. However, collagen binding is not required for matrix assembly as neither monoclonals blocking collagen binding nor purified collagen binding domains themselves inhibited matrix assembly. Therefore, the amino-terminal region of fibronectin contains a site important in matrix assembly, and most activity is present in the first 25-kDa of fibronectin. Fibronectin's cell-adhesive domain and the fibroblast receptor binding to this domain also play an important role in fibronectin matrix assembly. Apart from a monoclonal antibody to the amino-terminal domain, only monoclonal antibodies binding to fibronectin's cell-adhesive domain and inhibiting cell adhesion also inhibited matrix assembly. In addition a 105-kDa fragment containing the cell-adhesive domain inhibited matrix assembly. We conclude that at least two discrete and widely separated sites in fibronectin with different binding properties--the carboxyl-terminal fibroblast cell-adhesive domain and an amino-terminal matrix assembly domain localized primarily within the first 25 kDa--are required for fibronectin pericellular matrix assembly by fibroblasts. Fibronectin's cell-adhesive domain and its cell surface-receptor complex appear to be involved in the matrix assembly process prior to a step involving the amino-terminal domain. We believe that this step is likely to be the initiation of cell-associated fibronectin fibril formation by the fibronectin-adhesive-receptor complex.     

Inhibition of fibronectin matrix assembly by the heparin-binding domain of vitronectin.

The deposition of fibronectin into the extracellular matrix is an integrin-dependent, multistep process that is tightly regulated in order to ensure controlled matrix deposition. Reduced fibronectin deposition has been associated with altered embryonic development, tumor cell invasion, and abnormal wound repair. In one of the initial steps of fibronectin matrix assembly, the amino-terminal region of fibronectin binds to cell surface receptors, termed matrix assembly sites. The present study was undertaken to investigate the role of extracellular signals in the regulation of fibronectin deposition. Our data indicate that the interaction of cells with the extracellular glycoprotein, vitronectin, specifically inhibits matrix assembly site expression and fibronectin deposition. The region of vitronectin responsible for the inhibition of fibronectin deposition was localized to the heparin-binding domain. Vitronectin's heparin-binding domain inhibited both beta(1) and non-beta(1) integrin-dependent matrix assembly site expression and could be overcome by treatment of cells with lysophosphatidic acid, an agent that promotes actin polymerization. The interaction of cells with the heparin-binding domain of vitronectin resulted in changes in actin microfilament organization and the subcellular distribution of the actin-associated proteins alpha-actinin and talin. These data suggest a mechanism whereby the heparin-binding domain of vitronectin regulates the deposition of fibronectin into the extracellular matrix through alterations in the organization of the actin cytoskeleton.     

Role of the I-9 and III-1 modules of fibronectin in formation of an extracellular fibronectin matrix.

Cultured fibroblasts bind soluble protomeric fibronectin and mediate its conversion to insoluble disulfide-bonded multimers. The disulfide-bonded multimers are deposited in fibrillar pericellular matrix. Antifibronectin monoclonal antibodies were analyzed to identify domains of fibronectin required for assembly into matrix. Two antibodies, L8 and 9D2, inhibited binding and insolubilization of 125I-labeled plasma fibronectin by fibroblasts but did not inhibit binding of labeled amino-terminal 70-kDa fragment of fibronectin to matrix assembly sites. Immunoblotting of fibronectin fragments showed that the epitope for 9D2 is in the first type III homology sequence (III-1) whereas the epitope for L8 requires that the last type I sequence of the gelatin binding region (I-9) be contiguous to III-1 and is sensitive to reduction of disulfides in I-9. A 56-kDa gelatin-binding thermolysin fragment of fibronectin that contains III-1 and the L8 and 9D2 epitopes inhibited binding of fibronectin to cell layers 10-fold better than a 40-kDa gelatin-binding fragment that lacks III-1 and the antigenic sites. This 56-kDa fragment, however, did not bind specifically to cell layers. These results indicate that the I-9 and III-1 modules of fibronectin form a functional unit that mediates an interaction, perhaps between protomers, important in the assembly of fibronectin.     

Extracellular matrix assembly of cell-derived and plasma-derived fibronectins by substrate-attached fibroblasts

Using a previously described model system for the incorporation of plasma fibronectin into the extracellular matrix (McKeown-Longo, P.J. and Mosher, D.F., 1985. J. Cell Biol., 100:364-374), we compared the binding of cell-derived and plasma-derived fibronectins to human fibroblast cell layers. Binding was measured in time course experiments using metabolically labeled cell-derived, iodinated cell-derived, and iodinated plasma-derived fibronectins. The kinetics of matrix assembly of cell- and plasma-derived fibronectins were the same. Competitive binding curves using intact fibronectin or the 70-kD amino-terminal fragment of fibronectin suggested that cell surface binding sites have equal affinity for cell- and plasma-derived fibronectins. Iodinated fibronectins did not bind to isolated matrices containing collagen type I, fibronectin, and thrombospondin. These results suggest that fibroblasts do not distinguish between cell-derived and plasma-derived fibronectins when assembling exogenous fibronectin into extracellular matrix.     

Localization of cell surface sites involved in fibronectin fibrillogenesis

Fibronectin binding sites on cultured human fibroblasts were localized by high voltage electron microscopy using either 5- or 18-nm colloidal gold beads (Au5 or Au18) bound to intact fibronectin, the 70-kD amino- terminal fragment of fibronectin that blocks incorporation of exogenous fibronectin into extracellular matrix, or 160-180-kD fragments of fibronectin with cell adhesion and heparin-binding activities. Binding sites for Au18-fibronectin on the cell surface were localized to specific regions along the edge of the fibroblast and on retraction fibers. Au18-fibronectin complexes at these sites were initially localized in clusters that co-aligned with intracellular microfilament bundles. With longer incubations, Au18-fibronectin complexes were arranged into long fibrillar networks on the cell surface and in the extracellular space. The appearance of Au18-fibronectin in these fibrillar networks and disappearance of clusters of Au18-fibronectin suggest that Au18-fibronectin complexes are arranged into matrix at specific regions of the cell surface. Au18-70-kD fragment complexes initially had a similar distribution to Au18-fibronectin complexes. With longer incubations, Au18-70-kD fragment complexes were found in long linear arrangements on the cell surface. Double labeling experiments using Au18-70-kD fragment and Au5-160-180-kD fragments showed that the 70-kD fragment and the 160-180-kD fragments bind to different regions of the cell.     

Distribution of secondary structure along the fibronectin molecule

30-kDa, 50-kDa and 70-kDa gelatin-binding, 60-kDa central and 60-65-kDa heparin-binding fragments were produced by trypsin digestion of fibronectin. The secondary structure of the fragments was studied by circular dichroism and quantitative infrared spectroscopy. The structure of the 70-kDa gelatin-binding, 60-kDa central and 60-65-kDa heparin-binding fragments in solution appeared to be very close to that in the intact fibronectin. The content of the antiparallel beta-form, the only element of the secondary structure in all the fragments studied, was shown to be 30-35%.     

Cross-linking of a major fibroblast surface-associated glycoprotein (fibronectin) catalyzed by blood coagulation factor XIII

The surface proteins of cultured human skin fibroblasts were iodinated and then exposed to one or more of the following blood coagulation proteins: thrombin, fibrinogen, and factor XIII (plasma protransglutaminase). Radiolabeled polypeptides were analyzed by polyacrylamide gel electrophoresis in the presence of sodium dodecylsulfate. After exposure to physiological concentrations of activated factor XIII (XIII_a), the band of radioactivity corresponding to the major labeled surface protein (fibronectin, molecular weight = 2.2 × 10⁵ daltons) was cross-linked to a very high molecular weight complex. The cross-linking reaction was inhibited by fibrin (which is known to bind the catalytic subunit of XIII_a). Cross-linking of labeled cell surface fibronectin to fibrin could not be demonstrated. The fibrillar pattern of surface fibronectin appeared unaffected by cross-linking when studied by immunofluorescence. Cross-linking of cell surface fibronectin by XIII_a requires highly specific enzyme-substrate and protein-protein interactions, and may be an important physiological reaction.     

The N-terminal 70-kDa fragment of fibronectin binds to cell surface fibronectin assembly sites in the absence of intact fibronectin.

Binding of the N-terminal 70-kDa (70K) fragment of fibronectin to fibroblasts blocks assembly of intact fibronectin and is an accurate indicator of the ability of various agents to enhance or inhibit fibronectin assembly. Such binding is widely thought to be to already assembled fibronectin. We evaluated this hypothesis with fibronectin-null mouse fibroblasts plated on laminin-1 in the absence of intact fibronectin. As a proteolytic fragment or recombinant protein, 70K bound fibronectin-null cells specifically in linear arrays that extended outwards from the periphery of spread cells. At early time points, these arrays were similar to those formed by intact fibronectin. 70K arrays formed within 5 min following ligand addition at concentrations as low as 5 nM, indicating rapid and high affinity binding. Bound 70K was extractable with Triton X-100 or deoxycholate but became insoluble when cross-linked with a membrane-impermeable agent into large SDS-stable complexes. Intact fibronectin, in contrast, became progressively non-extractable in the absence of cross-linking. The detergent-resistant arrays of cross-linked 70K localized to tips of cellular extensions and partially overlapped with alpha6 and beta1 integrin subunits at the base of the extensions. alpha5 did not localize with 70K arrays, but became progressively co-localized with assemblies of intact fibronectin over time. These results support a model in which the 70-kDa region of fibronectin binds to linearly arrayed cell surface molecules of adherent cells to initiate assembly, display of the arrays is controlled by the integrin that mediates adhesion, and fibronectin-binding integrins promote fibronectin-fibronectin interactions during progression of assembly.     

The heparin-dependent accumulation of plasma fibronectin on macrophages

Previous experiments (H?rmann, H. & Jelini?, V. (1980) Hoppe-Seyler's Z. Physiol. Chem. 361, 379-387) had shown that heparin promoted the binding of plasma fibronectin to peritoneal macrophages of guinea pigs. The present data reveal that this effect only takes place at higher fibronectin concentrations indicating cooperative processes, most likely association of fibronectin at the cell surface. An unspecific precipitation of fibronectin by heparin was prevented by calcium in the medium. The accumulation at the cell surface was inhibited by the following fibronectin fragments: N-terminal 30 kDa and 70 kDa containing a potential self-association site and a transamidase-reactive site; central 95 kDa which comprised a negatively charged region possibly involved in self-association as well as the so-called alternative cell-binding site, but was lacking the cell-binding Arg-Gly-Asp sequence; heparin-binding 37-kDa and 60-kDa fragments. All these domains and sites, therefore, were potentially important in the assembly process at the cell surface. A peptide comprising the sequence Arg-Gly-Asp was ineffective pointing against an involvement of this fibronectin cell-binding site in the overall process. Macrophages of older animals were less capable of accumulating fibronectin under the reaction conditions. Their capability was improved after preincubation with activated plasma transglutaminase (coagulation factor XIIIa) suggesting that a cell-attached transamidase might be important for the assembly process.     

Cryptic chemotactic activity of fibronectin for human monocytes resides in the 120-kDa fibroblastic cell-binding fragment

Monocytes and lymphocytes form a second wave of infiltrating blood leukocytes in areas of tissue injury. The mechanisms for monocyte accumulation at these sites are not completely understood. Recently, however, fragments from extracellular matrix proteins including collagen, elastin, and fibronectin have been shown to induce monocyte chemotaxis. In this report we demonstrate that chemotactic activity for human monocytes is expressed when a 120-kDa fragment containing the RGDS cell-binding peptide is released from intact fibronectin or from larger fibronectin fragments. Monocytes, either from mononuclear cell Ficoll-Hypaque preparations (10-20% monocytes, 89-90% lymphocytes) or from elutriation preparations (95% monocytes, 5% lymphocytes), but not lymphocytes, migrated toward 120-kDa fragment preparations (10(-7) M) in blind-end chambers when the cells were separated from the chemoattractant by a 5-micron pore polycarbonate filter either alone or overlying a 0.45-micron pore nitrocellulose filter. Neutrophils migrated toward zymosan-activated serum but not toward 10(-5)-10(-8) M concentrations of the 120-kDa fragment. Intact fibronectin had no chemotactic activity for human monocytes. Fibronectin was isolated from citrated human plasma by sequential gelatin-Sepharose affinity and DEAE ion-exchange chromatography in the presence of buffers containing 1 mM phenylmethylsulfonyl fluoride to prevent fragmentation. Controlled enzymatic digestion with thermolysin cleaved fibronectin into 30 kDa fibrin, 45 kDa collagen, and 150/160-kDa cell and heparin domains. Upon prolonged digestion, purified 150/160-kDa fragments were cleaved into 120-kDa cell and 30/40-kDa heparin-binding fragments. Even though the intact fibronectin molecule, the 150/160-kDa fragments, and the 120-kDa fragment, have cell binding activity for Chinese hamster ovary fibroblasts, only the 120-kDa fragment expressed chemotactic activity for human monocytes. Thus, the 120-kDa fibroblastic cell-binding fragment contains a cryptic site for monocyte chemotaxis which is expressed upon enzymatic cleavage of fibronectin.     

Latent fibronectin-degrading serine proteinase activity in N-terminal heparin-binding domain of human plasma fibronectin

The N-terminal 70-kDa fragment of human plasma fibronectin, purified from a cathepsin D digest, is characterized by lack of stability. It is processed proteolytically during incubation in the presence of Ca2+ into 27-kDa N-terminal heparin-binding and 45-kDa collagen-binding domains. The N-terminal residue in the 27-kDa fragment was blocked as in native fibronectin. The 45-kDa fragments began with the sequences AAVYQP, AVYQP and VYQP (residues 260, 261, 262-265 of fibronectin) that correspond to the beginning of the collagen-binding domain. In the presence of Ca2+ the purified 27-kDa fragment underwent further processing finally leading to the cleavage of the bond K85-D86 and to the simultaneous appearance of a specific proteolytic activity. Inhibition studies suggests that the newly generated enzyme is a Ca(2+)-dependent serine proteinase. Among all assayed matrix proteins, the newly generated enzyme cleaves native fibronectin and its fragments. It is proposed that this fibronectinase may originate from the N-terminal domain of fibronectin.     

Inhibition of binding of fibronectin to matrix assembly sites by anti- integrin (alpha 5 beta 1) antibodies

Fibroblasts have cell surface sites that mediate assembly of plasma and cellular fibronectin into the extracellular matrix. Cell adhesion to fibronectin can be mediated by the interaction of an integrin (alpha 5 beta 1) with the Arg-Gly-Asp-Ser (RGDS)-containing cell adhesion region of fibronectin. We have attempted to elucidate the role of the alpha 5 beta 1 fibronectin receptor in assembly of fibronectin in matrices. Rat monoclonal antibody mAb 13, which recognizes the integrin beta 1 subunit, completely blocked binding and matrix assembly of 125I-fibronectin as well as binding of the 125I-70-kD amino-terminal fragment of fibronectin (70 kD) to fibroblast cell layers. Fab fragments of the anti-beta 1 antibody were also inhibitory. Antibody mAb 16, which recognizes the integrin alpha 5 subunit, partially blocked binding of 125I-fibronectin and 125I-70-kD. When cell layers were coincubated with fluoresceinated fibronectin and either anti-beta 1 or anti-alpha 5, anti-beta 1 was a more effective inhibitor than anti-alpha 5 of binding of labeled fibronectin to the cell layer. Inhibition of 125I-fibronectin binding by anti-beta 1 IgG occurred within 20 min. Inhibition of 125I-fibronectin binding by anti-beta 1 Fab fragments or IgG could not be overcome with increasing concentrations of fibronectin, suggesting that anti-beta 1 and exogenous fibronectin may not compete for the same binding site. No beta 1-containing integrin bound to immobilized 70 kD. These data indicate that the beta 1 subunit plays an important role in binding and assembly of exogenous fibronectin, perhaps by participation in the organization, regeneration, or cycling of the assembly site rather than by a direct interaction with fibronectin.