A novel method for purification of plasma fibronectin

Plasma fibronectin was purified from a gelatin-affinity chromatography column by elution with glucose. This procedure was effective only if the gelatin was particulate when it was attached to the Sepharose 4B. Glucose could not elute fibronectin from the gelatin if the gelatin was melted before it was attached to the Sepharose 4B. This new purification technique has the advantage of using very mild conditions for the isolation of plasma fibronectin.     

Elution of fibronectin proteolytic fragments from a hydroxyapatite chromatography column. A simple procedure for the purification of fibronectin domains

Human plasma fibronectin is composed of at least five distinct domains which we refer to as Hep-1/Fib-1, Gel, Cell, Hep-2 and Fib-2 depending on their affinity for heparin (Hep), gelatin (Gel), the cell surface (Cell) or fibrin (Fib). These domains are aligned from the NH2 to the COOH terminus in the above order and can be separated from each other by mild proteolytic digestion. We have studied the elution of fibronectin thermolysin digest from a hydroxyapatite column using a linear gradient (0.5-190 mM) of sodium phosphate buffer. The five major fibronectin domains were eluted from the hydroxyapatite chromatography column in the following order: Gel, Fib-2, Cell, Hep-1/Fib-1 and Hep-2. They were identified on the basis of their molecular mass, affinity to different macromolecules and reaction with domain-specific monoclonal antibodies. All domains except the Cell and Hep-2 domains eluted as single homogeneous peaks. The Cell domain eluted as two different peaks and the Hep-2 domain eluted as four different peaks. This is the first time that heterogeneity of these two domains has been observed. Since chromatography of a fibronectin thermolysin digest on a hydroxyapatite column provides a good separation of the five major fibronectin domains, we have elaborated a procedure in which each fibronectin domain is purified by no more than two steps; hydroxyapatite and molecular exclusion chromatography. Fractionation of fibronectin proteolytic digest on a hydroxyapatite chromatography column should be of great value in the comparative analysis of fibronectin from different sources and in the study of fibronectin heterogeneity. Its use in combination with molecular exclusion chromatography offers a simple and high-yield method for the purification of large amounts of fibronectin domains.     

Large-scale procedure for the purification of fibronectin domains

Human plasma fibronectin is composed of at least seven distinct domains, with affinities for different macromolecules and cell surfaces. Here we describe in detail a simple high-yield procedure for the purification of large amounts of fibronectin domains. This involves thermolysin digestion of the fibronectin molecule followed by the purification of the domain using mainly hydroxyapatite chromatography columns. This procedure represents a great simplification over those previously reported.     

Human placental (fetal) fibronectin: increased glycosylation and higher protease resistance than plasma fibronectin. Presence of polylactosamine glycopeptides and properties of a 44-kilodalton chymotryptic collagen-binding domain: difference from human plasma fibronectin

Human placental fibronectin was isolated from fresh term placenta by urea extraction and purified by gelatin affinity chromatography. A 44-kDa chymotryptic fragment, also purified by gelatin affinity chromatography, gave a broad, diffuse band on polyacrylamide gel electrophoresis, whereas the analogous 43-kDa fragment from human plasma fibronectin migrated as a defined, narrow band. Upon extended treatment with endo-beta-galactosidase from Escherichia freundii, the 44-kDa chymotryptic gelatin-binding fragment from placental fibronectin changed its behavior on gel electrophoresis and migrated as a narrower, more defined band. The carbohydrates on human placental fibronectin contained a large percentage of polylactosamine structures, part of which occurred on the gelatin-binding fragment, comprising almost twice as much carbohydrate as plasma fibronectin. NH2-terminal amino acid sequence analysis of the chymotryptic gelatin-binding fragments from both fibronectins showed the first 21 residues to be identical. Tryptic and chymotryptic peptide maps of the gelatin-binding fragment from placental fibronectin, however, showed differences including several protease-resistant domains not found in the analogous fragment from plasma fibronectin. Intact placental fibronectin contains 20,000 Da of carbohydrate, whereas plasma fibronectin contains 11,000 Da. Placental fibronectin is more protease-resistant than plasma fibronectin, possibly due to the additional carbohydrate. Polyclonal antibodies against either fibronectin completely cross-react with amniotic fluid fibronectin, placental fibronectin, and plasma fibronectin upon Ouchterlony immunodiffusion. Human fibronectins of putatively the same polypeptide structure are, therefore, glycosylated in a dramatically different fashion, depending on the tissue of expression. If the patterns of glycosylation comprise the only difference in the glycoprotein, this may confer the characteristic protease resistance found for each of the fibronectins.     

Plasma fibronectin binds glucose

Equilibrium dialysis studies demonstrated that plasma fibronectin bound D-glucose with moderate affinity. The binding of glucose by plasma fibronectin caused the dissoclation of plasma fibronectin-gelatin complexes. Glucose and gelatin did not compete for the same binding sites on plasma fibronectin. The glucose-caused dissociation of plasma fibronectin from plasma fibronectin-gelatinized horse erythrocyte complexes destroyed the potent hemagglutination activity of these complexes against trypsinized, formalinized sheep erythrocytes.     

Developmental changes in the glycosylation and binding properties of human fibronectins. Characterization of the glycan structures and ligand binding of human fibronectins from adult plasma, cord blood and amniotic fluid

Fibronectins from human adult plasma, fetal plasma and from amniotic fluid obtained during early and late gestation were compared with respect to (i) their reactivity with lectins, (ii) their binding to the physiological ligands gelatin and heparin, and (iii) the role of the carbohydrate residues in the binding to these two ligands. The two fibronectin isoforms displayed distinct developmental differences in both glycosylation and binding properties: (i) Proportions of tri/tetraantennary complex glycans compared to the fraction of biantennary structures, as inferred from the reactivity with concanavalin A, were highest in amniotic fluid fibronectin from late pregnancy, lower in amniotic fluid fibronectin from early gestation, and even lower in fetal and adult plasma fibronectins. Likewise, fucose (alpha 1-6) linked to the innermost N-acetylglucosamine of the chitobiosyl core, defined by reactivity with Lens culinaris agglutinin (LCA), was present primarily in amniotic fluid fibronectin, and decreased in content during gestation from the 2nd. to the 3rd. trimenon. Both fetal and adult plasma fibronectins were only weakly reactive with LCA, indicating a low content of (alpha 1-6) linked fucose residues. After prior treatment with sialidase, both plasma and amniotic fluid fibronectins strongly reacted with erythrocyte phytohaemagglutinin (E-PHA), indicating that both fibronectin isoforms contain bisecting (beta 1-4) N-acetylglucosamine residues. Amniotic fluid fibronectins showed much greater reactivity than adult and fetal plasma fibronectins with wheat germ agglutinin; binding of this lectin to amnion fluid fibronectins was not decreased by desialylation indicating the presence of poly(N-acetyllactosamine) units. Whereas amniotic fluid fibronectins were strongly reactive with peanut agglutinin, neither adult nor fetal plasma fibronectins did bind to this lectin unless after prior desialylation. Hence, both fibronectin isoforms contain O-glycan residues that are fully sialylated in fetal and adult plasma fibronectins, but only partly sialylated in amniotic fluid fibronectins. According to these differences, glycosylation of plasma and amniotic fluid fibronectins is under developmental regulation. (ii) Amniotic fluid fibronectins had a significantly lower binding activity for both heparin and gelatin than plasma fibronectins. Moreover, amnion fibronectin from late gestation displayed a significantly lower binding to these two ligands than amnion fibronectin from early gestation. Fetal plasma fibronectins had a lower binding activity for gelatin than adult plasma fibronectin. (iii) Treatment of fibronectins with sialidase, fucosidase and removal of N-glycans with endoglycosidases H and F did not affect binding to gelatin and heparin, indicating that the interaction of plasma and amnion fibronectin with these two ligands is not influenced by their oligosaccharide moieties.     

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.     

Domain structure of human plasma and cellular fibronectin. Use of a monoclonal antibody and heparin affinity to identify three different subunit chains

The domain structure of human plasma fibronectin was investigated by using heparin-binding and antibody reactivity of fibronectin and its proteolytically derived fragments. Digestion of human plasma fibronectin with a combination of trypsin and cathepsin D produced six major fragments. Affinity chromatography showed that one fragment (Mr 45 000) binds to gelatin and three fragments (Mr 31 000, 36 000, and 61 000) bind to heparin. The 31K fragment corresponds to NH2-terminal fragments isolated from other species. The 36K and 61K fragments are derived from a region near the C-terminus of the molecule and appear to be structurally related as demonstrated by two-dimensional peptide maps. A protease-sensitive fragment (Mr 137 000), which binds neither gelatin nor heparin but which has been shown previously to be chemotactic for cells [Postlethwaite, A. E., Keski-Oja, J., Balian, G., & Kang, A. H. (1981) J. Exp. Med. 153, 494-499], separates the NH2-terminal heparin- and gelatin-binding fragments from the C-terminal 36K and 61K heparin-binding fragments. A monoclonal antibody to fibronectin that recognized the 61K heparin-binding fragment was used to isolate a sixth fragment (Mr 34 000) that did not bind to heparin or gelatin and that represents a difference between the 61K and 36K heparin-binding fragments. Cathepsin D digestion produced an 83K heparin-binding, monoclonal antibody reactive fragment that contains the interchain disulfide bond(s) linking the two fibronectin chains at their C-termini. The data indicate that plasma fibronectin is a heterodimeric molecule consisting of two very similar but not identical chains (A and B). In contrast, enzymatic digestion of cellular fibronectin produced a 50K heparin-binding fragment lacking monoclonal antibody reactivity which suggests that the cellular fibronectin subunit is similar to the plasma A chain in enzyme susceptibility but contains a larger heparin-binding domain. A model relating the differences in the three fibronectin polypeptides to differences in published cDNA sequences is presented.     

Decreased interaction of fibronectin, type IV collagen, and heparin due to nonenzymatic glycation. Implications for diabetes mellitus

The nonenzymatic glycation of basement membrane proteins, such as fibronectin and type IV collagen, occurs in diabetes mellitus. These proteins are nonenzymatically glycated in vivo and can also be nonenzymatically glycated in vitro. After 12 days of incubation at 37 degrees C with 500 mM glucose, purified samples of human plasma fibronectin and native type IV collagen showed a 13.0- and 4.2-fold increase, respectively, in glycated amino acid levels in comparison to control samples incubated in the absence of glucose. Gelatin (denatured calfskin collagen) was glycated 22.3-fold under the same conditions. Scatchard analyses were performed on the binding of radiolabeled fibronectin to gelatin or type IV collagen. It was found that there is a 3-fold reduction in the affinity of fibronectin to type IV collagen due to the nonenzymatic glycation of fibronectin. The dissociation constant (KD) for the binding of control fibronectin to type IV collagen was 9.6 X 10(-7) M while the KD for glycated fibronectin and type IV collagen was 2.9 X 10(-6) M. This was similar to the 2.7-fold reduction in the affinity of fibronectin for gelatin found as a result of the nonenzymatic glycation of fibronectin (KD of 4.5 X 10(-7) M for the interaction of control fibronectin with gelatin vs. KD of 1.2 X 10(-6) M for the interaction of nonenzymatically glycated fibronectin with gelatin). The molecular association of control fibronectin or its glycated counterpart with [3H]heparin was also determined. Scatchard analyses of this interaction showed no difference between control fibronectin and glycated fibronectin in [3H]heparin binding.(ABSTRACT TRUNCATED AT 250 WORDS)     

Acylation of gelatin-agarose and the enhancement by heparin of fibronectin binding

The enhancement of the binding of plasma fibronectin to collagen or gelatin by heparin was previously thought to be due primarily to interaction of heparin with fibronectin. We observed, however, that the elution of purified human plasma fibronectin from heparin-treated gelatin-agarose required the same high urea concentrations regardless of whether heparin treatment preceded or followed fibronectin adsorption. Acylation of gelatin-agarose with acetic anhydride or succinic anhydride had little effect upon fibronectin binding, yet the heparin enhancement of fibronectin binding was abolished by either acylation reaction. When heparin binding to gelatin-agarose was investigated with dansyl heparin, gelatin-agarose bound substantial quantities of labeled heparin which could be readily dissociated from the matrix with 2 M NaCl. Acetylated gelatin-agarose did not bind detectable amounts of dansyl heparin. We interpret these results as evidence that the stronger binding of fibronectin to gelatin-agarose in the presence of heparin is due to heparin itself binding to gelatin, thus allowing fibronectin to bind simultaneously to both immobilized ligands through appropriate domains of the glycoprotein.     

Polypeptide heterogeneity of hamster and calf fibronectins.

The adhesive glycoprotein fibronectin has been isolated from fresh hamster plasma by affinity chromatography on gelatin coupled to Sepharose beads by the method of Engvall & Ruoslahti [Int. J. Cancer (1979) 20, 1-5]. Polyacrylamide-gel electrophoresis of material heated in sodium dodecyl sulphate and 2-mercaptoethanol shows two prominent polypeptide subunits of approx. mol.wts. 215 000 and 200 000, with variable amounts of lower-molecular-weight fragments. The unexpected polypeptide heterogeneity of different preparations of hamster fibronectins and bovine serum fibronectin is shown to be partly an artefact and is generated during isolation and storage of purified fibronectin. Treatment of each hamster fibronectin subunit or a smaller fragment of approx. mol.wt. 140 000 with thermolysin or trypsin after radioiodination produces similar patterns of tyrpsine-containing peptides, indicating similar primary amino-acid sequences. Antibodies raised against the major subunits of hamster plasma fibronectin were coupled to Sepharose beads and used in conjunction with gelatin affinity chromatography to isolate fibronectins extracted with urea from baby-hamster kidney (BHK) cells and present in the long-term culture medium of these cells. The cell and medium fibronectins are similar to hamster plasma fibronectin in amino-acid and carbohydrate composition and also produce very similar peptide 'maps'. We conclude that the various forms of hamster fibronectins are structurally analogous in agreement with indistinguishable biological properties in mediating the substance adhesion of BKH cells [Pena & Hughes (1978) Cell Biol. Int. Rep. 3, 339-344].     

Purification of fibronectin using gelatin derivatives

This work compares two distinct methods, column and batch, for the purification of fibronectin, from different plasma fractions, using gelatin and one of its derivates (Hemoce, Behring). The yields of both techniques at quantitative as well as qualitative levels (levels of immunologically active fibronectin), are evaluated. The data indicate that better conservation of immunological immunological characteristics is obtained with the use of gelatin derivatives (Hemoce). The plasma fraction does not have significant influence on the process yields.     

The structure of fibronectin and its role in cellular adhesion

Fibronectin is a large, adhesive glycoprotein which is found in a number of locations, most notably on cell surfaces, in extracellular matrixes, and in blood. Fibronectin has been detected in all vertebrates tested and in many invertebrates. Its presence in sponges is significant because this suggests that fibronectin may have appeared very early in evolution, possibly with the most primitive multicellular organisms. Cellular and plasma fibronectins have many striking similarities. However, the locations of the polypcptide chain differences between these two proteins indicate that plasma fibronectin cannot be derived from cellular fibronectin by means of simple post-translational proteolysis. Instead, these different types of fibronectin may be products of different genes or of differentially spliced messenger RNA molecules. Amniotic fluid fibronectin is possibly a third form of the protein. Cellular and plasma fibronectins are composed of at least six protcaseresistant domains which contain specific binding sites for actin, gelatin, heparin, Staphylococcus aureus, transglutarninase, fibrin, DNA, and a cell surface receptor. The relative locations of these domains have been mapped in the primary structure of fibronectin. The cell surface receptor for fibronectin has not been positively identified, but may be a glycoprotein, a glycolipid, or a complex of the two. Although cell-substratum adhesion is mediated by fibronectin, the locations of the areas of closest approach of the cell to the substratum (the adhesion plaques) and fibronectin are not coincident under conditions of active cell growth. Under conditions of cell growth arrest in low scrum concentrations, some fibronectin may become localized at the adhesion plaques. Models describing the domain structure of fibronectin and the molecular organization of the adhesion plaque area are presented.     

Method for the study of the underside of cultured cell monolayers.

A novel procedure for reversing cell monolayers is described. Cells are embedded in liquid gelatin containing ethylenediaminetetraacetic acid, cooled down to solidify gelatin, and then reversed. The main advantage of this technique is that cells are fixed after reversing so that the extracellular matrix does not obscure the cell surface. No substantial migration of receptors is likely to have taken place judging from the concentration of fibronectin receptor in typical focal or extracellular matrix contacts.     

Plasma fibronectin: three steps to purification and stability.

Large amounts of soluble fibronectin were easily purified from cryoprecipitated or fresh citrated human blood plasma by a three-step combination of gelatin and heparin-cellufine affinity chromatography. The elution conditions were optimized to obtain a homogeneous fraction on SDS-PAGE and Western blot under reducing condition. No proteolytic activities were detected by zymography at acidic or neutral pH. Furthermore, the fibronectin preparation was stable over time up to 456 h at 37 degrees C in the presence of calcium, zinc, or mercury. This preparation of very stable fibronectin, called highly purified fibronectin (hpFN), gave a yield of 7.00 +/- 0.77 mg of fibronectin per gram of cryoprecipitated plasma and 0.16 mg of fibronectin per milliliter of fresh citrated, giving a yield of 32 to 53% (from presumed fibronectin concentration). This preparation may be useful for cellular tests and interaction analysis.     

Deglycosylation of the chymotryptic collagen-binding fragment of human plasma fibronectin does not modify its affinity to denatured collagen

N-Glycanase deglycosylation of purified 44 kDa chymotryptic collagen-binding domain from human plasma fibronectin does not significantly modify its behavior on gelatin affinity chromatography. This indicates that carbohydrates do not play any role in the binding affinity of fibronectin to collagen. The influence of changes in glycosylation on the biological functions of fibronectin is discussed.     

Purification of human plasma fibronectin using immobilized gelatin and Arg affinity chromatography

This protocol describes a method for purification of fibronectin (Fn) from human plasma based on a combination of gel filtration and affinity chromatography steps. Clarified plasma is first loaded onto a Sepharose CL-4B column and unbound material is sequentially purified on columns containing covalently coupled gelatin and Arg. The elution conditions are optimized to obtain a homogeneous preparation of Fn on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE). Although the Fn yield is expected to be lower than that obtained using other methods, affinity adsorbents based on gelatin and Arg and gentle elution steps offer advantages including a high purity of the preparation and a correctly folded protein. The preparation can be useful for interaction studies and analysis of biological and immunological activities of Fn.     

Fibronectin quantification without antibodies: a bioassay for the detection of the gelatin-captured macromolecule

We have developed a new cell-adhesion-bioassay (CAA) for the quantitative determination of fibronectin in biological fluids. The assay is based on two particular properties of fibronectin: it specifically binds to gelatin with high affinity and simultaneously it can anchor to different surface molecules of a cell. First fibronectin, derived from very different biological fluids, is purified in situ, within the wells of the microtiter plates applied for the assay, using solid surface bound gelatin. After capturing the macromolecule, it is quantified based on its cell adhesive properties. In contrast to ELISA the CAA does not require specific antibodies, and as the Jurkat cells used as indicator cells, seem to recognize fibronectin from different species equally; species specificity of the reagent plays smaller, perhaps negligible, role in the determination of the amount of the macromolecule. The CAA method may not replace fibronectin specific ELISA-s, but using its principle, improved applications, for example a capture EIA for determining fibronectin can easily be envisioned and CAA may serve as a viable alternative for EIA-s when specific antibodies are not available or when relative measurement of not only the soluble but cell surface associated fibronectin is necessary.     

Purification of a plant cell wall fibronectin-like adhesion protein involved in plant response to salt stress

The structural role of extracellular-matrix (ECM) has been recognized in both plants and animals as a support and anchorage-inducing cell behavior. Unlike the animal ECM proteins, the proteins that have been identified in plant ECM have not yet been purified from whole plants and cell wall. As several immunological data indicate the presence of animal ECM-like proteins in plants cell wall, especially under salt stress or water deficit, we propose a protocol to purify a fibronectin-like protein from the cell wall of epicotyls of young germinating peas. The process consists of a combination of gelatin and heparin affinity chromatography, close to the classical one used for human blood plasma fibronectin purification. Proteins with affinity for gelatin and heparin, immunologically related to human fibronectin, are found in the cell wall of epicotyls grown under salt stress or not. Total amount of purified proteins is 3-4 times more enriched in salt stressed epicotyls. SDS-PAGE and Western blot with antibodies directed against human blood plasma fibronectin give evidence that the cell wall proteins purified by gelatin/heparin affinity chromatography are closely related to human fibronectin. The present protocol leads us to purify 17 (control) or 65 (salt stress) micrograms of protein per g of fresh starting material. Our results suggest that plant cell wall proteins can provide better anchorage of the cell to its cell-wall during salt stress or water deficit and could be considered not only as cell adhesion but also as signaling molecules.     

Identification of a plasma gelatinase in preparations of fibronectin

Preparations of fibronectin purified from human plasma according to conventional methods was found to contain a latent gelatinolytic activity. The protease was activated by exposure to trypsin or electrophoresis in sodium dodecyl sulfate. Zymography of the enzyme under nonreducing conditions gave an estimated Mr of 72,000. Reducing agents destroyed the activity of the enzyme. The gelatinase co-purified with fibronectin in chromatography on Sepharoses conjugated with gelatin, arginine, and heparin but could be separated from fibronectin by gel filtration in a physiological buffer. This protease was found to be a normal constituent of plasma and was probably not derived from the blood cells since the 72-kDa protease was not detected in lysates of these cells.