The structure of endothelial cell thrombospondin. Characterization of the heparin-binding domains

The glycoprotein thrombospondin is distributed between the extracellular matrix and the platelet-sequestered pool in the resting state and it undergoes redistribution upon platelet stimulation. It is believed to play a role in matrix structure and in coagulation. We have studied the structural domains of endothelial cell (EC) thrombospondin by use of the serine proteases thrombin, trypsin and chymotrypsin and have characterized the heparin-binding domains of this molecule. For this purpose we used purified thrombospondin synthesized and secreted by bovine aortic endothelial cells grown in the presence of radiolabeled methionine. We find that the susceptibility of EC thrombospondin to proteolysis is five-fold smaller than that of platelet thrombospondin. In the presence of 2 mM Ca ions the molecule is cleaved by 20 U/ml thrombin at a single locus, to yield fragments of 160 kDa and 35 kDa. Trypsin digestion for 5 min at room temperature at an enzyme-to-substrate ratio of 1:20 produces a stable fragment of 140 kDa but not the 30-kDa fragment observed in platelet thrombospondin. Chymotrypsin, under identical conditions to those used for trypsin, cleaves EC thrombospondin into four stable fragments of 160 kDa, 140 kDa, 27 kDa and 18 kDa. Chelation of Ca by EDTA increases susceptibility of the molecule to proteolysis. Under the conditions used a cryptic thrombin-cleavage site, not hitherto observed in platelet thrombospondin, was observed in EC thrombospondin. The location of this site is near a chymotrypsin-susceptible site, which has been observed in the long connecting arm, which is particularly Ca-stabilized. Heparin-binding capacity of EC thrombospondin was observed in at least two separate loci. Both thrombin and chymotrypsin produced small fragments (35 kDa and 27 kDa respectively) which bound to heparin with high affinity, and large fragments (160 kDa for thrombin and 140 kDa for chymotrypsin) which had low affinity. Chelation of Ca substantially decreased the low-affinity binding of the large fragments but not the high-affinity binding of the small fragments. Two-dimensional gel electrophoresis of the chymotryptic heparin-binding fragments shows that each molecule gave rise to a heterogeneous array of fragments of high molecular mass bound by disulfide bonds, indicating that there is a difference in the rate of cleavage between the three subunits of EC thrombospondin. Trypsin, despite its limited degradation, completely eliminated the heparin-binding capacity of both high and low-affinity loci, in contrast to platelet thrombospondin where the high affinity remains intact.(ABSTRACT TRUNCATED AT 400 WORDS)     

Primary structure of the heparin-binding site of type V collagen

The abilities of collagens, type I, II, III, IV, and V, to bind heparin were examined by heparin-affinity chromatography and binding studies with [35S]heparin. At a physiological pH and ionic strength, only type V collagen bound to heparin. Collagens type I and II showed higher affinities than types III and IV for heparin, but did not bind to a heparin column at a physiological ionic strength. The heparin binding site of type V collagen was located in a 30 kDa CNBr fragment of the alpha 1(V) chain, and the amino acid sequence of this fragment was determined. The 30 kDa fragment contained a cluster of basic amino acid residues, and enzymatic cleavage within this basic domain greatly reduced the heparin-binding activities of the resulting peptides. Thus this basic region is probably the heparin-binding site of type V collagen.     

Evidence that binding to the carboxyl-terminal heparin-binding domain (Hep II) dominates the interaction between plasma fibronectin and heparin

We assessed the participation of the three known heparin-binding domains of PFn (Hep I, Hep II, Hep III) in their interaction with heparin by making a quantitative comparison of the fluid-phase heparin affinities of PFn and PFn fragments under physiologic pH and ionic strength conditions. Using a fluorescence polarization binding assay that employed a PFn affinity-purified fluorescein-labeled heparin preparation, we found that greater than 98% of the total PFn heparin-binding sites exhibit a Kd in the 118-217 nM range. We also identified a minor (less than 2%) class of binding sites exhibiting very high affinity (Kd approximately 1 nM) in PFn and the carboxyl-terminal 190/170 and 150/136 kDa PFn fragments. This latter activity probably reflects multivalent inter- or intramolecular heparin-binding activity. Amino-terminal PFn fragments containing Hep I (72 and 29 kDa) exhibited low affinity for heparin under physiologic buffer conditions (Kd approximately 30,000 mM). PFn fragments (190/170 and 150/136 kDa) containing both the carboxyl-terminal Hep II and central Hep III domains retained most of the heparin-binding activity of native PFn (Kd = 278-492 nM). The isolated Hep II domain (33-kDa fragment) exhibited appreciable, but somewhat lower (2-5-fold), heparin affinity compared to the 190/170-kDa PFn fragment. Heparin binding to the 100-kDa PFn fragment containing Hep III was barely detectable (Kd greater than 30,000 nM). From these observations, we conclude that PFn contains only one major functional heparin-binding site per subunit, Hep II, that dominates the interaction between heparin and PFn.     

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.     

Cloning and functional characterization of an NAD(+)-dependent DNA ligase from Staphylococcus aureus

A Staphylococcus aureus mutant conditionally defective in DNA ligase was identified by isolation of complementing plasmid clones that encode the S. aureus ligA gene. Orthologues of the putative S. aureus NAD(+)-dependent DNA ligase could be identified in the genomes of Bacillus stearothermophilus and other gram-positive bacteria and confirmed the presence of four conserved amino acid motifs, including motif I, KXDG with lysine 112, which is believed to be the proposed site of adenylation. DNA sequence comparison of the ligA genes from wild type and temperature-sensitive S. aureus strain NT64 identified a single base alteration that is predicted to result in the amino acid substitution E46G. The S. aureus ligA gene was cloned and overexpressed in Escherichia coli, and the enzyme was purified to near homogeneity. NAD(+)-dependent DNA ligase activity was demonstrated with the purified enzyme by measuring ligation of (32)P-labeled 30-mer and 29-mer oligonucleotides annealed to a complementary strand of DNA. Limited proteolysis of purified S. aureus DNA ligase by thermolysin produced products with apparent molecular masses of 40, 22, and 21 kDa. The fragments were purified and characterized by N-terminal sequencing and mass analysis. The N-terminal fragment (40 kDa) was found to be fully adenylated. A fragment from residues 1 to 315 was expressed as a His-tagged fusion in E. coli and purified for functional analysis. Following deadenylation with nicotinamide mononucleotide, the purified fragment could self-adenylate but lacked detectable DNA binding activity. The 21- and 22-kDa C-terminal fragments, which lacked the last 76 amino acids of the DNA ligase, had no adenylation activity or DNA binding activity. The intact 30-kDa C terminus of the S. aureus LigA protein expressed in E. coli did demonstrate DNA binding activity. These observations suggest that, as in the case with the NAD(+)-dependent DNA ligase from B. stearothermophilus, two independent functional domains exist in S. aureus DNA ligase, consisting of separate adenylation and DNA binding activities. They also demonstrate a role for the extreme C terminus of the ligase in DNA binding. As there is much evidence to suggest that DNA ligase is essential for bacterial survival, its discovery in the important human pathogen S. aureus indicates its potential as a broad-spectrum antibacterial target for the identification of novel antibiotics.     

Identification of functional domains of the extrinsic 12 kDa protein in red algal PSII by limited rroteolysis and directed mutagenesis.

The extrinsic 12 kDa protein in red algal photosystem II (PSII) functions to minimize the chloride and calcium requirement of oxygen-evolving activity [Enami et al. (1998) Biochemistry 37: 2787]. In order to identify functional domains of the 12 kDa protein, we prepared the 12 kDa protein lacking N-terminal peptides or C-terminal peptides or both by limited proteolysis and directed mutagenesis. The resulting 12 kDa protein fragments were examined for their binding and functional properties by reconstitution experiments. (1) A peptide fragment from Gly-6 to C-terminus of the 12 kDa protein was prepared by V8 protease. This fragment rebound to PSII completely, and it reactivated oxygen evolution partially in the absence of Cl(-) and Ca(2+) ions but significantly in the presence of Cl(-) ion. (2) A peptide from Leu-10 to Phe-83 was obtained by chymotrypsin treatment. This peptide rebound to PSII effectively, but the rebinding did not restore oxygen evolution in both the absence and presence of Cl(-) and Ca(2+) ions. (3) Two mutant proteins, one lacking five residues and the other lacking nine residues of the N-terminus, were able to bind to PSII effectively. Recovery of oxygen evolution by their binding was almost the same as that reconstituted with the V8 protease-treated peptide. (4) Three mutant proteins lacking ten, seven or three residues of the C-terminus effectively rebound to PSII, but their binding did not result in recovery of the oxygen evolution. In contrast, reconstitution with a mutant protein lacking one residue of the C-terminus showed the same high restoration of oxygen evolution as reconstitution with the full-length 12 kDa protein. (5) These results indicate that two residues from lysine of the C-terminus of the 12 kDa protein constitute an important domain for minimizing the chloride and calcium requirement of oxygen evolution. In addition, the N-terminus of the protein, at least five residues, has a secondary function for the chloride requirement.     

Human apolipoprotein B-100 heparin-binding sites

Seven distinct heparin-binding sites have been demonstrated on human apolipoprotein (apo) B-100 by using a combination of digestion with cyanogen bromide or Staphylococcus aureus V-8 protease and heparin-Sepharose affinity chromatography. Based on fragment analysis, the approximate boundaries of the seven binding sites are as follows: site A, residues 5-99; site B, residues 205-279; site C, residues 875-932; site D, residues 2016-2151; site E, residues 3134-3209; site F, 3356-3489; and site G, residues 3659-3719. In sites E and F, two short regions enriched in basic amino acids have been identified, and it is likely that they are responsible for a major portion of the heparin-binding properties of these sites. The relative binding affinity of each of the seven sites was estimated in two ways. First, the affinity was assessed in a ligand blot assay using a 125I-labeled high-reactive heparin subfraction. Second, apoB-100 fragments generated by cyanogen bromide or S. aureus V-8 protease were separated into low- and high-affinity fractions by gradient salt elution of a heparin-Sepharose column. The distribution of the seven binding sites in the two fractions was determined in an immunoblotting assay using antibodies specific to each site, i.e. antibodies raised against synthetic peptide sequences found within each of the seven sites. The results of these two approaches demonstrate that site E and, to a somewhat lesser extent, site F bind to heparin with the highest affinity. Based on the analogy with apoE, in which the high-affinity heparin-binding site coincides with the domain of the protein that interacts with apoB,E (low density lipoprotein) receptors, the results of this study indicate that site E and site F, either singly or in combination, might constitute the receptor binding domain of apoB-100.     

Structural analysis of rod GTP-binding protein, Gt. Limited proteolytic digestion pattern of Gt with four proteases defines monoclonal antibody epitope.

The epitope of monoclonal antibody (mAb 4A), which recognizes the alpha subunit of the rod G protein, Gt, has been suggested to be both at the carboxyl terminus (Deretic, D., and Hamm, H.E. (1987) J. Biol. Chem. 262, 10839-10847) and the amino terminus (Navon, S.E., and Fung, B.K.-K. (1988) J. Biol. Chem. 263, 489-496) of the molecule. To characterize further the mAb 4A binding site on alpha t and to resolve the discrepancy between these results limited proteolytic digestion of Gt or alpha t using four proteases with different substrate specificities has been performed. Endoproteinase Arg-C, which cleaves the peptide bond at the carboxylic side of arginine residues, cleaved the majority of alpha t into two fragments of 34 and 5 kDa. The alpha t 34-kDa fragment in the holoprotein, but not alpha t-guanosine 5'-O-(3-thiotriphosphate), was converted further to a 23-kDa fragment. A small fraction of alpha t-GDP was cleaved into 23- and 15-kDa fragments. Endoproteinase Lys-C, which selectively cleaves at lysine residues, progressively removed 17 and then 8 residues from the amino terminus, forming 38- and 36-kDa fragments. Staphylococcus aureus V8 protease is known to remove 21 amino acid residues from the amino-terminal region of alpha t, with the formation of a 38-kDa fragment. L-1-Tosylamido-2-phenylethyl chloromethyl ketone-treated trypsin cleaved alpha t progressively into fragments of known amino acid sequences (38, then 32 and 5, then 21 and 12 kDa) and a transient 34 kDa fragment. The binding of mAb 4A to proteolytic fragments was analyzed by Western blot and immunoprecipitation. The major fragments recognized by mAb 4A on Western blots were the 34- and 23-kDa fragments obtained by endoproteinase Arg-C and tryptic digestion. Under conditions that allowed sequencing of the 15- and 5-kDa fragments neither the 34- nor the 23-kDa fragments could be sequenced by Edman degradation, indicating that they contained a blocked amino terminus. The smallest fragment that retained mAb 4A binding was the 23-kDa fragment containing Met1 to Arg204. Thus the main portion of the mAb 4A antigenic site was located within this fragment, indicating that the carboxyl-terminal residues from Lys205 to Phe350 were not required for recognition by the antibody. Additionally, the antibody did not bind the 38- and 36-kDa or other fragments containing the carboxyl terminus, showing that the amino-terminal residues from Met1 to Lys17 were essential for antibody binding to alpha t.     

Identification of second arginine‐glycine‐aspartic acid motif of ovine vitronectin as the complement C9 binding site and its implication in bacterial infection

Vitronectin (Vn), a multifunctional protein of blood and extracellular matrix, interacts with complement C9. This interaction may modulate innate immunity. Details of Vn–C9 interactions are limited. Vn–C9 interactions were assessed by employing a goat homologous system and observing Vn binding to C9 in three different assays. Using recombinant fragments, C9 binding was mapped to the N‐terminus of Vn. Site directed mutagenesis was performed to alter the second arginine glycine aspartic acid (RGD) sequence (RGD‐2) of Vn. Changing R to G or D to A in RGD‐2 caused significant decrease in Vn binding to C9 whereas changing of R to G in the first RGD motif (RGD‐1) had no effect on Vn binding to C9. These results imply that the RGD‐2 of goat Vn is involved in C9 binding. In a competitive binding assay, the presence of soluble RGD peptide inhibited Vn binding to C9 whereas heparin had no effect. Vn binding to C9 was also evaluated in terms of bacterial pathogenesis. Serum dependent inhibition of Escherichia coli growth was significantly reverted when Vn or its N‐fragment were included in the assay. The C‐fragment, which did not support C9 binding, also partly nullified serum‐dependent inhibition of bacterial growth, probably through other serum component(s).     

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.     

Fibulin binds to itself and to the carboxyl-terminal heparin-binding region of fibronectin.

Fibulin is a recently described extracellular matrix (ECM) and plasma glycoprotein (Argraves, W. S., Tran, H., Burgess, W. H., and Dickerson, K. (1990) J. Cell Biol. 111, 3155-3164). In this report, ligand affinity chromatography and solid-phase binding analyses were performed to determine which ECM protein(s) interact with fibulin. Fibulin-Sepharose bound two polypeptides of 240 and 100 kDa from the culture medium of metabolically radiolabeled fibroblasts. These two proteins were identified as fibronectin (FN) and fibulin, respectively, based on their electrophoretic behavior and reactivity with monoclonal antibodies. Consistent with the findings of affinity chromatography, fibulin bound to surfaces coated with FN (either plasma or cellular form) or fibulin but not with other ECM proteins, such as laminin, merosin, and types I and IV collagen. The binding of fibulin to solid-phase FN was estimated to have a Kd of 139 nM, whereas the Kd for self-interaction was 322 nM. Evaluation of proteolytic fragments from all regions of FN allowed a fibulin-binding site to be localized within a 23-kDa heparin-binding fragment containing type III repeats 13-14. Heparin did not compete for the interaction between fibulin and FN, suggesting that the binding sites for fibulin and heparin are distinct.     

Multiple binding sites in fibronectin and the staphylococcal fibronectin receptor.

The binding of fibronectin to Staphylococci exhibits the properties of a ligand-receptor interaction and has been proposed to mediate bacterial adherence to host tissues. To localize staphylococcal-binding sites in fibronectin, the protein was subjected to limited proteolysis and, of the generated fragments, Staphylococci appeared to preferentially bind to the N-terminal fragment. Different fibronectin fragments were isolated and tested for their ability to inhibit 125I-fibronectin binding to Staphylococci. The results indicate that only the N-terminal region effectively competed for fibronectin binding. However, when isolated fragments were adsorbed to microtiter wells, we found that two distinct domains, corresponding to the N-terminal fragment and to the heparin-binding peptide mapping close to the C-terminal end of fibronectin, promoted the attachment of both Staphylococcus aureus Newman and coagulase-negative strain of Staphylococcus capitis 651. These same domains were recognized by purified 125I-labeled staphylococcal receptor, either when immobilized on microtiter wells or probed after adsorption onto nitrocellulose membrane. The heparin-binding domain is comprised of type-III-homology repeats 14, 15 and 16. To determine which repeats participate in this interaction, we isolated and tested repeats type III14 and type III16. We found that the major staphylococcal binding site is located in repeat type III14. The staphylococcal receptor bound the N-terminal domain of fibronectin with a KD of 1.8 nM, whereas the dissociation constant of the receptor molecule for the internal heparin-binding domain was 10 nM. Since the fusion protein ZZ-FR, which contains the active sequences of fibronectin receptor (D1-D3) bound only to the N-terminus, it is reasonable to assume that the bacterial receptor may have additional binding sites outside the D domains, capable of interacting with the internal heparin-binding domain of 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.     

Localization of azidophencyclidine-binding site on the nicotinic acetylcholine receptor alpha-subunit

Nicotinic acetylcholine receptors in receptor-rich membranes from Torpedo californica and from T. marmorata electric tissue were photolabeled with the non-competitive inhibitor [3H]azidophencyclidine. The receptor subunits were separated on SDS-polyacrylamide gels and the alpha-subunits recovered from the gel, were subjected to Staphylococcus aureus V8 protease cleavage. The proteolytic fragments were resolved by SDS-polyacrylamide gel electrophoresis and were identified on protein blots by 125I-labeled alpha-bungarotoxin binding and by staining with concanavalin A. The site of specific azidophencyclidine labeling has been localized to the V8-18 kDa fragment which binds toxin. Labeling of the V8-18 kDa fragment was observed in the absence and in the presence of carbamylcholine. This was found for both the species of Torpedo used here.     

The protein S-binding site localized to the central core of C4b-binding protein

Human C4b-binding protein (C4BP) is a regulator of the classical pathway of the complement system. It appears in two forms in plasma, as free protein and in a noncovalent complex with the vitamin K-dependent coagulation protein, protein S. In the electron microscope C4BP has a spider-like structure with a central core and seven extended tentacles, each of which has a binding site for C4b, although the protein S-binding site has not been unequivocally pinpointed. C4BP was subjected to chymotrypsin digestion which yielded two major fragments, one of 160 kDa representing the central core, and one of 48 kDa representing the cleaved-off tentacles. We have now localized the protein S-binding site to the 160-kDa central core fragment. Using immunoblotting with a panel of polyclonal antisera, the isolated central core was shown to be completely devoid of 48-kDa fragments. The protein S-binding site was susceptible to proteolysis by chymotrypsin, but was protected by a molar excess of protein S included during the proteolysis. The 160-kDa central core fragment consisted of identical, disulfide-linked 25-kDa peptides and a proper disulfide bond arrangement was crucial to protein S binding. Using a direct binding assay it was shown that the isolated central core had the same affinity for protein S as intact C4BP.     

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.     

Hydrophobic properties of porcine fibronectin and its functional domains

The relations between surface hydrophobicities and binding properties of the functional domains of porcine plasma fibronectin were investigated. Porcine plasma fibronectin as well as human plasma fibronectin was adsorbed on a hydrophobic column with butyl or phenyl ligands in the presence of 0.5 M ammonium sulfate, and recovered in a single peak by decreasing the concentration of ammonium sulfate to 0 M, indicating that both fibronectins have very high surface hydrophobicities. On digestion with thermolysin, porcine plasma fibronectin yielded five fragments (140-150, 43, 25, 17, and 14 kDa) similar to those reported for human fibronectin, although porcine fibronectin was more resistant to the digestion than human fibronectin. The three heparin-binding fragments were found to have a wide range of surface hydrophobicities, the 140-150 kDa fragment having the lowest, the 25 kDa fragment a higher, and the 14 kDa fragment the highest among all the fragments. The 43 kDa collagen-binding and 17 kDa fragments had surface hydrophobicities as high as that of fibronectin. It is noteworthy that the 43 kDa collagen-binding fragment contributes to the high surface hydrophobicity of intact fibronectin in spite of the high content of carbohydrates.     

Evidence that type 1 plasminogen activator inhibitor binds to the somatomedin B domain of vitronectin.

The interaction between type 1 plasminogen activator inhibitor (PAI-1) and fragments of vitronectin (Vn) was investigated. The PAI-1-binding domain was not destroyed when Vn was cleaved by treatment with either acid or CNBr. Acid-cleaved Vn was fractionated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and analyzed by PAI-1 ligand binding. The smallest fragment (Mr 40,000) that retained PAI-1 binding function was sequenced and shown to contain the NH2 terminus of the molecule. Further cleavage of this fragment by treatment with CNBr generated a Mr 35,000 fragment (Pro52-Asp239) that did not interact with PAI-1, and a Mr 6,000 NH2-terminal fragment (Asp1-Met51) that spanned the somatomedin B domain and contained the RGD (cell binding) sequence. The purified Mr 6,000 fragment competed with immobilized Vn for PAI-1 binding, and formed complexes with activated PAI-1. These complexes could be immunoprecipitated by antibodies to PAI-1. Synthetic peptides containing the RGD sequence had no effect on the binding of this fragment to PAI-1. These results suggest that the cell-binding and PAI-1 binding sequences of Vn occupy distinct regions in the NH2-terminal somatomedin B domain of the molecule.     

Fibronectin fibril formation involves cell interactions with two fibronectin domains

Fibronectin fragments and domain-specific antibodies have been used to study the mechanism by which cells reorganize exogenous fibronectin substrata into fibrils. Fibroblasts prevented from protein synthesis, and hence not secreting endogenous fibronectin or other matrix components, reorganized exogenous fibronectin substrata into arrays resembling the matrix of normally cultured cells. Cells also formed fibrils from substrata containing mixtures of cell- and either of two different heparin-binding fibronectin fragments but not from either fragment alone. The gelatin-binding fragment alone or in conjunction with the cell-binding fragment did not promote fibril formation. Antibodies recognizing cell- and either heparin- or the gelatin-binding domains labeled fibrils formed by cells under normal culture conditions or when a substratum of intact fibronectin was used as the sole exogenous source. However, only antibodies recognizing the cell- or either heparin-binding fragment reduced fibrillogenesis from intact fibronectin substrates when added during cell spreading. These data suggest that formation of fibronectin fibrils can occur at the cell surface and that membrane components recognizing the cell- and the heparin-binding domains in fibronectin may cooperate in the assembly process     

Fibronectin's amino-terminal matrix assembly site is located within the 29-kDa amino-terminal domain containing five type I repeats

Fibronectin is organized into disulfide cross-linked, insoluble pericellular matrix fibrils by fibroblasts in vitro. Two sites, the Arg-Gly-Asp-Ser-containing cell attachment domain and a site located in the first 70 kDa of fibronectin, are required for matrix assembly. The first 70 kDa of fibronectin contain two structural motifs termed type I and type II homologies, which are repeated nine and two times, respectively. Previous work has implicated the amino-terminal region and the carboxyl terminus containing three type I repeats in matrix assembly, suggesting that type I repeats possess binding activity essential for fibronectin matrix assembly. To test this hypothesis, we developed a sensitive capture immunoassay to quantify insoluble matrix fibronectin and tested a panel of fibronectin fragments, containing all of the type I repeats found in the intact protein, for their ability to inhibit matrix assembly. Only fragments containing the first five type I repeats inhibited fibronectin matrix assembly, although sequences carboxyl-terminal to this domain enhanced this activity. Additional evidence for the specific recognition of the amino-terminal type I repeats by matrix assembling cells was found when the reversible, detergent-sensitive binding of a 125I-labeled fragment containing the first five type I repeats (29 kDa) to cell monolayers was studied. Only monolayers of cell lines that incorporate fibronectin into a fibrillar matrix specifically bound 125I-labeled 29 kDa. Binding of the radiolabeled amino-terminal fragment to matrix-forming cells was inhibited by unlabeled fragments containing the first five type I repeats but not by unlabeled fragments containing the remaining seven type I repeats. Matrix assembly is therefore not a generalized property of type I repeats. Rather, a critical site is located within the first 29 kDa of fibronectin.