Vitronectin exists in two structurally and functionally distinct forms in human plasma

Vitronectin (serum spreading factor, S-protein or epibolin) is a plasma glycoprotein implicated in cell adhesion, as well as in the regulation of complement-mediated cytolysis and antithrombin III function. Vitronectin was found to exist in fresh human plasma as a heterogeneous mixture consisting of 2% heparin-binding form and the remainder as a non-binding species. Heparin-binding vitronectin consisted of 6.5 S aggregates with a Stokes radius of 5.6 nm, which was enriched in the 65 kDa polypeptide, with a high content of molecules and a putative unfolded conformation. In contrast, non-heparin-binding vitronectin was a 4.2 S monomer with a Stokes radius of 3.9 nm, which appeared to be in a folded conformation with an immunologically cryptic site. Both vitronectins displayed similar activities in mediating the spreading of BHK fibroblastic cells on substrates. During blood coagulation, 5% more of the non-heparin-binding vitronectin was converted into the heparin-binding form, producing a greater than 3.5-fold increase in this species. Our results indicate that vitronectin normally exists in circulating blood in at least two structurally and functionally distinct forms which may serve different functions.     

Three types of vitronectin in human blood

Vitronectin is a cell-adhesive glycoprotein in serum and plasma, also termed serum spreading factor and complement S-protein. It consists of a mixture of a polypeptide of molecular weight 75 kilodalton (kDa) and its nicked product of 65 kDa plus 10 kDa. By a quantitative immunoblotting assay, human blood samples could be classified into three distinct vitronectin types; type I (58% of the population) was 75 kDa rich and 65 kDa poor, type II (35% of the population) contained approximately equal amounts of 75 kDa and 65 kDa, and type III (5% of the population) was 75 kDa poor and 65 kDa rich. The vitronectin type did not correlate with age, sex, or ABO blood type.     

The phosphorylation of the two-chain form of vitronectin by protein kinase A is heparin dependent.

In circulating blood, vitronectin occurs in two forms: a single-chain (75 kDa) and an endogenously clipped two-chain form (65 kDa and 10 kDa) held together by a disulfide bridge. The 75 kDa form was previously shown to be phosphorylated at Ser378 by protein kinase A, released by physiologically stimulated platelets. By contrast, at pH 7.5 the two-chain form is not phosphorylated at all. Heparin or heparan sulfate are shown here to modulate the conformation of clipped vitronectin at physiological pH, exposing Ser378 and allowing its stoichiometric phosphorylation by the kinase. At this pH the two-chain form of vitronectin in plasma exhibits a higher affinity for heparin, and behaves as a flexible molecule, which can conformationally respond to heparin and heparan sulfate, effectors involved in vitronectin function.     

Adsorption of vitronectin in human serum onto plastics is augmented by sodium dodecyl sulfate

We have investigated the adsorption of cell-spreading activity in human serum onto polystyrene plates after treatment of the serum with sodium dodecyl sulfate (SDS). Vitronectin in human serum was remarkably adsorbed onto the plate after boiling the serum with 0.1% SDS for 5 min. SDS was effective over the concentration range from 0.05 to 0.25%. Increase of the vitronectin adsorption was accompanied by an increase of cell spreading on the plates. The cell-spreading activity in SDS-treated serum was impeded by anti-vitronectin antibody but not by anti-fibronectin antibody. After treatment with SDS, fibronectin-depleted serum could induce cell spreading but vitronectin-depleted serum could not. These results indicate that vitronectin alone was the cell-spreading factor in SDS-treated human serum. However, SDS-treated pure vitronectin itself did not retain the cell-spreading activity. The activity was recovered when bovine serum albumin was added to pure vitronectin before or after boiling with 0.1% SDS. Therefore, vitronectin adsorbed from SDS-treated serum might retain the cell-spreading activity with the aid of serum protein. Treatment of serum with SDS provides an easy, specific, and efficient method of coating polystyrene plates with vitronectin.     

Immunohistochemical demonstration of vitronectin in association with elastin and amyloid deposits in human kidney

The multifunctional glycoprotein vitronectin, also called serum spreading factor and S-protein of complement, is a potent inducer of cell adhesion and spreading in vitro, and also has a regulatory function in the complement and coagulation pathways. It is present both in plasma and tissue. Recently, vitronectin immunoreactivity was demonstrated in the elastic fibres of normal human skin. Normal and amyloid kidney tissue was investigated for vitronectin immunoreactivity using polyclonal and monoclonal antibodies in an avidin-biotin-peroxidase complex technique and in an alkaline phosphatase anti-alkaline phosphatase complex technique. Vitronectin was found in the elastic layers of normal vessel walls, and in glomerular sclerotic lesions in cases of benign nephrosclerosis, but not in normal glomeruli. Strong specific vitronectin immunoreactivity was found in the amyloid deposits in kidneys from cases with amyloid A type amyloidosis, and in cases with amyloid light chain type amyloidosis. Structures immunostainable with anti-amyloid A antiserum were invariably immunostainable with anti-vitronectin. An antiserum against serum amyloid P component stained the same structures as did the anti-vitronectin antibodies, and in addition stained normal glomerular basement membranes. In conclusion, vitronectin immunoreactivity was demonstrated in elastic tissue, in amyloid deposits and in sclerotic lesions in human kidney.     

Activation of the collagen-binding of endogenous serum vitronectin by heating, urea and glycosaminoglycans.

The present study describes that the collagen-binding activity of vitronectin in human serum increases by treatment with heparin, heating and urea. Vitronectin purified from human serum was bound to native collagen, whereas endogenous vitronectin in the serum was not. We have examined the conditions to change the collagen-binding activity of endogenous vitronectin. Endogenous vitronectin in human serum became considerably bound to collagen when the serum was boiled in 4-8 M urea for 5 min and mixed with heparin (0.5-5 micrograms/ml). Each treatment of heating, urea or heparin alone, and any combination of the two factors, inefficiently activated the binding. Dextran sulfate could substitute for heparin, but dermatan sulfate, keratan sulfate, chondroitin sulfate A and C, heparan sulfate and hyaluronan could not. Possible explanations for the activation of endogenous vitronectin are discussed.     

Identification of the collagen-binding domain of vitronectin using monoclonal antibodies

Vitronectin is a 75 kilodalton (kDa) cell-adhesive glycoprotein found in animal blood and connective tissue, also termed serum spreading factor, S-protein, and epibolin. It promotes attachment and spreading of animal cells on tissue culture dishes, and it also binds to collagen. We established four mouse hybridoma lines producing monoclonal antibodies (M1, M2, M4 and M5) to human vitronectin. By immunoblotting, both epitopes recognized by M4 and M5 were suggested to exist in the amino terminal 5 kDa portion of vitronectin, and both M1 and M2 bound to the adjacent 35 kDa portion. Cell spreading on vitronectin-coated dishes was inhibited by M4 = M5 greater than M1, but not by M2. Collagen binding to vitronectin was inhibited by M2 greater than M4 = M5, but not by M1. These results indicate that the collagen-binding site is located near the cell-binding site in the amino terminal half of vitronectin. Independent inhibition of vitronectin binding to the cell and to collagen by these monoclonal antibodies will provide a potential tool to dissect the structure and function of vitronectin.     

Isolation of plasminogen activator inhibitor-2 (PAI-2) from human placenta. Evidence for vitronectin/PAI-2 complexes in human placenta extract.

Plasminogen activator inhibitor-2 (PAI-2), found in human placenta and pregnancy plasma, was prepared in a highly purified and functionally active form from human placenta. The purification was achieved by a combination of Rivanol and ammonium sulfate precipitation, followed by chromatography on DEAE Affigel Blue, hydroxylapatite and phenylalanine-Sepharose. PAI-2, which is precipitated by low Rivanol concentrations, can be selectively redissolved from the pellet by increasing the Rivanol concentration in the presence of a reducing agent, i.e. dithiothreitol. The purified protein shows a molecular mass of 45 kDa in SDS PAGE, cross-reacts with monoclonal antibodies against PAI-2 (Mab'PAI-2), and inhibits the amidolytic activity of urokinase-type plasminogen activator (u-PA) towards the chromogenic substrate Glu-Gly-Arg-pNA (S-2444). The specific activity of the purified inhibitor was 52,300 units/mg, attaining 71,000 units/mg in peak fractions. In the immunopurification of placental extract on anti-PAI-2 Sepharose, the eluate showed the expected reaction with Mab' PAI-2, and it also cross-reacted with anti-vitronectin serum. In order to complement these results, anti-vitronectin Sepharose was used for immunopurification of placenta extract. In Western Blot experiments the eluates of anti PAI-2 Sepharose and anti-vitronectin Sepharose both showed a heterogeneous pattern of high molecular weight bands recognized by either polyclonal antiserum against vitronectin or Mab'PAI-2. In either case, reduction of the eluates releases mainly a 45-kDa band, which is recognized by Mab'PAI-2, or 80-kDa and 76-kDa bands recognized by anti-serum against vitronectin. These data suggest that the predominant form of PAI-2 in placenta extract is heterogeneous and of high molecular mass, containing complexes in which vitronectin is covalently bound to PAI-2 by disulfide bridges.     

Activation of vitronectin (serum spreading factor) binding of heparin by denaturing agents

Vitronectin (serum spreading factor), a cell-adhesive glycoprotein present in mammalian serum, has previously been the subject of conflicting reports concerning its binding to heparin. Vitronectin purified from human plasma does not bind to heparin under physiological conditions, but it does so after treatment with denaturing agents including 8 M urea or 6 M guanidine-HC1, or heating at 100 degrees C for 5 min. These treatments seem to expose a heparin-binding site in vitronectin; this finding thus resolves the conflicts concerning this function.     

Role of vitronectin in embryonic rat endocardial cell migration in vitro

Summary Vitronectin is one of the extracellular matrices that mediate cell spreading and attachment in vitro. In the present paper, we demonstrate the involvement of vitronectin in the migration of cushion mesenchymal cells of the embryonic rat heart. Immunohistochemistry established the localization of vitronectin in the myocardial cells and in some of the cushion mesenchymal cells of the truncus arteriosus and atrioventricular canal. In vitro, vitronectin, fibronectin, and collagen type-I revcaled significant stimulating activity for cushion mesenchymal cell migration. The distance migrated by cushion mesenchymal cells cultured on vitronectin, collagen type-I, or both vitronectin and fibronectin was similar, but that on fibronectin was significantly shorter. Following the addition of anti-vitronectin IgG to the medium, the migration distance of cushion mesenchymal cells on fibronectin was remarkably increased. Most explants on vitronectin or on both vitronectin and fibronectin became detached from dishes after the addition of the antivitronectin antibody. Immunostaining revealed that cushion mesenchymal cells cultured on substrata other than vitronectin synthesized vitronectin. From these results, it is suggested that vitronectin is synthesized by myocardial cells and some cushion mesenchymal cells, and that vitronectin inhibits cell movement on fibronectin. This feature of vitronectin may be important in the regulation of the migration of cushion mesenchymal cell in vivo.     

Highly sulfated glycosaminoglycans augment the cross-linking of vitronectin by guinea pig liver transglutaminase. Functional studies of the cross-linked vitronectin multimers.

Vitronectin (VN) is an adhesive glycoprotein with roles in the complement, coagulation, and immune systems. Many of the functions of VN are mediated by a glycosaminoglycan binding site, near its carboxyl-terminal end. In this paper, we show that the highly sulfated glycosaminoglycans (GAGs), dextran sulfate, pentosan polysulfate, and fucoidan effectively augment [14C]putrescine incorporation into VN and cross-linking of VN into high molecular multimers by guinea pig liver transglutaminase (TG). Other GAGs including heparin, low molecular weight heparin, dermatan sulfate, keratan sulfate, and the nonsulfated dextrans were ineffective in accelerating these reactions. Dextran sulfate of average molecular mass 500 kDa was more effective than dextran sulfate of average molecular mass 5 kDa, supporting a template mechanism of action of the GAGs, in which VN molecules align on the GAG in a conformation suitable for cross-linking. The VN multimers catalyzed by TG retained functional activity in binding [3H]heparin, platelets, and plasminogen activator inhibitor type-1 (PAI-1). [3H]Heparin bound selectively to the 65-kDa monomeric band of VN and to the multimers derived from this band. PAI-1, however, bound equally to both the 75- and 65-kDa monomeric forms of VN, suggesting that the PAI-1 binding site on VN is distinct from the GAG binding site. The interaction of GAGs with the TG-catalyzed cross-linking of VN may facilitate studies of VN structure-function relationships.     

Bovine ovarian follicular fluid vitronectin content is influenced by the follicle size

Vitronectin was quantified in the follicular fluid aspirated from bovine follicles with diameters of 3 to 15 mm (as determined by ultrasonography) using a specific enzyme-linked immunosorbent assay (ELISA) validated for bovine vitronectin. The primary antibody was raised in rabbit against vitronectin purified from bovine plasma. Vitronectin quantified in serial dilutions of bovine plasma and ovarian follicular fluid was highly correlated with the volume of each sample assayed. In addition, known amounts of purified bovine vitronectin added to samples of plasma or follicular fluid were accurately recovered. Follicular fluid concentrations of vitronectin were positively correlated with the follicle diameter (r = 0.8; P < 0.01). These data indicate that bovine follicular fluid concentration of vitronectin is influenced by the stage of follicular development.     

Polymorphism of the human vitronectin gene causes vitronectin blood type.

Human blood plasma/sera are classified into three distinct vitronectin types based on the relative amount of the 75 kDa polypeptide to its cleavage product of 65 kDa. We asked whether the vitronectin blood types correlated with the polymorphism of the vitronectin gene. A portion of the vitronectin gene was amplified by using polymerase chain reaction and digested with a restriction enzyme PmaC I which may distinguish the base sequence causing the polymorphic change at the amino acid position 381. Amplified DNAs of the blood type I (75 kDa-rich), II (75/65 kDa-even), and III (65 kDa-rich) were shown to be resistant, moderately sensitive and completely sensitive to PmaC I, respectively. These results suggest that Thr at position 381 is essential for the cleavage of the vitronectin 75 kDa polypeptide and that three possible combinations of two codominant alleles of vitronectin determine three vitronectin blood types.     

Certain high molecular weight heparin chains have high affinity for vitronectin.

Vitronectin is a 70-kDa protein that is found in both the extracellular matrix as well as serum. Vitronectin is one of the few proteins that regulates both the complement and the coagulation systems. Heparin is known to bind to vitronectin. Review of the literature reveals apparently conflicting outcomes of the interaction of heparin, vitronectin, and the complement system. Previous studies demonstrated that heparin diminishes vitronectin inhibition of complement activity. Numerous studies have also demonstrated that heparin exerts a net inhibitory effect on complement. We used two dimensional affinity resolution electrophoresis (2DARE) to examine this apparent paradox. 2DARE allowed simultaneous determination of binding affinity of heparin for vitronectin as well as the M(r) of the heparin species. In the 2DARE experiment, the interaction of heparin with vitronectin caused retardation of the movement of the heparin through the tube gel in the first dimension. The degree of the retardation of movement was used to calculate the approximate K(d) of that interaction. The heparin from the tube gel was then subjected to a second dimension electrophoresis to determine the M(r) of the heparin. 2DARE analysis of the interaction of heparin with vitronectin clearly demonstrated that a sub-population of heparin chains with M(r) > 8000 bound vitronectin with high affinity whereas most high M(r) chains and all lower M(r) chains showed little to no affinity for vitronectin. Our findings are consistent with the hypothesis that a unique binding domain exists in certain heparin chains for vitronectin.     

Cyclic AMP-dependent protein kinase phosphorylates serine378 in vitronectin.

We previously observed that Ser378 in the heparin-binding domain of vitronectin becomes phosphorylated by a protein kinase in plasma upon addition of ATP and divalent cations. We now report that purified plasma vitronectin contains approximately 2.5 mol of phosphate per mol of protein and that vitronectin becomes phosphorylated during biosynthesis in human hepatoma (HepG2) cells. In vitro, rabbit muscle cAMP-dependent protein kinase specifically phosphorylates Ser378 in single-chain (75 kDa) vitronectin but does not phosphorylate the two-chain (65/10 kDa) form cleaved at Arg379. Heparin affects neither the time course nor the extent of phosphorylation of Ser378 at neutral pH. The extent of phosphorylation of Ser378 achieved with cAMP-dependent protein kinase (greater than or equal to 0.3 mol phosphate per mol vitronectin) is greater than that obtainable in plasma and should enable comparisons to be made of the activities of the native and phosphorylated forms.     

The presence of methionine or threonine at position 381 in vitronectin is correlated with proteolytic cleavage at arginine 379.

Vitronectin (serum spreading factor, complement S protein, epibolin) is a glycoprotein that mediates cell adhesion and interacts with components of the complement, coagulation, and fibrinolytic systems. It circulates in plasma as a 75-kDa single chain polypeptide and as a two-chain form consisting of 65- and 10-kDa polypeptides linked by a disulfide bond. An individual may have a predominance of the single chain or the two-chain form inherited as a Mendelian trait or have approximately equal amounts of both forms. Inspection of published cDNA sequences suggests that either methionine or threonine can occur at position 381, which is adjacent to the presumed site of proteolytic cleavage (Arg379-Ala380) that gives rise to the two-chain form. We have determined the presence of the Met381 and/or Thr381 alleles of the vitronectin gene in 42 individuals by oligonucleotide hybridization to genomic DNA. To determine whether this polymorphism is correlated with the susceptibility to cleavage of the Arg379-Ala380 peptide bond in vivo, we have prepared immunoblots of plasma from the same group of individuals. Nineteen individuals homozygous for the Thr381 allele had 17 +/- 9% (mean +/- S.D.) single chain vitronectin in their plasma samples. Nine individuals homozygous for the Met381 allele had 66 +/- 4% single chain vitronectin. Fourteen heterozygous individuals had 38 +/- 13% single chain vitronectin. The differences in mean values were statistically significant (p less than 0.001). These results suggest that the presence of threonine rather than methionine at position 381 of vitronectin increases the susceptibility of the protein to cleavage of the Arg379-Ala380 peptide bond in vivo.     

Interaction of vitronectin with collagen

Purified human plasma vitronectin was demonstrated to bind to type I collagen immobilized on plastic as measured by enzyme-linked immunosorbent assay and by binding of 125I-radiolabeled vitronectin to a collagen-coated plastic surface. Vitronectin did not bind to immobilized laminin, fibronectin, or albumin in these assays. Vitronectin showed similar interaction with all types of collagen (I, II, III, IV, V, and VI) tested. Collagen unfolded by heat treatment bound vitronectin less efficiently than native collagen. Vitronectin-coated colloidal gold particles bound to type I collagen fibrils as shown by electron microscopy. Salt concentrations higher than physiological interfered with the binding of vitronectin to collagen, suggesting an ionic interaction between the two proteins. Binding studies conducted in the presence of plasma showed that purified vitronectin added to plasma bound to immobilized collagen, whereas the endogenous plasma vitronectin bound to collagen less well. Although fibronectin did not interfere with the binding of vitronectin to native collagen, vitronectin inhibited the binding of fibronectin to collagen. These results show that vitronectin has a collagen-binding site(s) which, unlike that of fibronectin, preferentially recognizes triple-helical collagen and that the binding between vitronectin and collagen has characteristics compatible with the occurrence of such an interaction in vivo.     

Role of vitronectin-like protein in Agrobacterium attachment and transformation of Arabidopsis cells

The role of plant vitronectin-like protein (Vn) in Agrobacterium-host plant interactions and receptor-specific bacterial attachment is unclear and still open to debate. Using a well-established Agrobacterium-mediated Arabidopsis transformation system, the marker gene beta-glucuronidase (GUS) of Escherichia coli, and biochemical and cytological methods, such as ELISA tests, immunoblots, immunolocalization, and functional in vitro binding assays, we have reassessed the role of Vn in receptor-specific bacterial attachment and transformation. We provide evidence that Vn is present in the host plant cells and anti-human vitronectin antibody cross-reacts with a 65-kDa protein from Arabidopsis cells. The specificity of the immunological cross-reactivity of anti-vitronectin antibodies was further demonstrated by ELISA competition experiments. Immunogold labeling showed that Vn is localized in the plant cell wall, and its level increased considerably after phytohormone treatment of the petiole explants. However, Agrobacterium attachment was unaffected, and no inhibition of petiole cell transformation was detected in the presence of human vitronectin and anti-vitronectin antibodies in the media. Additionally, no correlation between the occurrence of Vn, attachment of bacteria to the cells, and susceptibility to Agrobacterium-mediated transformation was observed. Taken together, our data do not support a functional role of plant Vn as the receptor for site-specific Agrobacterium attachment leading to the transformation of Arabidopsis cells.     

Conformational lability of vitronectin: induction of an antigenic change by alpha-thrombin-serpin complexes and by proteolytically modified thrombin

We previously showed that the alpha-thrombin-antithrombin III complex causes antigenic change in vitronectin as monitored by the monoclonal anti-vitronectin antibody 8E6 (Tomasini & Mosher, 1988). We have extended these studies to other protease-serpin complexes and to gamma-thrombin, a proteolytic derivative of alpha-thrombin. In the presence of heparin, recognition of vitronectin by 8E6 was increased 64- or 52-fold by interaction with the complex of alpha-thrombin and heparin cofactor II or the Pittsburgh mutant (Met358----Arg) of alpha 1-protease inhibitor, respectively. This was comparable to the value obtained with the alpha-thrombin-antithrombin III complex. Factor Xa-serpin complexes were approximately 4-fold less effective than the corresponding thrombin complexes. alpha-Thrombin-serpin complexes but not Xa-serpin complexes formed disulfide-bonded complexes with vitronectin. Antigenic changes and disulfide-bonded complexes were not detected when trypsin- or chymotrypsin-serpin complexes were incubated with vitronectin. gamma-Thrombin caused 7- and 34-fold increases in recognition of vitronectin by MaVN 8E6 in the absence and presence of heparin, respectively. In contrast, alpha-thrombin by itself had no effect. The antigenic change induced by gamma-thrombin was maximal when gamma-thrombin and vitronectin were equimolar, was not dependent on cleavage of vitronectin, and was abolished by inhibition of gamma-thrombin with Phe-Pro-Arg-chloromethyl ketone but not with diisopropyl fluorophosphate. These data indicate that alpha-thrombin is the component in alpha-thrombin-serpin complexes that induces the antigenic change in vitronectin, probably via a region that is preferentially exposed in gamma-thrombin.     

Phosphorylation of vitronectin by a protein kinase in human plasma. Identification of a unique phosphorylation site in the heparin-binding domain

Incubation of human plasma with 27 nM [gamma-32P]ATP in the presence of 20 mM MnCl2 results in the phosphorylation of several proteins detected by sodium dodecyl sulfate-polyacrylamide gel electrophoresis and autoradiography. About 60% of the incorporated radioactivity is found in a 75-kDa protein containing [32P] phosphoserine. The amino-terminal amino acid sequence of the purified 75-kDa [32P]phosphoprotein is identical to that of vitronectin (also termed serum spreading factor or complement S protein). Rabbit antiserum against vitronectin precipitates greater than 90% of the 75-kDa [32P]phosphoprotein from plasma. Reverse phase chromatography of [32P]vitronectin degraded sequentially with CNBr and chymotrypsin yields one major labeled peptide. The sequence of the peptide, Ser-Arg-Arg-Pro-[32PO4]Ser-Arg-Ala-Thr, corresponds to residues 374-381 which are located in the heparin-binding fragment of vitronectin identified by Suzuki et al. [1984) J. Biol. Chem. 259, 15307-15314). Vitronectin could potentially be phosphorylated in vivo with ATP released from injured cells or secreted by platelets activated during hemostasis.