Interspecies cross-reactivity of monoclonal antibodies to various epitopes of human plasminogen

The immunological cross-reactivities of three conformationally specific monoclonal antibodies to distinct epitopes on human plasminogen toward plasminogens purified from 14 additional species have been examined. Antibody 10-F-1, which is produced against an epitope on the kringle 4 region of human plasminogen, shows a high degree (greater than 80%) of cross-reactivity against baboon, goat, monkey, ovine, and rabbit plasminogens; more limited (20-50%) cross-reactivity against bovine, equine, goose, guinea pig, mouse, rat, and porcine plasminogens; and little comparable cross-reactivity against canine and chicken plasminogens. Antibody 10-H-2, generated to an epitope of the kringles 1-3 region of human plasminogen, shows extensive cross-reactivity (72%) only toward monkey plasminogen, more limited (22-35%) cross-reactivity toward equine and rabbit plasminogens, and much less cross-reactivity toward any other of the above plasminogens. Antibody 10-V-1, also produced against an epitope on the kringle 1-3 region of human plasminogen, which is distinct from the 10-H-2 epitope, shows extensive cross-reactivity (72-100%) with baboon, monkey, and rabbit plasminogens; more limited cross-reactivity with equine (48%) and mouse (28%) plasminogens; and a low level of such reactivity with the remaining plasminogens. These studies show that the extent of interspecies cross-reactivity of various plasminogens greatly depends upon the epitope in question. The K4 region of these molecules appears more extensively conserved than the K1-3 region, at least in regard to the particular epitopes examined in this study.     

Plasminogen binding with decapeptide and polypeptide fragments of streptokinase

The plasminogen binding with streptokinase decapeptides, modeling the primary structure of molecule, and chymotryptic fragments of streptokinase have been investigated. The immunoenzymatic assay has shown that plasminogen binds to all streptokinase fragments with the decreasing affinity in the set of fragments: 36 > 30 > 17 > 7 > 11 kDa. Location of the binding sites in streptokinase primary structure was performed using the immobilized decapeptides on plastic pins adopted to IEA. In the presence of 10 mM 6-aminohexanoic acid 11 sites for human Glu- and mini-plasminogens, pig and bovine plasminogens binding have been found. They were of the same location for human, bovine and pig plasminogens. 3 sites were located in plasminogen alpha-domain--T43-A72, N113-T126, Q133-V158, 5 sites in beta-domain--T163-L188, A203-S222, Q239-I264, Y275-L294, T315-L340, and 3 sites in gamma-domain--T361-R362, N377-E392, T397-N410. Participation of linear part of streptokinase polypeptide chain in plasminogen--streptokinase complex formation is suggested.     

Plasminogens Tochigi II and Nagoya: two additional molecular defects with Ala-600----Thr replacement found in plasmin light chain variants

Previous studies in our laboratories (Miyata, T., et al. (1982) Proc. Natl. Acad. Sci. U.S. 79, 6132-6136) showed that the structural defect in a hereditarily abnormal plasminogen, plasminogen Tochigi, is due to replacement of Ala by Thr at position 600 from the NH2-terminal end. In the present studies, two abnormal plasminogens, plasminogens Tochigi II and Nagoya, obtained from other family members were analyzed to identify the structural impairment in these molecules. Amino acid sequence analysis of one of the tryptic peptides isolated, respectively, from plasminogens Tochigi II and Nagoya indicated that in both cases, Ala-600 (equivalent to Ala-55 of the chymotrypsin numbering system) had been replaced by Thr. No other substitutions at the active site and substrate-binding site residues, namely, His-57, Asp-102, Ser-195, and Asp-189, were found in the plasmin light chain variants, indicating that all these residues are intact. Moreover, the NH2-terminal heptapeptide sequences of the plasmin light chain variants isolated from plasminogens Tochigi II and Nagoya were identical to the sequence determined for the normal control. These results indicate that the absence of proteolytic activity of both abnormal molecules is due to the same amino acid substitution as that of previously reported plasminogen Tochigi.     

The AH-site of plasminogen and two C-terminal fragments. A weak lysine-binding site preferring ligands not carrying a free carboxylate function.

Glu-plasminogen [native plasminogen (Glu-1-Asn-790)], Lys-plasminogen [plasmin-cleaved fragment of plasminogen (Lys-77-Asn-790)] and miniplasminogen [fragment of plasminogen (Val-440-Asn-790)] were all found to interact specifically with immobilized 6-aminohexyl ligands. The interactions apparently are mediated by a single weak lysine-binding site, termed the AH-site, as seen from the patterns of inhibition obtained from frontal-quantitative-affinity-chromatography experiments with 6-aminohexanoic acid and alpha-N-acetyl-L-lysine methyl ester as competing ligands. The AH-site, in contrast with the strong lysine-binding site of Glu-plasminogen and Lys-plasminogen, may prefer ligands not carrying a free carboxylate function and therefore may interact with lysine side chains of proteins. In Glu-plasminogen the AH-site is present, but is apparently only partially free to react. It is suggested that it participates in an intramolecular complex and that an equilibrium state between two Glu-plasminogen forms exists. It is further suggested that binding of the plasminogens to fibrin is mainly determined by the AH-site.     

Isolation and characterization of native and lower molecular weight forms of sheep plasminogen.

Two major forms of native sheep plasminogen (SPg-a) have been isolated from plasma by affinity chromatography. These forms differ in molecular weight, charge characteristics, affinity for epsilon-aminocaproic acid (epsilon-Ahx), and carbohydrate content. Upon treatment of SPg-a with plasmin, lower molecular weight plasminogens can be isolated. A plasminogen (SPg-b) of molecular weight approximately 8,000 less than native plasminogen is rapidly produced when either major plasminogen form is treated with plasmin. The molecular weight differences found in the major SPg-a forms are retained in the SPg-b forms, derived from each SPg-a. Upon protracted treatment of either major form of SPg-a or SPg-b with plasmin, a plasminogen (SPg-c) or molecular weight approximately 32,000 less than SPg-b is produced. A single peptide (P) is also produced in this step. The SPg-c species produced from each original SPg-a major form possess essentially the same molecular weights and carbohydrate compositions; but the P cleaved retains the molecular weight and carbohydrate differences found in each major SPg-a or SPg-b form. A large decrease in the S20,w of SPg-a is observed upon the binding of epsilon-Ahx to this protein. A much smaller alteration in the S20,w of SPg-b and SPg-c is observed upon binding of epsilon-Ahx to these proteins.     

Characterization of the cDNA coding for mouse plasminogen and localization of the gene to mouse chromosome 17

A full-length cDNA coding for mouse plasminogen has been isolated and characterized. The cDNA is 2720 bp in length (excluding the poly(A) tail) and contains a 24-bp 5' noncoding region, an open reading frame of 2436 bp, and a 3' noncoding region of 257 bp. The open reading frame codes for 812 amino acids and includes a signal peptide that is likely 19 amino acids in length and the mature protein of 793 amino acids. The calculated Mr of mouse plasminogen is 88,706 excluding carbohydrate. There are two potential N-linked carbohydrate addition sites; one of which is glycosylated in human, bovine, and porcine plasminogens. Mouse plasminogen was found to contain two additional amino acids compared to the human protein. In addition, mouse and human plasminogens were found to be 79 and 76% identical at the protein and DNA levels, respectively. Analysis of the segregation of two allelic forms, Plgb and Plgd, of plasminogen DNA in three sets of recombinant inbred strains has allowed the localization of the mouse plasminogen gene to the proximal end of mouse chromosome 17 within the t complex and close to the locus D17Rp17. The Plg gene is deleted in the semidominant deletion mutant, hair-pintail (Thp).     

Measurement of the binding of antifibrinolytic amino acids to various plasminogens

A method for studying the binding of various antifibrinolytic amino acids to plasminogen has been devised. This method is based upon the ability of inhibitors of the streptokinase-induced conversion of plasminogen to plasmin to produce an alteration in the s_20,w⁰ of native plasminogen accompanying their binding to plasminogen. Typical examples of antifibrinolytic amino acids, e.g., 6-amino hexanoic acid, trans-4-aminomethyl cyclohexane-1-carboxylic acid, and l-lysine cause alterations in the s_20,w⁰ of streptokinase-insensitive plasminogens as well as streptokinase-sensitive plasminogens from 5.1–5.6 S to 4.1–4.7 S depending upon the particular plasminogen used. Titration of the s_20,w⁰ of human plasminogen (streptokinase-sensitive) using absorption optics in the analytical ultracentrifuge with the above three compounds led to dissociation constants of 4.5 ± 0.8 × 10⁻⁴m, 8.0 ± 0.8 × 10⁻⁵m, and 6.8 ± 0.8 × 10⁻²m, respectively. When duck plasminogen (streptokinase-insensitive) was used, dissociation constants of 5.6 ± 0.7 × 10⁻⁴m, 9.0 ± 0.8 × 10⁻⁵m, and 8.8 ± 0.7 × 10⁻²m, were obtained.     

Identification of the rat Heymann nephritis autoantigen (GP330) as a receptor site for plasminogen.

Previous results have demonstrated the binding of a 76- and 80-kDa serum protein to the Heymann nephritis autoantigen, gp330. This 76-kDa serum protein was purified by column chromatography and preparative sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A rabbit polyclonal antibody for the serum protein was produced and used to screen a rat liver cDNA expression library. Sequence analysis of an isolated clone identified the serum protein as plasminogen. Plasminogen was isolated from rat serum by standard techniques, and the binding of plasminogen to gp330 was confirmed by Western analysis. Enzyme-linked immunosorbent assay results demonstrated a time-dependent, saturable, and specifically inhibitable binding of plasminogen to gp330. There was no significant difference in the binding of the two carbohydrate forms of plasminogen to gp330. Plasminogen binding to gp330 could be completely inhibited by the addition of exogenous gp330. This binding could also be partially inhibited by benzamidine but only slightly by the lysine analogue, epsilon-aminocaproic acid. However, even a combination of these two inhibitors could not completely block the binding of plasminogen to gp330 indicating that gp330 may be binding to plasminogen through some other unknown interactions. These results demonstrate that gp330 is a receptor site for plasminogen.     

Conformation ability test of human, rabbit and bovine plasminogens and their specific interaction with streptokinase.

Human, rabbit and bovine plasminogens, having different sensitivity to streptokinase-activating action, differ, according to spectrophotometric titration, tryptophan fluorescence and circular dichroism spectroscopy, in the state of tyrosine and tryptophan residues, and in secondary and tertiary structures. Human plasminogen-streptokinase equimolar complex formation (according to gel chromatography) is accompanied by a differential ultraviolet spectrum. Difference spectroscopy is a convenient and adequate means of studying the formation of the said complexes. Streptokinase-human plasminogen complex formation is not hindered by partial substitution of water (20%) with ethanol or dimethylsulphoxide or by addition of 0.001 M sodium dodecylsulphate. The complex is not formed in 6 M urea, in solution, at pH less than 2.0 or approximately 12.0-13.0, or with bovine plasminogen. Circular dichroism and tryptophan fluorescence spectral pattern changes during streptokinase-plasminogen complex formation enable us to conclude that streptokinase secondary and tertiary structures undergo certain rearrangements in the framework of the complex, while tryptophan-containing sites of the molecule are not drastically changed. The data obtained enable us to presuppose formation of streptokinase-rabbit plasminogen complexes which differ from human plasminogen complexes with streptokinase.     

The role of carbohydrate side chains of plasminogen in its activation by staphylokinase

Kinetic parameters (k(Pg) and K(Pg)) were determined for activation of Glu-plasminogen (Glu-Pg) and Lys-plasminogen (Lys-Pg) type I (with N-linked carbohydrate chain at Asn-289) and type II (with unsubstituted Asn-289) by plasmin-staphylokinase (Pm-STA) complex. The K(Pg) values for Glu-Pg I and Lys-Pg I (17.1 and 11.2 microM, respectively) were higher than those for Glu-Pg II and Lys-Pg II (14.9 and 5.4 microM, respectively), while only minor differences in the k(Pg) values were observed between plasminogens type I and type II. Soluble fibrin significantly increased the k(Pg)/K(Pg) values for activation of all four plasminogens due to a decrease in the K(Pg) values but did not alter the k(Pg) values. However, the activation of plasminogens type I was stimulated by fibrin lesser degree than that of plasminogens type II. These findings indicate that N-glycosylation of kringle 3 of plasminogen decreases the stability of Pm-STA-Pg ternary enzyme-substrate complex in solution as well as interferes with its formation and rearrangement on the fibrin surface.     

Characterization of a Mr 25,000 basic fibroblast growth factor form in adult, regenerating, and fetal rat liver

A heparin-binding Mr 25,000 immunoreactive bFGF-like protein (ir-bFGF) is recognized in adult rat liver extract by affinity-purified polyclonal anti-human placental bFGF antibodies. Hepatic levels of this protein increase 4-fold in regenerating rat liver during the first 48 h after partial hepatectomy. Also, they appear to be higher in embryonic than in newborn or in adult rat liver. Mr 25,000 ir-bFGF from regenerating rat liver, partially purified by heparin-affinity chromatography, induces plasminogen activator activity and cell proliferation in transformed fetal bovine aortic endothelial GM 7373 cells and competes with Mr 18,000 [125I]bFGF for the binding to high affinity bFGF receptors. The data indicate the presence in rat liver of a high molecular weight form of bFGF whose expression is modulated during embryonic development and liver regeneration.     

Kinetic studies of the urokinase-catalysed conversion of NH2-terminal glutamic acid plasminogen to plasmin.

Initial velocities for the urokinase (EC 3.4.99.26)-catalysed conversion of glutamic acid plasminogen to plasmin (EC 3.4.21.7) have been determined at various urokinase and glutamic acid plasminogen concentrations. As has been found for the corresponding reaction with lysine plasminogen this conversion obeys the Michaelis rate equation. The apparent Michaelis constants are of the same order of magnitude for lysine and glutamic acid plasminogens. The difference in conversion rates for the reactions has been shown to be connected with their having different catalytic constants. The data were analysed according to two reaction schemes, in one of which only one peptide bond is split during the glutamic acid plasminogen-plasmin conversion and in the other of which the cleavage of two peptide bonds with the obligatory formation of an intermediate plasminogen is assumed. The results favour the former.     

Cooperative association of plasminogen with fibrinogen

We have examined the association of both Glu- and Lys-plasminogen to fibrinogen by ultracentrifugal sedimentation equilibrium in neutral isotonic buffer in the presence of aprotinin. The fibrinogen and plasminogens, which were homogenous, did not exhibit any self-association. In each association study, five different molar ratios of plasminogen to fibrinogen were examined. The data were analyzed by mathematical modeling using nonlinear least-squares curve fitting. Analyses of molecular species present showed that up to 4 mol of either Glu- or Lys-plasminogen was associated with each mol of fibrinogen. For the binding of Glu-plasminogen, the values of the successive changes of the standard free energy of association were found to be -5.48, -7.73, -8.88, and -11.41 kcal/mol (Ka = 2.16 X 10(4), 1.32 X 10(6), 1.06 X 10(7), and 1.08 X 10(9) M-1). For the experimental conditions used here, the association of Lys-plasminogen appears to be described by virtually the same fitting parameters. The very marked cooperativity of association found here would appear to imply that there are significant alterations of the structure of fibrinogen as a result of each successive molecule of plasminogen bound.     

Assessment of plasminogen synthesis in vitro by mouse tumor cells using a competition radioimmunoassay for mouse plasminogen

A sensitive, specific competition radioimmunoassay for mouse plasmin(ogen) has been developed in order to determine whether mouse tumor cells can synthesize plasminogen in vitro. The rabbit anti-BALB/c mouse plasminogen antibodies used in the assay react with the plasminogen present in serum from BALB/c, C3H, AKR and C57BL/6 mice, and also recognized mouse plasmin. The competition radioimmunoassay can detect as little as 50 ng of mouse plasminogen. No competition was observed with preparations of fetal calf, human an rabbit plasminogens. A variety of virus-transformed and mouse tumor cell lines were all found to contain less than 100 ng mouse plasminogen/mg of cell extract protein. Thus, if the plasminogen activator/plasmin system is important in the growth or movement of this group of tumor cells, the cells will be dependent upon the circulatory system of the host for their plasminogen supply.     

Dysplasminogenemias

This review on dysplasminogenemias describes a growing relationship between genetic polymorphisms of plasminogen and dysplasminogenemias. Plasminogen variants found in eight families in America, Japan and Europe are discussed. Methods used to identify abnormal plasminogens are described in detail. These methods include (a) plasminogen functional to antigen ratios, (b) plasmin generation rates with several plasminogen activators, e.g. urokinase, streptokinase, and the plasmin light (B) chain.streptokinase complex, and (c) plasma and purified plasminogen isoelectric forms. The functional defect including plasminogen kinetics of activation parameters are reviewed, including the formation of plasmin. The molecular defect found in one family, Tochigi I, is described, a single amino acid substitution was found. Finally, the lack of relationships between the abnormal plasminogen variants is reviewed. The variants fall into two classes: one class with a complete absence of a functioning active center, and the second class with different plasminogen kinetics of activation parameters.     

Plasminogen carbohydrate side chains in receptor binding and enzyme activation: a study of C6 glioma cells and primary cultures of rat hepatocytes.

The human [Glu1]-plasminogen carbohydrate isozymes, plasminogen type I (Pg 1) and plasminogen type II (Pg 2), were separated by chromatography and studied in cell binding experiments at 4 degrees C with primary cultures of rat hepatocytes and rat C6 glioma cells. In both cell systems, Pg 1 and Pg 2 bound to an equivalent number of receptors, apparently representing the same population of surface molecules. The affinity for Pg 2 was slightly higher. With hepatocytes, the KD for Pg 1 was 3.2 +/- 0.2 microM, and the KD for Pg 2 was 1.9 +/- 0.1 microM, as determined from Scatchard transformations of the binding isotherms. The Bmax was approximately the same for both isozymes. With C6 cells, the KD for Pg 1 was 2.2 +/- 0.1 microM vs. 1.5 +/- 0.2 microM for Pg 2. Again, the Bmax was similar with both isozymes. 125I-Pg 1 and 125I-Pg 2 were displaced from specific binding sites by either nonradiolabeled isozyme. The KI for Pg 2 was slightly lower than the KI for Pg 1 with hepatocytes (0.9 vs. 1.3 microM) and with C6 cells (0.6 vs. 1.1 microM). No displacement was detected with miniplasminogen at concentrations up to 5.0 microM. Activation of Pg 1 and Pg 2 by recombinant two-chain tissue-plasminogen activator (rt-PA) was enhanced by hepatocyte cultures. The enhancing effect was greater with Pg 2. Hepatocyte cultures did not affect the activation of miniplasminogen by rt-PA or the activation of plasminogen by streptokinase. Unlike the hepatocytes, C6 cells did not enhance the activation of plasminogen by rt-PA or streptokinase; however, plasmin generated in the presence of C6 cells reacted less readily with alpha 2-antiplasmin.     

The receptor for the plasminogen activator of urokinase type is up-regulated in transformed rat thyroid cells.

Five rat thyroid cell lines were tested for the expression of the cell surface receptor for urokinase type plasminogen activator (uPA). All tested lines were found to bind uPA, but transformed 1-5G and Ki-Mol cells, which are also high uPA producers, bound at least ten times more uPA, as compared to non-producers, 'normal' TL5 cells. Moreover, it was possible to remove membrane-bound uPA by treating the cells with phosphatidylinositol-specific phospholipase C, suggesting that rat uPAR, like its human counterpart, is linked to the membrane by a glucosyl-phosphatidylinositol anchor. The specificity of the binding was tested by competition with three different synthetic peptides corresponding to amino acids 14-37 of human, rat and mouse uPA. The results indicate also that the receptor binding region of rat uPA is located within the growth factor domain of the molecule and that its expression may be dependent on the transformed state of the cells.     

Purification, cloning, and characterization of a profibrinolytic plasminogen-binding protein, TIP49a

The plasminogen receptors responsible for enhancing cell surface-dependent plasminogen activation expose COOH-terminal lysines on the cell surface and are sensitive to proteolysis by carboxypeptidase B (CpB). We treated U937 cells with CpB, then subjected membrane fractions to two-dimensional gel electrophoresis followed by ligand blotting with (125)I-plasminogen. A 54-kDa protein lost the ability to bind (125)I-plasminogen after treatment of intact cells and was purified by two-dimensional gel electrophoresis and then sequenced by mass spectrometry. Two separate amino acid sequences were obtained and were identical to sequences contained within human and rat TIP49a. The cDNA for the 54-kDa protein matched the human TIP49a sequence, and encoded a COOH-terminal lysine, consistent with susceptibility to CpB. Antibodies against rat TIP49a recognized the plasminogen-binding protein on two-dimensional Western blots of U937 cell membranes. Human (125)I-Glu-plasminogen bound specifically to TIP49a protein, and binding was inhibited by epsilon-aminocaproic acid. A single class of binding sites was detected, and a K(d) of 0.57 +/- 0.14 microm was determined. TIP49a enhanced plasminogen activation 8-fold compared with the BSA control, and this was equivalent to the enhancement mediated by plasmin-treated fibrinogen. These results suggest that TIP49a is a previously unrecognized plasminogen-binding protein on the U937 cell surface.     

In vivo and in vitro interaction of high and low molecular weight single-chain urokinase-type plasminogen activator with rat liver cells.

The plasma clearance and the interaction of high (HMW) and low (LMW) molecular weight single-chain urokinase-type plasminogen activator (scu-PA) with rat liver cells was determined. 125I-Labeled HMW- and LMW-scu-PA were rapidly cleared from plasma with a half-life of 0.45 min and a maximal liver uptake of 55% of the injected dose. Liver uptake of scu-PA was mediated by parenchymal cells. Excess of unlabeled HMW-scu-PA reduced the liver uptake of 125I-HMW-scu-PA strongly. In vivo liver degradation of scu-PA was reduced by inhibitors of the lysosomal pathway. A high affinity binding site (Kd 45 nM, Bmax 1.7 pmol/mg cell protein) for both HMW- and LMW-scu-PA was determined on isolated parenchymal liver cells. Cross-competition binding studies showed that LMW- and HMW-scu-PA bind to the same site. Tissue-type plasminogen activator, mannose- or galactose-terminated glycoproteins did not affect the scu-PA binding to parenchymal liver cells. It is concluded that LMW- and HMW-scu-PA are taken up in the liver by a common, newly identified recognition site on parenchymal liver cells and are subsequently degraded in the lysosomes. It is suggested that this site is important for the regulation of the turnover of scu-PA.     

Mouse ovarian granulosa cells produce urokinase-type plasminogen activator, whereas the corresponding rat cells produce tissue-type plasminogen activator

It is well established that rat ovarian granulosa cells produce tissue plasminogen activator (tPA). The synthesis and secretion of the enzyme are induced by gonadotropins, and correlate well with the time of follicular rupture in vivo. We have found that in contrast, mouse granulosa cells produce a different form of plasminogen activator, the urokinase-type (uPA). As with tPA synthesis in the rat, uPA production by mouse granulosa cells is induced by gonadotropins, dibutyryl cAMP, and prostaglandin E2. However, dexamethasone, a drug which has no effect on tPA synthesis in rat cells inhibits uPA synthesis in the mouse. Results of these determinations made in cell culture were corroborated by examining follicular fluid, which is secreted in vivo predominantly by granulosa cells, from stimulated rat and mouse ovarian follicles. Rat follicular fluid contained only tPA, and mouse follicular fluid only uPA, indicating that in vivo, granulosa cells from the two species are secreting different enzymes. The difference in the type of plasminogen activator produced by the rat and mouse granulosa cells was confirmed at the messenger RNA level. After hormone stimulation, only tPA mRNA was present in rat cells, whereas only uPA mRNA was found in mouse cells. Furthermore, the regulation of uPA levels in mouse cells occurs via transient modulation of steady-state levels of mRNA, a pattern similar to that seen with tPA in rat cells.