Tissue plasminogen activator and plasmin independently decrease human neutrophil activation

Tissue-plasminogen activator (t-PA) and plasmin both decrease platelet aggregation, which may contribute to thrombolysis and tissue salvage. Since neutrophils may contribute to reperfusion injury, we examined the effects of t-PA and plasmin on human neutrophil function. t-PA (1 to 100 micrograms/ml) decreased f-MLP-induced chemotaxis and ionophore A23187-induced superoxide and LTB4 release in isolated neutrophils, and these effects were not blocked by the plasmin-inhibitor epsilon-aminocaproic acid (epsilon-ACA). On the other hand, plasmin (0.05 to 0.5 units/ml) also decreased these neutrophil functions but its effects were blocked in the presence of epsilon-ACA. Thus, while both t-PA and plasmin decrease neutrophil functions, effects of t-PA are independent of plasmin generation. Cumulative effects of t-PA and plasmin on neutrophil functions may relate to the overall efficacy of t-PA in thrombotic disorders.     

Changes in the bovine zona pellucida induced by plasmin or embryonic plasminogen activator

Effects of bovine plasmin and plasminogen activator recovered from bovine embryo-conditioned medium (bePA) on the polypeptide profile and solubility of bovine zonae pellucidae (ZP) were evaluated. ZP were isolated from bovine ovarian oocytes and incubated at 39°C with 0, 100, or 200 μg/ml plasmin for 0, 24, or 48 hr or bePA with 0 or 100 μg/ml human plasminogen for 0 or 48 hr. ZP were evaluated either by SDS-PAGE or for changes in solubility using a zona pellucida dissolution time (ZPDT) assay. Two prominent polypeptides, molecular weight (MW) 76,000 and 65,000, and two minor polypeptides, MW 23,000 and 22,000, were resolved by SDS-PAGE. No changes occurred in the polypeptide profile for ZP incubated with 0 μg/ml plasmin for 0, 24, or 48 hr, and ZPDT did not differ (P > 0.10). Treatment with 100 or 200 μg/ml plasmin induced reductions in the MW 76,000, 23,000, and 22,000 polypeptides and the appearance of MW 45,000 and <10,000 polypeptides. ZPDT were less (P < 0.05) in 100 and 200 μg/ml compared with 0 μg/ml plasmin. Polypeptide profiles and ZPDT for ZP incubated with bePA were similar (P > 0.10) to ZP incubated with unconditioned medium. Addition of human plasminogen to ZP incubated with bePA reduced the MW 76,000, 23,000, and 22,000 polypeptides, caused the appearance of MW 45,000 and 20,000 polypeptides, and decreased ZPDT (P < 0.05). These results demonstrate that bovine plasmin is capable of proteolytically degrading the bovine ZP and that bePA can indirectly affect the ZP by converting plasminogen to plasmin. Mol. Reprod. Dev. 51:330–338, 1998. © 1998 Wiley-Liss, Inc.     

Fluorescence polarization assay of plasmin, plasminogen, and plasminogen activator

A chromatographic method involving medium-pressure liquid chromatography on alumina impregnated with silver nitrate is described for the separation of a series of closely related C₂₇ sterol precursors of cholesterol differing only in the number and location of olefinic double bonds. The features of the described system are compared with those of previously described thin-layer, gas-liquid, gravity column, and high-pressure liquid chromatographic methods.     

A covalent molecular weight approximately 92,000 hybrid plasminogen activator derived from human plasmin fibrin-binding and tissue plasminogen activator catalytic domains

A covalent hybrid plasminogen activator was prepared from the sulfhydryl forms of the NH2-terminal heavy (A) chain of human plasmin (PlnA) containing the fibrin-binding domain and the COOH-terminal B chain of tissue plasminogen activator (t-PAB) containing the catalytic domain. The sulfhydryl form of PlnA [PlnA(SH)2] was isolated from reduced Lys-2-plasmin on an L-lysine-substituted Sepharose column, and the sulfhydryl form of t-PAB [t-PAB(SH)] was prepared from reduced two-chain tissue plasminogen activator (t-PA) by removing the tissue plasminogen activator NH2-terminal A chain (t-PAA) on an L-lysine-substituted Sepharose column from the chain mixture. The specific plasminogen activator activity, with soluble fibrin, of the isolated t-PAB(SH) chain was determined to be 62,700 international units (IU)/mg of protein, about 13% of the specific plasminogen activator activity of the parent t-PA. The PlnA(SH)2 and the t-PAB(SH) chains were mixed in a 1:1 molar ratio, and hybridization (reoxidation) was allowed to proceed by first dialyzing out the reducing agent at 4 degrees C and then concentrating the mixture. The time for maximum hybridization, or formation of the covalent hybrid activator, was 6 days, as determined by both specific plasminogen activator activity, with soluble fibrin, and specific amidolytic activity; sodium dodecyl sulfate-polyacrylamide gel electrophoresis showed the continual formation of an Mr approximately 92,000 hybrid. The covalent PlnA-t-PAB hybrid activator was isolated from the 6-day hybridization mixture by a two-step affinity chromatography method.(ABSTRACT TRUNCATED AT 250 WORDS)     

Novel properties of human monocyte plasminogen activator

Human peripheral monocytes stimulated by either muramyl dipeptide [N-acetyl-muramoyl-L-alanyl-D-isoglutamine], bacterial lipopolysaccharide or lymphokine-containing supernatants of human lymphocytes, could be shown to produce and secrete appreciable activities of a 52 000-Mr plasminogen activator. This enzyme was suppressed in control and stimulated cultures by dexamethasone (0.1 microM). Monocyte plasminogen activator could only be assayed under conditions of low ionic strength and had no detectable activity at 0.15 M NaCl. Intracellular enzyme was present as a proenzyme, requiring activation by preincubation with plasminogen containing traces of plasmin, before its activity could be seen on sodium dodecyl sulphate/polyacrylamide gel electrophoresis by a fibrin overlay method. Secreted enzyme was in the active form. Further incubation of lysate or supernatant plasminogen activator with plasminogen did not produce any active enzyme species of Mr 36 000, unlike incubations of urokinase with plasminogen. Moreover, comparisons with other plasminogen activators of Mr 52 000 from transformed cell lines showed that the monocyte activator was unique in its resistance to monocyte minactivin, a specific inactivator of urokinase-type plasminogen activators, and in its sensitivity to human alpha 2-macroglobulin. It was therefore concluded that human monocyte plasminogen activator, although sharing an Mr of 52 000 in common with other such activators, is not identical to the high Mr form of urokinase or the plasminogen activators of transformed cells. On present evidence it is the least likely of these enzymes to be active extracellularly under normal physiological conditions.     

Synthesis of recombinant human single-chain urokinase-type plasminogen activator variants resistant to plasmin and thrombin

Single-chain urokinase-type plasminogen activator (scu-PA), a potential therapeutic reagent for thrombosis, is activated in plasma by plasmin. The activated enzyme is further digested by plasmin to generate low-molecular-weight urokinase (LMW-UK), which has no affinity for fibrin. To circumvent this dual effect of plasmin, we synthesized in Escherichia coli a variant of scu-PA, which is not converted to LMW-UK on treatment with plasmin. In another variant, the activation cleavage site was modified such that activation by plasmin was slowed down and that inactivation by thrombin was greatly diminished. The combination of these variants may be applicable as an effective thrombolytic reagent for clinical use.     

Follicular plasminogen and plasminogen activator and the effect of plasmin on ovarian follicle wall.

Plasminogen, plasminogen activator, protease inhibitors, and a proteolytic activity are shown to be present in bovine follicular fluid. Much of the proteolytic activity appears to be due to plasmin. In addition, plasminogen activator activity can be demonstrated in follicle wall homogenates. Evidence that plasmin decreases the tensile strength of follicle wall preparations is also reported. The potential for the involvement of these substances in ovulation is discussed.     

Fibrin and plasminogen structures essential to stimulation of plasmin formation by tissue-type plasminogen activator

Plasminogen activation catalysed by tissue-type plasminogen activator (t-PA) has been examined in the course of concomitant fibrin formation and degradation. Plasmin generation has been measured by the spectrophotometric method of Petersen et al. (Biochem. J. 225 (1985) 149-158), modified so as to allow for light scattering caused by polymerized fibrin. Glu1-, Lys77- and Val442-plasminogen are activated in the presence of fibrinogen, des A- and des AB-fibrin and the rate of plasmin formation is found to be greatly enhanced by both des A- and des AB-fibrin polymer. Plasmin formation from Glu1- and Lys77-plasminogen yields a sigmoidal curve, whereas a linear increase is obtained with Val442-plasminogen. The rate of plasmin formation from Glu1- and Lys77-plasminogen declines in parallel with decreasing turbidity of the fibrin polymer effector. In order to study the effect of polymerization, this has been inhibited by the synthetic polymerization site analogue Gly-Pro-Arg-Pro, by fibrinogen fragment D1 or by prior methylene blue-dependent photooxidation of the fibrinogen used. Inhibition of polymerization by Gly-Pro-Arg-Pro reduces plasmin generation to the low rate observed in the presence of fibrinogen. Antipolymerization with fragment D1 or photooxidation has the same effect on Glu1-plasminogen activation, but only partially reduces and delays the stimulatory effect on Lys77- and Val442-plasminogen activation. The results suggest that protofibril formation (and probably also gelation) of fibrin following fibrinopeptide release is essential to its stimulatory effect. The gradual increase and subsequent decline in the rate of plasmin formation from Glu1- or Lys77-plasminogen during fibrinolysis may be explained by sequential exposure, modification and destruction of different t-PA and plasminogen binding sites in fibrin polymer.     

Actin accelerates plasmin generation by tissue plasminogen activator.

Actin has been found to bind to plasmin's kringle regions, thereby inhibiting its enzymatic activity in a noncompetitive manner. We, therefore, examined its effect upon the conversion of plasminogen to plasmin by tissue plasminogen activator. Actin stimulated plasmin generation from both Glu- and Lys-plasminogen, lowering the Km for activation of Glu-plasminogen into the low micromolar range. Accelerated plasmin generation did not occur in the presence of epsilon-amino caproic acid or if actin was exposed to acetic anhydride, an agent known to acetylate lysine residues. Actin binds to tissue plasminogen activator (t-Pa) (Kd = 0.55 microM), at least partially via lysine-binding sites. Actin's stimulation of plasmin generation from Glu-plasminogen was inhibited by the addition of aprotinin and was restored by the substitution of plasmin-treated actin, indicating the operation of a plasmin-dependent positive feedback mechanism. Native actin binds to Lys-plasminogen, and promotes its conversion to plasmin even in the presence of aprotinin, indicating that plasmin's cleavage of either actin or plasminogen leads to further plasmin generation. Plasmin-treated actin binds Glu-plasminogen and t-PA simultaneously, thereby raising the local concentration of t-PA and plasminogen. Together, but not separately, actin and t-PA prolong the thrombin time of plasma through the generation of plasmin and fibrinogen degradation products. Actin-stimulated plasmin generation may be responsible for some of the changes found in peripheral blood following tissue injury and sepsis.     

Complex interactions between bovine plasminogen and streptococcal plasminogen activator PauA

The interactions between bovine plasminogen and the streptococcal plasminogen activator PauA that culminate in the generation of plasmin are not fully understood. Formation of an equimolar activation complex comprising PauA and plasminogen by non-proteolytic means is a prerequisite to the recruitment of substrate plasminogen; however the determinants that facilitate these interactions have yet to be defined. A mutagenesis strategy comprising nested deletions and random point substitutions indicated roles for both amino and carboxyl-terminal regions of PauA and identified further essential residues within the alpha domain of the plasminogen activator. A critical region within the alpha domain was identified using non-overlapping PauA peptides to block the interaction between PauA and bovine plasminogen, preventing formation of the activation complex. Homology modelling of the activation complex based upon the known structures of streptokinase complexed with human plasmin supported these findings by placing critical residues in close proximity to the plasmin component of the activation complex.     

Activation with plasmin of tow-chain urokinase-type plasminogen activator derived from single-chain urokinase-type plasminogen activator by treatment with thrombin

Thrombin converts single-chain urokinase-type plasminogen activator (scu-PA) to an inactive two-chain derivative (thrombin-derived tcu-PA) by hydrolysis of the Arg-156--Phe-157 peptide bond. In the present study, we show that inactive thrombin-derived tcu-PA (specific activity 1000 IU/mg) can be converted with plasmin to active two-chain urokinase-type plasminogen activator (specific activity 43,000 IU/mg) by hydrolysis of the Lys-158--Ile-159 peptide bond. This conversion follows Michaelis-Menten kinetics with a Michaelis constant Km of 37 microM and a catalytic rate constant k2 of 0.013 s-1. The catalytic efficiency (k2/Km) for the activation of thrombin-derived tcu-PA by plasmin is about 500-fold lower than that for the conversion of intact scu-PA to tcu-PA. tcu-PA, generated by plasmin treatment of thrombin-derived tcu-PA, has similar properties to tcu-PA obtained by digestion of intact scu-PA with plasmin (plasmin-derived tcu-PA); its plasminogen activating potential and fibrinolytic activity in an in vitro plasma clot lysis system appear to be unaltered. These observations confirm that the structure of the NH2-terminal region of the B chain of u-PA is an important determinant for its enzymatic activity, whereas that of the COOH-terminal region of the A chain is not.     

Gonadotropin surge-induced up-regulation of the plasminogen activators (tissue plasminogen activator and urokinase plasminogen activator) and the urokinase plasminogen activator receptor within bovine periovulatory follicular and luteal tissue

This study examined the effect of the preovulatory gonadotropin surge on the temporal and spatial regulation of tissue plasminogen activator (tPA), urokinase plasminogen activator (uPA), and uPA receptor (uPAR) mRNA expression and tPA, uPA, and plasmin activity in bovine preovulatory follicles and new corpora lutea collected at approximately 0, 6, 12, 18, 24, and 48 h after a GnRH-induced gonadotropin surge. Messenger RNAs for tPA, uPA, and uPAR were increased in a temporally specific fashion within 24 h of the gonadotropin surge. Localization of tPA mRNA was primarily to the granulosal layer, whereas both uPA and uPAR mRNAs were detected in both the granulosal and thecal layers and adjacent ovarian stroma. Activity for tPA was increased in follicular fluid and the preovulatory follicle apex and base within 12 h after the gonadotropin surge. The increase in tPA activity in the follicle base was transient, whereas the increased activity in the apex was maintained through the 24 h time point. Activity for uPA increased in the follicle apex and base within 12 h of the gonadotropin surge and remained elevated. Plasmin activity in follicular fluid also increased within 12 h after the preovulatory gonadotropin surge and was greatest at 24 h. Our results indicate that mRNA expression and enzyme activity for both tPA and uPA are increased in a temporally and spatially specific manner in bovine preovulatory follicles after exposure to a gonadotropin surge. Increased plasminogen activator and plasmin activity may be a contributing factor in the mechanisms of follicular rupture in cattle.