A monoclonal antibody to the epsilon-aminocaproic acid binding site on the kringle 4 region of human plasminogen that accelerates the activation of Glu1-plasminogen by urokinase

A monoclonal antibody, 10-F-1, previously shown [V. A. Ploplis, H. S. Cummings, and F. J. Castellino (1982) Biochemistry 21, 5891-5897] to interact with a particular epsilon-aminocaproic acid (EACA)3 binding site on the kringle 4 (K4) region of human Glu1-plasminogen (Glu1-Pg), has been employed to assess the contribution of this particular EACA site toward the enhancement, by EACA and its analogs, of the urokinase (UK)-catalyzed activation of Glu1-Pg. As is the case with EACA-like compounds, the presence of antibody 10-F-1 accelerates the activation of Glu1-Pg by UK, but does not enhance the similar activation of Lys77-plasminogen. In the presence of concentrations of antibody 10-F-1 which saturate its binding site on Glu1-Pg, the Km of Glu1-Pg activation by UK is raised from 1.4 +/- 0.2 microM, a value obtained in the absence of antibody, to 17.0 +/- 2.0 microM. On the other hand, the kcat for this activation, 0.038 +/- 0.005 s-1, is elevated to 2.45 +/- 0.2 s-1 at saturating concentrations of antibody 10-F-1. The kcat/Km for activation under these conditions is 0.027 s-1 microM-1 in the absence of antibody, and 0.144 s-1 microM-1 in the presence of saturating levels of antibody 10-F-1. This demonstrates that the interaction of this antibody with its epitope results in a fivefold stimulation of the activation rate of Glu1-Pg by UK. The availability of antibody 10-F-1 allows for a specific means of probing the function of one of the four to five thermodynamically equivalent weak EACA sites on human plasminogen. From this particular study, it is concluded that the weak binding site for EACA on the K4 domain of Glu1-Pg is either in-part or in-whole responsible for the enhancing effect of EACA on human Glu1-Pg activation by UK.     

Effectors of the activation of human [Glu1]plasminogen by human tissue plasminogen activator

The activation of human [Glu1]plasminogen [( Glu1]Pg) by human recombinant (rec) two-chain tissue plasminogen activator (t-PA) is inhibited by Cl-, at physiological concentrations, and stimulated by epsilon-aminocaproic acid (EACA), as well as fibrin(ogen). Chloride functions as a result of its binding to [Glu1]Pg, with a Ki of approximately 9.0 mM, thereby rendering [Glu1]Pg a less effective substrate for two-chain rec-t-PA. EACA stimulates the activation in Cl-(-)containing solutions, with a Ka of approximately 4.0 mM, primarily by reversal of the Cl-(-)inhibitory effect. Fibrinogen appears to exert its stimulatory properties mainly through effects on the enzyme, two-chain rec-t-PA, with a Ka of approximately 3.7 microM in activation systems containing physiological levels of Cl-. Analysis of the results of this paper reveals that normal plasma components, Cl- and fibrinogen, exert major regulatory roles on the ability of [Glu1]Pg to be activated by two-chain rec-t-PA, in in vitro systems. The presence of Cl- inhibits the stimulation of [Glu1]Pg activation that would normally occur in the presence of fibrinogen, a result of possible importance to the observation that some degree of systemic fibrinogenolysis accompanies therapeutic use of tissue plasminogen activator.     

The activation of human [Glu1]plasminogen by human single-chain urokinase

The activation of human [Glu1]plasminogen ([Glu1]Pg) by single-chain human urokinase (SCUKase) displays a substantial lag phase at physiological levels of [Glu1]Pg. Employing a monoclonal antibody that exhibits a high level of specificity for SCUKase, as compared to two-chain urokinase (TCUKase), we have demonstrated conclusively that during this lag phase a progressive loss of SCUKase occurs, most likely resulting from its conversion to TCUKase, in a reaction catalyzed by plasmin (HPm). The overall activation of [Glu1]Pg by SCUKase is inhibited by physiological levels of Cl- and stimulated by epsilon-amino caproic acid. Kinetic studies demonstrate that both these effects are based on first, the reaction of [Glu1]Pg with the TCUKase that is formed during the activation, and, second, the concomitant rate at which HPm is provided for the conversion of SCUKase to TCUKase. The results indicate that at physiological levels of [Glu1]Pg, its activation in the presence of SCUKase is regulated in one manner by the rate at which SCUKase is converted to TCUKase, in a process that is strongly influenced by physiological levels of Cl-. Finally, and importantly, we show that SCUKase possesses very little, if any, inherent ability to activate [Glu1]Pg at a rate that influences the kinetics of HPm generation under physiological conditions of [Glu1]Pg and Cl- concentrations.     

Plasminogen activation by single-chain urokinase in functional isolation. A kinetic study

The kinetics of the activation of Glu- and Lys-plasminogen by single-chain urokinase (sc urokinase) derived from the transformed human kidney cell line TCL-598 have been studied and compared with two-chain urokinase (tc urokinase). Plasminogen activation was determined by the increase in fluorescence polarization of fluorescein-labeled aprotinin, a high affinity inhibitor of plasmin. This methodology allows plasmin generation by sc urokinase to be measured in functional isolation, with no interfering generation of tc urokinase, sc urokinase was found to activate plasminogen to plasmin with apparent Michaelis-Menten-type kinetics. The Km for Glu-plasminogen activation was 47.7 microM, with a catalytic constant of 2.91 min-1. Lys-plasminogen activation by sc urokinase was characterized by a Km of 11.7 microM and a kcat of 5.60 min-1. The Km values for the activation of Glu- and Lys-plasminogen by tc urokinase were found to be similar to those for activation by sc urokinase (36.8 and 9.0 microM, respectively), but the catalytic constants were higher at 36.0 and 118 min-1, respectively. Therefore, on the basis of the catalytic efficiency kcat/Km, sc urokinase seems to have 16-27-fold lower activity than tc urokinase. This activity of sc urokinase is in contrast to its lack of activity against a low molecular weight peptide substrate (less than 0.2% of the activity of sc urokinase). The activation of sc urokinase to tc urokinase by plasmin was also characterized (Km = 3.0 microM, kcat = 105 min-1). Using these data, it was possible to calculate the theoretical rate of plasminogen activation by sc urokinase in the absence of aprotinin, when tc urokinase is generated by the action of plasmin. The calculated rate was in good agreement with that determined experimentally using the chromogenic substrate D-Val-Leu-Lys-p-nitroanilide. These data demonstrate that sc urokinase has properties which distinguish it from conventional serine protease zymogens. The lack of activity against low molecular weight peptide substrates demonstrates the inaccessibility of the substrate-binding pocket. However, there is a moderate activity against plasminogen, suggesting that plasminogen may be acting as both an effector and a substrate for sc urokinase.     

Ionic modulation of the effects of heparin on plasminogen activation by tissue plasminogen activator: the effects of ionic strength, divalent cations, and chloride.

Ionic strength, divalent cations, and Cl- modulate the ability of the glycosaminoglycan heparin to stimulate the activation of human plasminogen (Pg) by tissue-type Pg activator. Kinetic analysis of Pg activation indicates that heparin is inhibitory, stimulatory, or nonstimulatory as a function of ionic strength. While increasing ionic strength inhibits Pg activation in the absence of heparin, in it presence an activation phase followed by an inhibitory phase is observed. Divalent cations, inhibitors of activation in the absence of heparin, increase the rate of activation in its presence. Kinetic analysis demonstrates that divalent cations augment the heparin stimulatory effect a maximum of 60-fold due to increases in kcat without changes in Km of the reaction. This effect is heparin-specific, since activation is not affected by Ca2+ in the presence of heparan sulfate or de-N-sulfated heparin. Also, Cl- inhibits Pg activation in the presence of heparin by acting as a competitive inhibitor (Kic of 100 mM). Furthermore, inhibition by Cl- reduces the overall magnitude of heparin stimulation of Pg activation. These results suggest that physiologic ions in combination with heparin may be significant effectors of Pg activation in the vascular microenvironment.     

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.     

Effects of human fibrinogen and its cleavage products on activation of human plasminogen by streptokinase

The influence of human fibrinogen (Fg) and its terminal plasminolytic digestion products, fragment D and fragment E, on the kinetics of activation of human plasminogen (Pg) by catalytic levels of streptokinase (SK) has been investigated. Both Fg and fragment D enhanced the rates of activation of human Glu1-Pg, Lys77-Pg, and Val442-Pg. Fragment E was refractive in this regard. In the case of Glu1-Pg, the Km for activation by SK, 0.4 microM, was not affected by the presence of Fg or fragment D. The kcat for this same reaction, 0.12 s-1, was elevated to 0.3 s-1 at saturating levels of these effector molecules. On the other hand, the Km for activation of Lys77-Pg, 0.5 microM, was decreased to 0.09 microM, whereas the kcat, 0.33 s-1, was not altered in the presence of saturating concentrations of Fg or fragment D. In the case of Val442-Pg, the Km for this same activation, 2.0 microM, was lowered to 0.4 microM and 0.25 microM in the presence of Fg and fragment D, respectively. The kcat for this process, 1.0 s-1, was unchanged in the presence of these agents. The concentrations of Fg (KFg) and fragment D (KFD) that led to half-maximal stimulation of the activation rates were determined. For Fg with Glu1-Pg, Lys77-Pg, and Val442-Pg, the KFg values were 0.08 microM, 0.14 microM, and 0.17 microM, respectively. The KFD values for these same plasminogens were 0.25 microM, 2.0 microM, and 1.7 microM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Purification and properties of a plasminogen activator from cultured rat prostate adenocarcinoma cells

Zymographic analysis of the supernates from confluent cultures of a rat prostate adenocarcinoma cell line, PA-III, revealed the existence of two molecular forms of specific plasminogen activators, one of molecular weight of approximately 80 000 and another of approximate molecular weight of 45 000, in sodium dodecyl sulfate. The low molecular weight form has been purified 364-fold in 66% yield from the culture medium by a combination of gel filtration on Sephacryl S-200 and affinity chromatography on Sepharose 4B-benzamidine. The purified material possessed a specific activity of 192 000 urokinase CTA units mg-1. This enzyme displayed activity toward human Glu1-plasminogen, characterized by a Km of 1.7 +/- 0.2 microM and a Vmax of 0.53 +/- 0.1 pmol of plasmin min-1 unit-1. A synthetic chromogenic substrate, H-D-Ile-Pro-Arg-p-nitroanilide (S-2288), was found for the activator. The enzyme possessed a Km of 0.33 mM and a kcat of 55 s-1 for S-2288. The activator was found to be a serine protease, inhibited by diisopropyl fluorophosphate (iPr2PF). At a concentration of 1 mM iPr2PF, and 30 nM enzyme, the half-time of this inhibition was 3.8 min. The 45 000 molecular weight enzyme was found to be inhibited by rabbit antibodies to human urokinase, thus characterizing the activator as a member of the urokinase class. The 80 000 molecular weight enzyme was not neutralized by anti-human urokinase but was neutralized by rabbit anti-human melanoma activator, likely allowing it to be classified as the tissue activator type.     

Use of a fluorescence plate reader for measuring kinetic parameters with inner filter effect correction

A general method is presented here for the determination of the Km, kcat, and kcat/Km of fluorescence resonance energy transfer (FRET) substrates using a fluorescence plate reader. A simple empirical method for correcting for the inner filter effect is shown to enable accurate and undistorted measurements of these very important kinetic parameters. Inner filter effect corrected rates of hydrolysis of a FRET peptide substrate by hepatitis C virus (HCV) NS3 protease at various substrate concentrations enabled measurement of a Km value of 4.4 +/- 0.3 microM and kcat/Km value of 96,500 +/- 5800 M-1 s-1. These values are very close to the HPLC-determined Km value of 4.6 +/- 0.7 microM and kcat/Km value of 92,600 +/- 14,000 M-1 s-1. We demonstrate that the inner filter effect correction of microtiter plate reader velocities enables rapid measurement of Ki and Ki' values and kinetic inhibition mechanisms for HCV NS3 protease inhibitors.     

Mechanism of inhibitory effect of angiostatin on plasminogen activation by its physiologic activators

The influence of angiostatin K1-4.5--a fragment of the heavy chain of plasmin and a powerful inhibitor of angiogenesis--on kinetic parameters (k(Pg) and K(Pg)) of human Glu-plasminogen activation under the action of urokinase (uPA) not having affinity for fibrin and fibrin-specific tissue plasminogen activator (tPA) was investigated. Angiostatin does not affect the k(Pg) value, but increases the value K(Pg) urokinase plasminogen activation. A decrease in the k(Pg) value and an increase in the K(Pg) value were found for fibrin-stimulated plasminogen activation by tPA with increasing concentrations of angiostatin. The obtained results show that angiostatin is competitive inhibitor of the uPA activator activity, while it inhibits the activator activity of tPA by mixed type. Such an influence ofangiostatin on the kinetic constants ofthe urokinase plasminogen activation suggests that angiostatin dose dependent manner replaces plasminogen in the binary enzyme-substrate complex uPA-Pg. In case of fibrin-stimulated plasminogen activation by tPA, both zymogen and tPA are bound to fibrin with formation of the effective triple tPA-Pg-fibrin complex. Angiostatin replaces plasminogen both from the fibrin surface and from the enzyme-substrate tPA-Pg complex that leads to a decrease in k(Pg) and an increase in K(Pg) of plasminogen activation. Inhibition constants by angioststin (Ki) of plasminogen-activator activities of uPA and tPA determined by Dixon method were found to be 0.59 +/- 0.04 and 0.12 +/- 0.05 microM, respectively.     

The role of chloride in taurine transport across the human placental brush-border membrane.

Taurine, a sulfated beta-amino acid, is conditionally essential during development. A maternal supply of taurine is necessary for normal fetal growth and neurologic development, suggesting the importance of efficient placental transfer. Uptake by the brush-border membrane (BBM) in several other tissues has been shown to be via a selective Na(+)-dependent carrier mechanism which also has a specific anion requirement. Using BBM vesicles purified from the human placenta, we have confirmed the presence of Na(+)-dependent, carrier-mediated taurine transport with an apparent Km of 4.00 +/- 0.22 microM and a Vmax of 11.72-0.36 pmol mg-1 protein 20 s-1. Anion dependence was examined under voltage-clamped conditions, in order to minimize the contribution of membrane potential to transport. Uptake was significantly reduced when anions such as thiocyanate, gluconate, or nitrate were substituted for Cl-. In addition, a Cl(-)-gradient alone (under Na(+)-equilibrated conditions) could energize uphill transport as evidenced by accelerated uptake (3.13 +/- 0.8 pmol mg-1 protein 20 s-1) and an overshoot compared to Na+, Cl- equilibrated conditions (0.60 +/- 0.06 pmol mg-1 protein 20 s-1). A Cl(-)-gradient (Na(+)-equilibrated) also stimulated uptake of [3H]taurine against its concentration gradient. Analysis of uptake in the presence of varying concentrations of external Cl- suggested that 1 Cl- ion is involved in Na+/taurine cotransport. We conclude that Na(+)-dependent taurine uptake in the placental BBM has a selective anion requirement for optimum transport. This process is electrogenic and involves a stoichiometry of 2:1:1 for Na+/Cl-/taurine symport.     

Interaction of plasminogen and fibrin in plasminogen activation

Glu1-, Lys77-, miniplasminogens, kringle 1-3, kringle 1-5A, and kringle 1-5R were able to bind with fibrin, while microplasminogen and kringle 4 did not bind significantly. Kringle 1-5A, but not kringle 1-3, effectively inhibited the binding of Glu1-, Lys77-, and miniplasminogens with fibrin. Miniplasminogen also inhibited the binding of Glu1-plasminogen with fibrin. The binding of kringle 1-3 with fibrin was blocked by mini- or Glu1-plasminogen. It is therefore evident that there are two fibrin-binding domains in plasminogen and that the one in kringle 5 is of higher affinity than that in kringle 1-3. CNBr cleavage products of fibrinogen effectively enhanced the activation of Glu1-, Lys77-, or miniplasminogens, but not microplasminogen, by tissue-type plasminogen activator. Kringle 1-5, but not kringle 1-3, dose-dependently inhibited the enhancement by fibrinogen degradation products of Glu1-plasminogen activation by the activator. Lysine and epsilon-aminocaproic acid could inhibit the binding of plasminogens and plasminogen derivatives with fibrin and block the enhancement effect of fibrinogen degradation products on plasminogen activation. The data clearly illustrate that the binding of plasminogen with fibrin, mainly determined by kringle 5, is essential for effective activation by tissue-type plasminogen activator. However, the presence of kringle 1-4 in the plasminogen molecule is required for the full enhancing effect since the kcat/Km of miniplasminogen activation in the presence of fibrinogen degradation products was 8.2 microM-1 min-1 which is significantly less than 52.0 microM-1 min-1 of Glu1-plasminogen.     

Streptokinase binds preferentially to the extended conformation of plasminogen through lysine binding site and catalytic domain interactions

Binding of streptokinase (SK) to plasminogen (Pg) activates the zymogen conformationally and initiates its conversion into the fibrinolytic proteinase, plasmin (Pm). Equilibrium binding studies of SK interactions with a homologous series of catalytic site-labeled fluorescent Pg and Pm analogues were performed to resolve the contributions of lysine binding site interactions, associated changes between extended and compact conformations of Pg, and activation of the proteinase domain to the affinity for SK. SK bound to fluorescein-labeled [Glu]Pg(1) and [Lys]Pg(1) with dissociation constants of 624 +/- 112 and 38 +/- 5 nM, respectively, whereas labeled [Lys]Pm(1) bound with a 57000-fold tighter dissociation constant of 11 +/- 2 pM. Saturation of lysine binding sites with 6-aminohexanoic acid had no effect on SK binding to labeled [Glu]Pg(1), but weakened binding to labeled [Lys]Pg(1) and [Lys]Pm(1) 31- and 20-fold, respectively. At low Cl(-) concentrations, where [Glu]Pg assumes the extended conformation without occupation of lysine binding sites, a 23-fold increase in the affinity of SK for labeled [Glu]Pg(1) was observed, which was quantitatively accounted for by expression of new lysine binding site interactions. The results support the conclusion that the SK affinity for the fluorescent Pg and Pm analogues is enhanced 13-16-fold by conversion of labeled [Glu]Pg to the extended conformation of the [Lys]Pg derivative as a result of lysine binding site interactions, and is enhanced 3100-3500-fold further by the increased affinity of SK for the activated proteinase domain. The results imply that binding of SK to [Glu]Pg results in transition of [Glu]Pg to an extended conformation in an early event in the SK activation mechanism.     

Human cathepsin H: deletion of the mini-chain switches substrate specificity from aminopeptidase to endopeptidase

The mini-chain of human cathepsin H has been identified as the major structural element determining the protease's substrate specificity. A genetically engineered mutant of human cathepsin H lacking the mini-chain, des[Glu(-18)-Thr(-11)]-cathepsin H, exhibits endopeptidase activity towards the synthetic substrate Z-Phe-Arg-NH-Mec (kcat = 0.4 s(-1), Km = 92 microM, kcat/Km = 4348 M(-1) s(-1)) which is not cleaved by r-wt cathepsin H. However, the mutant enzyme shows only minimal aminopeptidase activity for H-Arg-NH-Mec (kcat = 0.8 s(-1), Km = 3.6 mM, kcat/Km = 222 M(-1) s(-1)) which is one of the best known substrates for native human cathepsin H (kcat = 2.5 s(-1), Km = 150 microM, kcat/Km = 16666 M(-1) s(-1)). Inhibition studies with chicken egg white cystatin and E-64 suggest that the mini-chain normally restricts access of inhibitors to the active site. The kinetic data on substrates hydrolysis and enzyme inhibition point out the role of the mini-chain as a structural framework for transition state stabilization of free alpha-amino groups of substrates and as a structural barrier for endopeptidase-like substrate cleavage.     

Kinetic analysis of the effects of heparin and lipoproteins on tissue plasminogen activator mediated plasminogen activation

Heparin sulfate and the less sulfated glycosaminoglycan heparan sulfate enhance human plasminogen (Pg) conversion to plasmin by tissue-type plasminogen activator (t-PA). Kinetic studies indicate that both heparin and heparan increase the kcat of t-PA-mediated Pg activation by 25- and 3.5-fold, respectively. The Km of plasmin formation is unaltered by the presence of either heparin or heparan. Both heparin and heparan stimulate the activity of t-PA by interacting with the finger domain of t-PA, with association constants of 1 microM and 200 nM, respectively. Additionally, the lipoproteins lipoprotein(a) [Lp(a)] and low-density lipoprotein (LDL) inhibit the heparin enhancement of Pg activation. Lp(a) is a competitive inhibitor and LDL is a mixed inhibitor of t-PA-mediated Pg activation, with inhibition constants of 30 and 70 nM, respectively. The inhibition constants correspond to physiologic concentrations of these lipoproteins. These data suggest that heparin, heparan, and lipoproteins may play an important in vivo role in regulating cell surface associated activation of the fibrinolytic system.     

Na+-independent Cl(-)-HCO-3- exchange in Madin-Darby canine kidney cells. Role in intracellular pH regulation

The role of plasma membrane Cl(-)-HCO-3-exchange in regulating intracellular pH (pHi) was examined in Madin-Darby canine kidney cell monolayers. In cells bathed in 25 mM HCO-3, pH 7.4, steady state pHi was 7.10 +/- 0.03 (n = 14) measured with the fluorescent pH probe 2',7'-biscarboxyethyl-5,6-carboxyfluorescein. Following acute alkaline loading, pHi recovered exponentially in approximately 4 min. The recovery rate was significantly decreased by Cl- or HCO-3 removal and in the presence of 50 microM 4,4'-diisothiocyano-2,2'-disulfonic stilbene (DIDS). Na+ removal or 10(-3) M amiloride did not inhibit the pHi recovery rate after an acute alkaline load. Following acute intracellular acidification, the pHi recovery rate was significantly inhibited by 10(-3) M amiloride but was not altered by Cl- removal or 50 microM DIDS. At an extracellular pH (pHo) of 7.4, pHi remained unchanged when the cells were bathed in either Cl- free media, HCO-3 free media, or in the presence of 50 microM DIDS. As pHo was increased to 8.0, steady state pHi was significantly greater than control in Cl(-)-free media and in the presence of 50 microM DIDS. It is concluded that Madin-Darby canine kidney cells possess a Na+-independent Cl(-)-HCO-3 exchanger with a Km for external Cl- of approximately 6 mM. The exchanger plays an important role in pHi regulation following an elevation of pHi above approximately 7.1. Recovery of pHi following intracellular acidification is mediated by the Na+/H+ antiporter and not the anion exchanger.     

The blockage of the high-affinity lysine binding sites of plasminogen by EACA significantly inhibits prourokinase-induced plasminogen activation

Prourokinase-induced plasminogen activation is complex and involves three distinct reactions: (1) plasminogen activation by the intrinsic activity of prourokinase; (2) prourokinase activation by plasmin; (3) plasminogen activation by urokinase. To further understand some of the mechanisms involved, the effects of epsilon-aminocaproic acid (EACA), a lysine analogue, on these reactions were studied. At a low range of concentrations (10-50 microM), EACA significantly inhibited prourokinase-induced (Glu-/Lys-) plasminogen activation, prourokinase activation by Lys-plasmin, and (Glu-/Lys-) plasminogen activation by urokinase. However, no inhibition of plasminogen activation by Ala158-prourokinase (a plasmin-resistant mutant) occurred. Therefore, the overall inhibition of EACA on prourokinase-induced plasminogen activation was mainly due to inhibition of reactions 2 and 3, by blocking the high-affinity lysine binding interaction between plasmin and prourokinase, as well as between plasminogen and urokinase. These findings were consistent with kinetic studies which suggested that binding of kringle 1-4 of plasmin to the N-terminal region of prourokinase significantly promotes prourokinase activation, and that binding of kringle 1-4 of plasminogen to the C-terminal lysine158 of urokinase significantly promotes plasminogen activation. In conclusion, EACA was found to inhibit, rather than promote, prourokinase-induced plasminogen activation due to its blocking of the high-affinity lysine binding sites on plasmin(ogen).     

Activation of pro-urokinase by plasmin: non-Michaelian kinetics indicates a mechanism of negative cooperativity

Enzyme kinetic plots relating the initial rate of activation of pro-urokinase to urokinase by plasmin, according to the concentration of substrate, were smooth downward curves and indicated that an apparent decrease in binding affinity occurred with increase in the concentration of pro-urokinase. Such nonlinear plots were obtained with plasmin 1 and also plasmin 2. Over sections of each curve it was possible to estimate apparent kinetic constants. At the uppermost concentrations of substrate tested, these were Km 2.9 microM and kcat 35.5 min-1 for plasmin 1, and at the lowermost concentrations, Km 9.5 nM and kcat 2.0 min-1. Linear plots were obtained when the single proteolytic cleavage was made by K5-plasmin or undegraded plasmin in the presence of 1.0 mM 6-aminohexanoic acid (6-AHa). Constants were estimated for catalysis of this reaction by K5 plasmin to be Km 6.0 microM and kcat 38 min-1 (r = 0.987). The catalytic efficiency of plasmin, at the lowermost concentrations of pro-urokinase tested, was therefore 33-fold higher than that of K5-plasmin. Plotting of data for the cleavage of pro-urokinase by plasmin 1 (in the absence of 6-AHa) according to the model of Hill, gave a slope of 0.5 at the lowermost concentrations of pro-urokinase increasing to 1.0 at higher concentrations (greater than 0.3 microM); such a profile is characteristic of negative cooperativity. The rates of formation of plasmin and urokinase in a mixture containing a low concentration of plasminogen and pro-urokinase were measured and compared to those predicted by a computer program designed to calculate theoretical rates using available kinetic data. The observed rates of generation of both plasmin and urokinase coincided to those predicted from the negative cooperativity model. The mechanism of the negative cooperativity may reside in a conformational change induced by binding of pro-urokinase to the kringle structure of plasmin. This property may be of significance in controlling the fibrinolytic properties of the urokinase-type plasminogen activator system.     

The phosphoenolpyruvate carboxykinase of Trypanosoma (Schizotrypanum) cruzi epimastigotes: molecular, kinetic, and regulatory properties

The phosphoenolpyruvate carboxykinase (ATP:oxaloacetate carboxy-lyase (transphosphorylating), EC 4.1.1.49) of the epimastigote form of Trypanosoma (Schizotrypanum) cruzi has been purified to homogeneity. The enzyme is composed of two apparently identical 42,000 +/- 500 subunits, is highly specific for adenine nucleotides, and has a strict requirement of Mn2+ ions for activity; the activation of the enzyme by ionic Mn2+ reveals that one Mn2+ ion required for each 42,000 subunit. Hyperbolic kinetics are observed for all substrates in the carboxylation reaction with Km (phosphoenolpyruvate) of 0.36 +/- 0.08 mM, Km (HCO-3) of 3.7 +/- 0.2 mM, and Km (Mg-ADP) of 39 +/- 1 microM. In the decarboxylation reaction the kinetics with respect to oxalacetic acid are also hyperbolic with a Km of 27 +/- 3 microM, but towards Mg-ATP there is a biphasic response: hyperbolic at low (less than 250 microM) concentrations with a Km of 39 +/- 1 microM, but at higher concentrations the nucleotide produces a strong inhibition of the enzyme activity. This inhibition is also observed with Mg-GTP and Mg-ITP which are not substrates of the reaction. The results are consistent with an important regulatory function of the enzyme in the amino-acid catabolism of T. cruzi.     

Studies of the role of factor Va in the factor Xa-catalyzed activation of prothrombin, fragment 1.2-prethrombin-2, and dansyl-L-glutamyl-glycyl-L-arginine-meizothrombin in the absence of phospholipid

In order to specifically evaluate the role of Factor Va in the prothrombinase complex, studies of the activation of prothrombin, Fragment 1.2-prethrombin-2, and active-site-blocked meizothrombin were carried out, both in the absence of phospholipid and at concentrations of substrates and Factor Va sufficient to approach saturation in all components. Km values were independent of Factor Va concentrations, whereas kcat (apparent) values approached saturation with respect to Factor Va concentrations. The three respective substrates exhibited the following parameters of kinetics (Km, microM; kcat, s-1 at saturating [Factor Va]): prothrombin (9.0 +/- 0.4; 31 +/- 1); Fragment 1.2-prethrombin-2 (5.4 +/- 0.4; 13 +/- 2); and meizothrombin (3.6 +/- 0.3; 51 +/- 5). Models of kinetics were constructed to interpret the results, and two of these were formally consistent with experimental results. Both models indicated that the variation of kcat(app) with concentrations of Factor Va reflects the formation of a Factor Va-Factor Xa binary complex. Analysis of kinetics indicated Kd values for this interaction of 1.3 +/- 0.1, 3.0 +/- 0.5, and 1.0 +/- 0.1 microM for the three respective substrates. The models differed in the interpretation of Km. One indicated that Km reflects a binary interaction between Factor Xa and prothrombin, whereas the other indicated a binary interaction between Factor Va and prothrombin. Both indicated that two of the three possible binary interactions between the three components would be reflected in Km and kcat values but not the third. To distinguish these models, the binary interactions were studied by extrinsic fluorescence (Va.Xa), light-scattering (Factor Va.prothrombin), and competition kinetics (Xa.II). The first two interactions were detected and were characterized by Kd values of 2.7 +/- 0.1 microM (Va.Xa) and 8.8 +/- 0.8 microM (Factor Va.prothrombin). No active-site-dependent interaction between prothrombin and Factor Xa could be detected in the absence of Factor Va. The results of these studies suggest that Factor Va interacts with both Factor Xa and prothrombin and effectively presents one to the other in the formation of a ternary enzyme-substrate-cofactor complex. In addition, a comparison of the parameters of kinetics of conversion of prothrombin and its intermediates indicates that meizothrombin is the major intermediate of prothrombin activation in the absence, as well as in the presence of phospholipid.