Activation of rat liver guanylate cyclase by proteolysis.

Guanylate cyclase activity (GTP pyrophosphate-lyase (cyclizing), EC 4.6.1.2.), measured in purified rat liver plasma membranes, was markedly increased by treatment with various purified proteases. The effect was maximal with trypsin, alpha-chymotrypsin, papain, and thermolysin (6- to 8-fold increase with 5 to 20 microgram of protease/ml) and lower with subtilisin and elastase (3- to 4-fold increase). The activation was due to an increase in the maximal velocity of the cyclizing reaction. No modification was observed either in the apparent affinity for the substrate MnGTP or in the cooperative behavior of the enzyme kinetics which displayed Hill coefficients of 1.6 for both basal and activated states. The Triton X-100-dispersed guanylate cyclase remained sensitive to papain, which suggests that the action of proteases was not restricted to an indirect action upon the membranous environment of the guanylate cyclase. In contrast, the cytosolic soluble guanylate cyclase, assayed in the presence or absence of sodium azide, was absolutely insensitive to papain. Thus, proteolysis represents a previously undescribed mechanism for activating membranous guanylate cyclase systems, which might be of importance in the physiological regulation of this enzyme.     

Study of the interaction of trypsin inhibitor from the sea anemone Radianthus macrodactylus with proteases

The interaction of the inhibitor VJ (InhVJ), isolated from sea anemone R. macrodactylus, with different proteases was investigated using the method of biosensor analysis. The following enzymes were tested: serine proteases (trypsin, α-chymotrypsin, plasmin, thrombin, kallikrein), cysteina protease (papain) and aspartic protease (pepsin). In the rage of the concentrations studied (10–400 nM) inhibitor VJ interacted only with trypsin and α-chymotrypsin. The intermolecular complexes formation between inhibitor VJ and each of these enzymes was characterized by the following kinetic and thermodynamics parameters: K_D = 7.38 × 10^?8 M and 9.93 × 10^?7 M for pairs InhVJ/trypsin and InhVJ/α-chymotrypsin, respectively.     

A possible approach to the analysis of protease mixtures

A problem of quantitative assay of proteases in complex mixtures is solved by using a set of peptide substrates with detectable (chromogenic or fluorogenic) groups (DGs). Quantitation of separate DGs released in reaction of enzyme mixture with a set of substrates is carried out in chromatographic analysis of reaction products. Reaction of peptide derivatives of aminonaphthalene sulfamides with a mixture of thrombin and proteases from viper venom shows the amounts of produced DGs to be proportional to the amounts of both thrombin and venom proteases, confirming the validity of proposed approach. There are cases of mutual influence of some components in proteases mixtures as illustrated by inhibition of trypsin activity in presence of viper venom; one determines enzyme activities in this specific mixture rather than their amounts.     

Preparation and properties of soluble-insoluble immobilized proteases

In order to carry out an effective enzyme reaction, the preparation of soluble-insoluble immobilized enzyme was investigated. Proteases were selected as model enzymes, and their immobilization was carried out by using an enteric coating polymer as a carrier. Among the polymers tested, methacrylic acid-methylacrylate-methylmethacrylate copolymer (MPM-06) gave the most active soluble-insoluble immobilized papain. This immobilized papain showed insoluble from below pH 4.8 and soluble form above pH 5.8; it was also soluble in water-miscible organic solvent. It was reusable and more stable with heat and water-miscible organic solvents than native proteases. Furthermore, various proteases could be immobilized by using MPM-06 with high activity. Chymotrypsin immobilized by this method catalyzed the effective peptide synthesis in a heterogeneous reaction system containing water-miscible organic solvent.     

Glial-derived neurite-promoting factor is a slow-binding inhibitor of trypsin, thrombin, and urokinase

Glial-derived neurite-promoting factor was found to be a slow-binding inhibitor of trypsin, urokinase, and thrombin. The kinetic mechanism of the inhibition differs among the three proteases. With trypsin and urokinase, an initial protease-factor complex formed which isomerized to a tighter complex. For thrombin, however, no initial complex was kinetically observed. The dissociation constants of the equilibrium complexes of the factor with trypsin, urokinase, and thrombin were 17, 280, and 18 pM, respectively, and the apparent second-order rate constants for the interaction of the factor with these enzymes were, respectively, 4.7 X 10(6), 1.2 X 10(5), and 2.1 X 10(6) M-1S-1. Heparin increased the rate at which the factor reacted with thrombin by over 40-fold to 8.9 X 10(7) M-1S-1 and decreased the dissociation constant of the complex by over 80-fold to 0.3 pM. The values obtained for the apparent second-order rate constants when compared with the kinetics of neurite induction by the factor indicate that the neurite-promoting activity of the factor is not due to the inhibition of urokinase but could be due to the inhibition of an enzyme with a specificity similar to that of thrombin or trypsin. Comparison of the values of the apparent second-order rate constants obtained for the factor with those obtained for protease nexin suggests that these two molecules are very similar in their inhibitory properties.     

Thrombin-platelet interactions: an assessment of the roles of saturable and nonsaturable binding in platelet activation

Thrombin binds to platelets and induces platelet activation, but the relationship of binding to activation is not clear. To better define this relationship, we have analyzed parameters of binding and activation by alpha-thrombin and by three analogous proteases that activate platelets somewhat differently. The proteases were nitro-alpha-thrombin, a derivative with nitrated tyrosine, gamma-thrombin, a product of partial proteolysis of alpha-thrombin, and trypsin, a homologous protease. Nitro-alpha-thrombin and native alpha-thrombin activated platelets similarly, whereas gamma-thrombin and trypsin activated to a slightly lesser extent than alpha-thrombin and only after a distinctive delay. alpha-Thrombin and nitro-alpha-thrombin bound to platelets to about the same extent, but only alpha-thrombin showed evidence of saturable binding. Hirudin, a thrombin inhibitor, blocked both platelet activation and saturable binding by alpha-thrombin. With nitro-alpha-thrombin, hirudin blocked platelet activation, but it had no effect on binding. gamma-Thrombin and trypsin bound less than alpha-thrombin and with no evidence of saturable binding. There were identical relationships between the total amount bound and the extent of platelet activation for the four proteases (some show no saturable binding) but distinct differences in the relationships of total amount bound and the rate of activation; similar rates of activation required the binding of three to five times more gamma-thrombin or trypsin than alpha-thrombin. That is, without saturable binding, activation was slower. These data thus show a correlation between total amount bound and extent of activation but no correlation between amount saturably bound and the extent of platelet activation. Conversely, the rate of activation is more closely correlated with saturable binding than with total binding. We conclude that high-affinity saturable binding is not essential for thrombin-induced platelet activation but that it may accelerate the reaction.     

Specificity of thrombin: evidence for selectivity in acylation rather than binding for p-nitrophenyl alpha-amino-p-toluate.

The lysyl ester analogue p-nitrophenyl alpha-amino-p-toluate hydrobromide was synthesized, and its reactions with thrombin, trypsin, and plasmin were studied by stopped-flow and conventional methods. Kinetic parameters were compared with those determined for the arginyl ester analogue, p-nitrophenyl p-guanidinobenzoate hydrochloride, with these enzymes. By following nitrophenol release or proflavin absorption changes in the stopped-flow spectrophotometer, the constants Ks (enzyme-substrate binding), k2 (acylation), and k3 (deacylation) were determined. The major findings were: (1) Ks values were similar regardless of the substrate or the enzyme; (2) k3 was approximately the same for the reaction of the lysyl ester analogue with any enzyme; (3) k2 for the lysyl ester analogue was 1100 times greater with trypsin than with thrombin; and (4) k2 with thrombin was 60 times greater for the arginyl than for the lysyl ester analogue. The results suggest that the limited cleavage of lysyl bonds by thrombin is due in part to restricted acylation rather than substrate binding. The active site of thrombin, compared with that of trypsin, appears to have a more stringent requirement for the spatial relationship between the cationic group and the bond cleaved in substrates.     

Neutrophil cathepsin G promotes prothrombinase and fibrin formation under flow conditions by activating fibrinogen-adherent platelets

Human neutrophil proteases cathepsin G and elastase can directly alter platelet function and/or participate in coagulation cascade reactions on the platelet or neutrophil surface to enhance fibrin formation. The clotting of recalcified platelet-free plasma (PFP) or platelet-rich plasma (PRP) supplemented with corn trypsin inhibitor (to shut down contact activation) was studied in well-plates or flow assays. Inhibitors of cathepsin G or elastase significantly delayed the burst time (t(50)) of thrombin generation in neutrophil-supplemented PRP from 49 min to 59 and 77 min, respectively, in well-plate assays as well as reduced neutrophil-promoted fibrin deposition on fibrinogen-adherent platelets under flow conditions. In flow assays, purified cathepsin G was a far more potent activator of platelet-dependent coagulation than elastase. Anti-tissue factor had no effect on neutrophil protease-enhanced thrombin formation in PRP. The addition of cathepsin G (425 nm) or convulxin (10 nm) to PRP dramatically reduced the t(50) of thrombin generation from 53 min to 17 or 23 min, respectively. In contrast, the addition of elastase to PRP left the t(50) unaltered. Whereas perfusion of PFP (gamma(w) = 62.5 s(-1)) over fibrinogen-adherent platelets did not result in fibrin formation until 50 min, massive fibrin could be observed on cathepsin G-treated platelets even at 35 min. Cathepsin G addition to corn trypsin inhibitor-treated PFP produced little thrombin unless anionic phospholipid was present. However, further activation inhibition studies indicated that cathepsin G enhances fibrin deposition under flow conditions by elevating the activation state of fibrinogen-adherent platelets rather than by cleaving coagulation factors.     

Receptor and G protein-mediated responses to thrombin in HEL cells.

Thrombin is believed to activate platelets via cell surface receptors coupled to G proteins. In order to better understand this process, we have examined the interaction of thrombin with HEL cells, a leukemic cell line that has served as a useful model for studies of platelet structure and function. In HEL cells, as in platelets, thrombin stimulated inositol trisphosphate (IP3) formation and suppressed cAMP synthesis. Both events were inhibited by pertussis toxin with 50% inhibition occurring at a toxin concentration that ADP-ribosylated 50% of the Gi alpha subunits present in HEL cells. IP3 formation was also stimulated by a second serine protease, trypsin. The trypsin response was identical to the thrombin response in time course, magnitude, and pertussis toxin sensitivity, suggesting that a similar mechanism is involved. Agonist-induced changes in the cytosolic-free Ca2+ concentration were used to test this hypothesis. Both proteases caused a transient increase in intracellular calcium [Ca2+]i that could be inhibited with D-phenylalanyl-L-prolyl-L-arginine chloromethyl ketone thrombin. Exposure to either protease desensitized HEL cells against subsequent increases in [Ca2+]i and IP3 caused by the other, although responses to other agonists were retained. This loss of responsiveness persisted despite repeated washing of the cells and the addition of hirudin. Complete recovery occurred after 20 h and could be prevented with cycloheximide. These observations suggest that 1) HEL cell thrombin receptors, like those on platelets, are coupled to phospholipase C and adenylylcyclase by pertussis toxin-sensitive G proteins, 2) the G proteins involved are equally accessible to pertussis toxin in situ, 3) when access is limited to the outside of the cell the response mechanisms for thrombin and trypsin are similar, if not identical, despite the broader substrate specificity of trypsin, 4) both proteases cause persistent changes that may involve proteolysis of their receptors or associated proteins, and 5) desensitization of the thrombin response occurs at a step no later than the activation of phospholipase C and requires protein synthesis for recovery.     

Reactions of papain and of low-molecular-weight thiols with some aromatic disulphides. 2,2′-Dipyridyl disulphide as a convenient active-site titrant for papain even in the presence of other thiols

1. The u.v.-spectral characteristics of 5,5'-dithiobis-(2-nitrobenzoic acid) (Nbs(2)), 2,2'-dipyridyl disulphide (2-Py-S-S-2-Py), 4,4'-dipyridyl disulphide (4-Py-S-S-4-Py), 5-mercapto-2-nitrobenzoic acid (Nbs), 2-thiopyridone (Py-2-SH) and 4-thiopyridone (Py-4-SH) were determined over a wide range of pH and used to calculate their acid dissociation constants. 2. The reactions of l-cysteine, 2-mercaptoethanol and papain with the above-mentioned disulphides were investigated spectrophotometrically in the pH range 2.5-8.5. 3. Under the conditions of concentration used in this study the reactions of both low-molecular-weight thiols with all three disulphides resulted in the stoicheiometric release of the thiol or thione fragments Nbs, Py-2-SH and Py-4-SH at all pH values. The rates of these reactions are considerably faster at pH8 than at pH4, which suggests that the predominant reaction pathway in approximately neutral media is nucleophilic attack of the thiolate ion on the unprotonated disulphide. 4. The reaction of papain with Nbs(2) is markedly reversible in the acid region, and the pH-dependence of the equilibrium constant for this system in the pH range 5-8 at 25 degrees C and I=0.1 is described by: [Formula: see text] 5. Papain reacts with both 2-Py-S-S-2-Py and 4-Py-S-S-4-Py in the pH range 2.5-8.5 to provide release of the thione fragments, stoicheiometric with the thiol content of the enzyme. 6. Whereas the ratios of the second-order rate constant for the reaction at pH4 to that at pH8 for the cysteine-2-Py-S-S-2-Py reaction (k(pH4)/k(pH8)=0.015) and for the papain-4-Py-S-S-4-Py reaction (k(pH4)/k(pH8)=0.06) are less than 1, that for the papain-2-Py-S-S-2-Py reaction is greater than 1 (k(pH4)/k(pH8)=15). 7. This high reactivity of papain has been shown to involve reaction of the thiol group of cysteine-25, the enzyme's only cysteine residue, which is part of its catalytic site. 8. That this rapid and stoicheiometric reaction of the thiol group of native papain is not shown either by low-molecular-weight thiols or by the thiol group of papain after its active conformation has been destroyed by acid or heat denaturation, strongly commends 2-Py-S-S-2-Py as one of the most useful papain active-site titrants discovered to date. This reagent has been shown to allow accurate titration of papain active sites in the presence of up to 10-fold molar excess of l-cysteine and up to 100-fold molar excess of 2-mercaptoethanol.     

Persistent activation of platelet membrane phospholipase C by proteolytic action of trypsin and thrombin

Trypsin causes rapid activation of intact platelets that mimics many actions of thrombin, including the stimulation of phospholipase C (PLC). We have examined the effects of thrombin and trypsin on PLC in a platelet membrane preparation using exogenous [3H]-phosphatidylinositol 4,5-bisphosphate (PIP2) as substrate. Trypsin induced PIP2 breakdown, which was maximal at 20 micrograms/ml, but was reduced at higher concentrations. alpha- and gamma-Thrombins also stimulated PLC-induced hydrolysis of PIP2 in membranes. This effect was inhibited by leupeptin. Exogenous [3H]phosphatidylinositol 4-monophosphate (PIP) was hydrolyzed in response to both thrombin and trypsin in the same ratio as PIP2. Activation of membrane-bound PLC persisted after removal of thrombin and trypsin. The hydrolysis of [3H]phosphatidylinositol was not activated by alpha-thrombin and trypsin. We examined the question of whether calpain was involved in the observed PLC activation by thrombin and trypsin. Although dibucaine activated a Ca2(+)-dependent protease as judged by the hydrolysis of actin-binding protein and by the activation of phosphoprotein phosphatases, it failed to stimulate the generation of phosphatidic acid in 32P-prelabeled platelets. Moreover, when PLC was assayed in the membranes, the addition of Ca2(+)-activated neutral proteinases did not increase the rate of hydrolysis of either PIP or PIP2. Our results show that proteases such as trypsin and thrombin are able to stimulate membrane-bound PLC, but this activation does not seem to be related to calpain.     

Conditions which affect initiation of animal cell division by trypsin and thrombin

It has been well documented that trypsin or thrombin initiate proliferation of quiescent secondary chick embryo cells. However, there has been less certainty about the ability of these proteases to initiate division of quiescent mammalian cells. Accordingly, we studied the conditions under which quiescent chick embryo (CE), mouse embryo (ME), and human diploid foreskin (HF) cells respond to trypsin or thrombin Extended culture of these cell strains in serum-free medium increased the initiation of cell division by both proteases. Under these conditions, CE cell number was increased 90% over controls by trypsin and 70% by thrombin. In contrast, quiescent ME and HF cells both responded better to thrombin than trypsin, giving maximal increases, respectively, of 70 and 40% over controls with thrombin and 22 and 14% with trypsin. Calf serum inhibited the initiation of these cell strains, particularly the ME cells, by both trypsin and thrombin. This inhibition of initiation could be attributed to decreased proteolytic activity in the case of trypsin, but not thrombin In contrast to the cell strains tested, quiescent cultures of the 3T3 cell line showed no detectable increase in cell number with trypsin or thrombin in the absence of serum, and only a slight increase in cell number with thrombin in the presence of serum. However, in the presence of plasma, 3T3 cell number increased up to 20% with thrombin Initiation of cell division by proteases has been reported and confirmed mostly for early passage cell strains rather than cell lines. Our experiments with CE cells indicate that this is possibly the result of a rapid decline in protease responsiveness upon serial subculture. With these cells we found a decline in response first to trypsin, then thrombin, and finally serum Throughout these studies, we compared the ability of trypsin and thrombin to initiate cell division under various conditions. We found several differences between the two proteases, indicating that they initiate cell division by somewhat different mechanisms.     

Plant lipases: biocatalyst aqueous environment in relation to optimal catalytic activity in lipase-catalyzed synthesis reactions.

Adsorption and desorption isotherms of two commercial enzyme preparations of papain and bromelain were determined with a Dynamic Vapor System. The Guggenheim-Anderson-deBoer (GAB) modeling of the obtained sorption isotherms allowed the definition of different levels of hydration of those samples. Afterward, these enzyme preparations were used as biocatalysts in water and solvent-free esterification and alcoholysis reactions. The evolution of the obtained fatty acid ester level as a function of the initial hydration level of the biocatalyst, i.e., thermodynamic water activity (a(w)) and water content, was studied. The results show an important correlation between the initial hydration level of the biocatalyst and its catalytic activity during the lipase-catalyzed synthesis reactions. Thus, the Carica papaya lipase (crude papain preparation) catalytic activity is highly dependent on the biocatalyst hydration state. The optimized synthesis reaction yield is obtained when the a(w) value of the enzyme preparation is stabilized at 0.22, which corresponds to 2% water content. This optimal level of hydration occurs on the linear part of the biocatalyst's sorption isotherm, where the water molecules can form a mono- or multiple layer with the protein network. The synthesis reaction yield decreases when the a(w) of the preparation is higher than 0.22, because the excess water molecules modify the system equilibrium leading to the reverse and competitive reaction, i.e., hydrolysis. These results show also that an optimal storage condition for the highly hydrophilic crude papain preparation is a relative humidity strictly lower than 70% to avoid an irreversible structural transition leading to a useless biocatalyst. Concerning the bromelain preparation, no effect of the hydration level on the catalytic activity during esterification reactions was observed. This biocatalyst has too weak a catalytic activity which makes it difficult to observe any differences. Furthermore, the bromelain preparation is far more hydrophobic as it adsorbs only 18 g of water per 100 g of dry material at a(w) around 0.90. No deliquescence of this enzymatic preparation is observed at this a(w) value.     

Flu virion as a substrate for proteolytic enzymes

The proteolysis of flu virions of the strain A/Puerto Rico/8/34 (subtype H1N1) by enzymes of various classes was studied to develop an approach to the study of the structural organization and interaction of the basic protein components of the virion environment: hemagglutinin (HA), transmembrane homotrimeric glycoprotein, and matrix protein M1 forming a layer under the lipid membrane. Among the tested proteolytic enzymes and enzymic preparations (thermolysin, trypsin, chymotrypsin, subtilisin Carlsberg, pronase, papain, and bromelain), the cysteine proteases bromelain and papain and the enzymic preparation pronase efficiently deleted HA ectodomains, while chymotrypsin, trypsin, and subtilisin Carlsberg deleted only a part of them. An analysis by MALDI TOF mass spectrometry allowed us to locate the sites of HA hydrolysis by various enzymic preparations. Bromelain, papain, trypsin, and pronase split the polypeptide chain after the K177 residue located before the transmembrane domain (HA2 185-211). Subtilisin Carlsberg hydrolyzed the peptide bond at other neighboring points: after L178 (a basic site) or V176. The hydrolytic activity of bromelain measured by a highly specific chromogenic substrate of cysteine proteases Glp-Phe-Ala-pNA was almost three times higher in the presence of 5 mM beta-mercaptoethanol than in the presence of 50 mM. However, the complete removal of exodomains of HA, HA, and low-activity enzyme by the HA high- and low-activity enzyme required identical time intervals. In the absence of the reducing reagent, the removal of HA by bromelain proceeded a little more slowly and was accompanied by significant fragmentation of protein Ml1. The action of trans-epoxysuccinyl-L-leucylamido)butane (E-64), a specific inhibitor of cysteine proteases, and HgCl2 on the hydrolysis of proteins HA and M1 by bromelain was investigated.     

The novel serpin endopin 2 demonstrates cross-class inhibition of papain and elastase: localization of endopin 2 to regulated secretory vesicles of neuroendocrine chromaffin cells

This study demonstrates that endopin 2 is a unique secretory vesicle serpin that displays cross-class inhibition of cysteine and serine proteases, indicated by effective inhibition of papain and elastase, respectively. Homology of the reactive site loop (RSL) domain of endopin 2, notably at P1-P1' residues, with other serpins that inhibit cysteine and serine proteases predicted that endopin 2 may inhibit similar proteases. Recombinant N-His-tagged endopin 2 inhibited papain and elastase with second-order rate constants (k(ass)) of 1.4 x 10(6) and 1.7 x 10(5) M(-1) s(-1), respectively. Endopin 2 formed SDS-stable complexes with papain and elastase, a characteristic property of serpins. Interactions of the RSL domain of endopin 2 with papain and elastase were indicated by cleavage of endopin 2 near the predicted P1-P1' residues by these proteases. Endopin 2 did not inhibit the cysteine protease cathepsin B, or the serine proteases chymotrypsin, trypsin, plasmin, and furin. Endopin 2 in neuroendocrine chromaffin cells was colocalized with the secretory vesicle component (Met)enkephalin by confocal immunonfluorescence microscopy, and was present in isolated secretory vesicles (chromaffin granules) from chromaffin cells as a glycoprotein of 72-73 kDa. Moreover, regulated secretion of endopin 2 from chromaffin cells was induced by nicotine and KCl depolarization. Overall, these results demonstrate that the serpin endopin 2 possesses dual specificity for inhibiting both papain-like cysteine and elastase-like serine proteases. These findings demonstrate that endopin 2 inhibitory functions may occur in the regulated secretory pathway.     

The reaction of bovine thrombin with N-butyrylimidazole. Two different reactions resulting in the inhibition of catalytic activity.

N-Butyrylimidazole has been found to be a potent inhibitor of purified bovine thrombin. The rate and extent of inhibition of thrombin by N-butyrylimidazole could be reduced by the presence of benzamidine, a competitive inhibitor, or by the ester substrate, p-tosyl-L-arginine methyl ester. Spectral studies of the reaction of N-butyrylimidazole with thrombin demonstrated the modification of approximately 1 mol of tyrosine/mol of enzyme at maximum inhibition. In addition to the reaction with tyrosine, N-butyrylimidazole also appears to react with a residue at the "active site" as judged by a decrease in the number of active sites available in the modified enzyme for titration with p-nitrophenyl-p'-guanidinobenzoate. The time course of ester hydrolysis by butyrylated thrombin showed a distinct lag phase suggesting partial reactivation of the enzyme under assay conditions. Partial reactivation of the modified enzyme also occurred spontaneously upon standing in 0.5 M NaCl but was much faster in presence of imidazole (0.03 M, pH 7.6). It is suggested that, in addition to reaction with tyrosine, there is a reaction of N-butyrylimidazole with either the histidine and/or serine residue at the active site of thrombin resulting in a derivative unstable under esterase assay conditions such as that described for the reaciton of N-acetylimidazole with trypsin (L. L. Houston and K. A. Walsh (1970), Biochemistry 9, 156).     

Amphibian embryo protease inhibitors. IV. Studies on an inhibitor of chymotrypsin and papain

Amphibian embryo chymotrypsin and papain inhibitor (ACPI) purified by the procedure described in this paper produces a single band on sodium dodecyl sulfate (SDS) gel electrophoresis and a single peak on Sephadex G-75 chromatography. Except for its enzyme specificity, ACPI is very similar to amphibian embryo trypsin inhibitor (ATI). Its molecular weight is about 10,500 and its amino acid composition is typical of many naturally occurring protease inhibitors. Inhibition develops slowly, is retarded by the presence of substrate and is temporary. ACPI is localized in the yolk platelets and its disappearance both from whole embryos and from select tissue types corresponds closely with that of ATI. Possible roles for amphibian embryo proteases and protease inhibitors in development are discussed.     

Inactivation of thrombin by murine peritoneal macrophages.

We recently showed that murine peritoneal macrophages cultured in vitro express potent prothrombinase activity (Lindahl, U., Pejler, G., B?gwald, J., and Seljelid, R. (1989) Arch. Biochem. Biophys. 273, 180-188). In the present report, we demonstrate that the macrophages also express anticoagulant activity by inactivating the thrombin that is formed due to the action of the prothrombinase. Addition of exogenous purified thrombin to the macrophage cultures resulted in inactivation of the enzyme at a maximum rate of approximately 5 micrograms/h/10(6) cells. The inactivation appeared to be specific for thrombin, since neither Factor Xa, chymotrypsin, nor trypsin, three serine proteases exhibiting homology with thrombin, were inactivated by the macrophages. Thrombin-inactivating activity was not secreted into the culture medium. Inhibitors of endocytosis did not decrease the rate by which thrombin was inactivated, suggesting that internalization of the coagulation factor was not required. In contrast, the thrombin-inactivating activity was strongly inhibited by the polycation Polybrene. Anion-exchange chromatography of extracts obtained after Triton X-100-solubilization of the macrophages demonstrated that the thrombin-inactivating activity exhibited a high negative charge. Incubation of the thrombin-inactivating activity recovered after anion-exchange chromatography with unlabeled thrombin, followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis, showed that thrombin was proteolytically cleaved into defined fragments. Similar proteolytic fragments were obtained when 125I-labeled thrombin was added to macrophage cultures. Degradation of thrombin was blocked by phenylmethanesulfonic fluoride, an inhibitor of serine proteases, but not by inhibitors of other classes of proteases. Thrombin that had been chemically modified at its active site was degraded at the same rate by the macrophages as active thrombin. Taken together, these findings indicate that the murine macrophages express surface-bound serine protease activity that specifically inactivates thrombin by proteolytic cleavage. The significance of thrombin-inactivating activity in relation to the involvement of macrophage procoagulant activity in the immune response is discussed.     

Vanadium inhibition of serine and cysteine proteases.

A study was made on the effect of vanadium, in both the tetravalent state in vanadyl sulphate and in the pentavalent state in sodium meta-vanadate, and ortho-vanadate, on the proteolysis of azocasein by two serine proteases, trypsin and subtilisin and two cysteine proteases bromelain and papain. Also the proteolysis of bovine azoalbumin by serine proteases was considered. An inhibitory effect was present in all cases, except meta-vanadate with subtilisin. The oxidation level of vanadium by itself did not determine the inhibition kinetics, which also depended on the type and composition of the vanadium containing molecule and on the enzyme assayed. The pattern of inhibition was similar for proteases belonging to the same class. The highest inhibition was obtained with meta-vanadate on papain and with vanadyl sulphate on bromelain.     

Thrombin-like inhibitory action of trypsin and trypsin-like proteases on human platelet adenylate cyclase

The effects of trypsin, acrosin and a recently described trypsin-like protease from bovine sperm were studied on adenylate cyclase activity in membranes of human platelets. These proteases caused an immediate decrease in adenylate cyclase activity, which was independent of the platelet membrane concentration used and which was constant for up to 20 min of incubation at 25 degrees C. When the incubation was prolonged, the proteases eliminated their own inhibitory action as well as that of the inhibitory hormone epinephrine. The adenylate cyclase inhibition caused by the proteases was strictly dependent on the presence of GTP (EC50 approximately 0.1 microM), whereas in the absence of GTP only minor changes in enzyme activity were observed at the conditions and protease concentrations used. Maximal inhibition caused by the proteases was between 40% and 60%. Half-maximal inhibition by the purified proteases trypsin and acrosin was observed at about 30 ng/ml and 2 micrograms/ml respectively. Inhibition of platelet adenylate cyclase by the proteases was partially additive with that caused by epinephrine, while with thrombin no additivity was observed. The serine protease inhibitor leupeptin blocked the actions of the proteases when added simultaneously with the enzymes, but was ineffective when added later on. Treatment of platelet membranes with the alkylating N-ethylmaleimide at low concentrations and Mn2+ ions (greater than or equal to 1 mM), both agents known to abolish inhibition of adenylate cyclase via the inhibitory guanine-nucleotide-binding protein Gi, eliminated the inhibitory action of the proteases. The data indicate that trypsin and trypsin-like proteases have two opposite effects on the platelet adenylate cyclase system, the well-documented elimination of Gi action and, as shown here, an immediate activation of Gi with subsequent adenylate cyclase inhibition. The data are consistent with the hypothesis that the activation of Gi caused by the proteases is due to an interaction of the proteases with specific cell-surface receptor sites in a manner similar to thrombin.