Binding of thrombin to thrombomodulin accelerates inhibition of the enzyme by antithrombin III. Evidence for a heparin-independent mechanism

The endothelial cell surface provides a receptor for thrombin-designated thrombomodulin (TM) which regulates thrombin formation and the activity of the enzyme at the vessel wall surface by serving as a potent cofactor for the activation of protein C by thrombin. Heparin-like structures of the vessel wall have been proposed as another regulatory mechanism catalyzing the inhibition of thrombin by antithrombin III. In the present study, the interaction of antithrombin III with the thrombin-TM complex and its interference with heparin and polycations were investigated by using human components and TM isolated from the microvasculature of rabbit lung. Purified TM bound thrombin and acted as a cofactor for protein C activation. The addition of heparin (0.5 unit/mL) to the reaction mixture interfered neither with the binding of thrombin to TM nor with the activation of protein C. However, the polycations protamine (1 unit/mL) as well as polybrene (0.1 mg/mL) affected the thrombin-TM interaction. This was documented by an increase in the Michaelis constant from 8.3 microM for thrombin alone to 19.5 microM for thrombin-TM with the chromogenic substrate compound S-2238 in the presence of 1 unit/mL protamine. When the inhibition of thrombin by antithrombin III was determined, the second-order rate constant k2 = 8.4 X 10(3) M-1 s-1 increased about 8-fold in the presence of TM, implying an accelerative function of TM in this reaction. Although purified TM did not bind to antithrombin III-Sepharose, suggesting the absence of heparin-like structures within the receptor molecule, protamine reversed the accelerative effect of TM in the inhibition reaction.(ABSTRACT TRUNCATED AT 250 WORDS)     

Characterization of a protein C activator from the venom of Agkistrodon contortrix contortrix

An enzyme capable of activating protein C has been purified 60-fold from the venom of the Southern copperhead snake (Agkistrodon contortrix) by ion-exchange and gel filtration chromatography. The purified enzyme consists of a single polypeptide with an apparent molecular weight of 37,000. The isoelectric point of the protein C activator was determined to be 6.3 when measured by chromatofocusing. The enzyme was inhibited by p-nitrophenyl p-guanidinobenzoate, phenylmethanesulfonyl fluoride, and D-Phe-Pro-Arg-CH2Cl but was not affected by cysteine-directed reagents or by metal chelators. These results suggest that the enzyme is a serine protease. Protein C activator was capable of hydrolyzing the thrombin substrate tosyl-Gly-Pro-Arg-p-nitroanilide (TGPRpNA), and steady-state kinetic studies determined that the Km for amidolysis of this substrate was 1.1 mM while the Vmax was 66 s-1. The activator demonstrated considerable substrate specificity since the amidolysis of D-Phe-Pip-Arg-pNA, D-Ile-Pro-Arg-pNA, Bz-Ile-Glu-Gly-Arg-pNA, D-Val-Leu-Arg-pNA, and pyrGlu-Pro-Arg-pNA was less than 10% of that of TGPRpNA when measured under identical conditions using 1.0 mM substrate concentrations. The enzyme appears to be thrombin-like in its preference for arginyl as compared to lysyl chloromethyl ketones as well as by its inhibition by benzamidine and p-aminobenzamidine. However, the substrate specificity of the activator is distinguished from alpha-thrombin in that it does not clot fibrinogen and does not react with antithrombin III or hirudin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Quail (Coturnix japonica) protamine, full-length cDNA sequence, and the function and evolution of vertebrate protamines

Using the chicken protamine gene as a probe, we have isolated and sequenced several positive clones from a quail testis cDNA library which reveal the complete sequence for the quail protamine cDNA. The predicted amino acid sequence for the quail protamine contains the N-terminal tetrapeptide ARYR present in the N-terminal region of the mammalian protamines as well as several conserved motifs and arginine clusters. In addition the size of the quail protamine (56 amino acids) is closer to that of mammals (50 amino acids) than that of the chicken (61 amino acids). Altogether this data strongly suggests the existence of an avian-mammalian protamine gene line during evolution. Southern blot analysis suggests a small number of copies (2) per haploid genome (similar to that of chicken). The reported quail protamine cDNA sequence is the second avian protamine for which the amino acid sequence is available so far and provides new insights into vertebrate protamine function and evolution.     

Protamine, a substrate for thrombolytic agents and enzymes of similar specificity.

Protamine, a highly purified basic polypeptide of 4000 molecular weight containing 80–85% arginine, is a useful substrate for the assay of plasmin, activated plasminogen, and enzymes of similar specificity, e.g., urokinase, coagulation factor Xa, trypsin, and thrombin, and is also an excellent secondary substrate for activator assays of urokinase and streptokinase. The assays were performed manually, and also automated procedures for continuous multiple sample analyses were used. The relative sensitivities for various plasmin-like enzymes were: trypsin > plasmin > urokinase > factor Xa > thrombin. Using protamine with manual assay procedures, the amino-terminal groups of the enzyme-degraded protamine digestion products were detected and quantitated by the colorimetric ninhydrin or the fluorometric fluorescamine procedures, and using protamine with an automated system the ninhydrin method was used. Assigning the CTA casein assay for plasmin a nominal sensitivity of 0.1 (for 0.1 CTA unit of plasmin), the sensitivities of the various assay methods were casein, automated protamine, and manual protamine with ninhydrin, 0.1; manual protamine-trichloroacetic acid with fluorescamine, 0.005; and manual protamine direct fluorescamine, 0.0005. A unit of plasmin, based on the uptake of 1 μequiv base/min during hydrolysis of 0.4% protamine sulfate under standard conditions, is equal to approximately 1.7 × 10³ RFI units or 2.9 CTA units; or, 1 CTA unit of plasmin resulted in an average uptake of 0.346 μmol of base or equivalent bonds split per minute.     

Identification and characterization of an unusual metallo-β-lactamase from <Emphasis Type="Italic">Serratia proteamaculans</Emphasis>

Metallo-β-lactamases (MBLs) are a family of metalloenzymes that are capable of hydrolyzing β-lactam antibiotics and are an important means by which bacterial pathogens use to inactivate antibiotics. A database search of the available amino acid sequences from Serratia proteamaculans indicates the presence of an unusual MBL. A full length amino acid sequence alignment indicates overall homology to B3-type MBLs, but also suggests considerable variations in the active site, notably among residues that are relevant to metal ion binding. Steady-state kinetic measurements further indicate functional differences and identify two relevant pK _a values for catalysis (3.8 for the enzyme–substrate complex and 7.8 for the free enzyme) and a preference for penams with modest reactivity towards some cephalosporins. An analysis of the metal ion content indicates the presence of only one zinc ion per active site in the resting enzyme. In contrast, kinetic data suggest that the enzyme may operate as a binuclear enzyme, and it is thus proposed that a catalytically active di-Zn²⁺ center is formed only once the substrate is present.     

Specificity of hemorrhagic proteinase from Crotalus atrox (western diamondback rattlesnake) venom

Hemorrhagic proteinase, HTb, isolated from Crotalus atrox (western diamondback rattlesnake) venom was studied for its specificity. HTb showed fibrinogenase activity, hydrolyzing the A alpha chain of fibrinogen first, followed by the cleavage of the B beta chain. HTb is different from thrombin and did not produce a fibrin clot. The degradation products of fibrinogen were found to be different, indicating that the cleavage sites in the A alpha and B beta chains are different from those of thrombin. N-Benzoyl-Phe-Val-Arg-p-nitroanilide was not hydrolyzed by HTb, although this substrate was hydrolyzed by thrombin and reptilase.     

Discovery of amino acid motifs for thrombin cleavage and validation using a model substrate

Understanding the active site preferences of an enzyme is critical to the design of effective inhibitors and to gaining insights into its mechanisms of action on substrates. While the subsite specificity of thrombin is understood, it is not clear whether the enzyme prefers individual amino acids at each subsite in isolation or prefers to cleave combinations of amino acids as a motif. To investigate whether preferred peptide motifs for cleavage could be identified for thrombin, we exposed a phage-displayed peptide library to thrombin. The resulting preferentially cleaved substrates were analyzed using the technique of association rule discovery. The results revealed that thrombin selected for amino acid motifs in cleavage sites. The contribution of these hypothetical motifs to substrate cleavage efficiency was further investigated using the B1 IgG-binding domain of streptococcal protein G as a model substrate. Introduction of a P(2)-P(1)' LRS thrombin cleavage sequence within a major loop of the protein led to cleavage of the protein by thrombin, with the cleavage efficiency increasing with the length of the loop. Introduction of further P(3)-P(1) and P(1)-P(1)'-P(3)' amino acid motifs into the loop region yielded greater cleavage efficiencies, suggesting that the susceptibility of a protein substrate to cleavage by thrombin is influenced by these motifs, perhaps because of cooperative effects between subsites closest to the scissile peptide bond.     

Dissociation of rabbit red blood cell cyclic AMP-dependent protein kinase I by protamine

When protamine is used as the protein substrate for the rabbit red blood cell cyclic AMP-dependent protein kinase I, no dependency on cyclic AMP is observed. It appears that protamine is capable of interacting with the regulatory subunit of kinase I, leading to the dissociation of the regulatory subunit from the catalytic subunit. This releases the catalytic moiety for enzymic activity. The results suggest an alternative mechanism by which protein kinase I may be activated by protein-protein interaction without the participation of the cyclic nucleotide.     

Hydrolysis of protamine by calcium-activated neutral protease (CANP)

To determine the substrate recognition mechanism in calcium-activated neutral protease (CANP), the hydrolytic velocities for some possible substrates were compared. In general, succinylated polypeptides were poorer substrates than unmodified ones, suggesting that CANP interacts with positively charged amino groups and/or repels negatively charged succinyl groups in substrates. Among the substrates examined, protamine was degraded quite rapidly in a restricted manner. This degradation of protamine was remarkably accelerated by the addition of salt, and, in the absence of salt, protamine was inhibitory as to the degradation of vimentin by CANP. Protamine was separated into components and the sites cleaved by CANP were determined. CANP cleaved the clupeine YII and Z components at two sites, both being arginyl-arginine bonds, and the amino acid sequences around these sites were almost identical between YII and Z. No other arginyl-arginine bond was cleaved at all. These results showed that CANP prefers basic amino acid side chains but its specificity is very restricted.     

A novel alkaline serine protease with fibrinolytic activity from the polychaete, Neanthes japonica

A new protease named NJP with fibrinolytic activity was isolated from Neanthes japonica (Izuka), by a combination of ammonium sulfate fractionation, hydrophobic chromatography, ion-exchange chromatography and gel filtration. The molecular mass of NJP was approximately 28.6-33.5kDa as estimated by MALDI-TOF mass spectrometry and SDS-PAGE, which revealed a monomeric form of the protease. The isoelectric point of NJP determined by 2-DE was 9.2. NJP was stable in the range of pH 7.0-11.0 with a maximum enzymatic activity at 40°C and pH 9.0. The hydrolyzing activity of NJP on fibrinogen started from the Aα-chain, followed by the Bβ-chain, and the γ-chain at last. NJP had also a higher specificity for the chromogenic substrate S-2238 for thrombin. NJP activity was completely inhibited by PMSF. Analysis of partial amino acid sequences showed that NJP had very low homology with other known fibrinolytic enzymes. These results indicate that NJP is a novel alkaline thrombin-like serine protease. Thus NJP may have potential applications in the prevention and treatment of thrombosis.     

Purification and characterization of a fibrinolytic enzyme and identification of fibrinogen clotting enzyme in a marine green alga, Codium divaricatum

A fibrinolytic enzyme was isolated from a marine green alga, Codium divaricatum, and designated C. divaricatum protease (CDP). This protease effectively hydrolyzed fibrinogen A alpha chain, while it had very low hydrolyzing efficiency for B beta and gamma chains. This property was similar to that of alpha-fibrinogenase isolated from snake venom. Protease activity peaked at pH 9, and was completely inhibited by diisopropyl fluorophosphate (DFP) and phenylmethylsulfonyl fluoride (PMSF), identifying it as a serine protease. Its molecular form was single polypeptide structure and molecular weight was estimated as 31,000 by SDS-PAGE. Fibrinogen clotting enzyme was also identified in a fraction by ion-exchange chromatography. Analysis of clots formed by the enzyme and by thrombin by SDS-PAGE showed that the fibrinogen clotting enzyme would act like thrombin and have high substrate specificity.     

A very stable and potent fibrinolytic enzyme found in earthworm Lumbricus rubellus autolysate

• 1.1. The autolysate of earthworms was found to exhibit powerful fibrin and thrombin substrate hydrolyzing activity.
• 2.2. It also showed a clot-forming activity in the fibrinogen- or plasma-added system.
• 3.3. Zymography revealed that there were three active components with mol. wts of 40,000, 21,000 and 15,000 in the autolysate.
• 4.4. The major form with a mol. wt 35,500 (by SDS-PAGE) was further purified. The N-terminal amino acid sequence of this enzyme (16 residues) was similar to that of the swine pancreatic proelastase.

     

The Structure And Synthetic Capabilities Of A Catalytic Peptide Formed By Substrate-Directed Mechanism – Implications To Prebiotic Catalysis

Previously, we have shown that a small substrate may serve as a template in the formation of a specific catalytic peptide, a phenomenon which might have had a major role in prebiotic synthesis of peptide catalysts. This was demonstrated experimentally by the formation of a catalytic metallo-dipeptide, Cys₂-Fe²⁺, around o-nitrophenyl β-D-galactopyranoside (ONPG), by dicyandiamide (DCDA)-assisted condensation under aqueous conditions. This dipeptide was capable of hydrolyzing ONPG at a specific activity lower only 1000 fold than that of β galactosidase. In the present paper we use molecular modeling techniques to elucidate the structure of this catalyst and its complex with the substrate and propose a putative mechanism for the catalyst formation and its mode of action as a “mini enzyme”. This model suggests that interaction of Fe²⁺ ion with ONPG oxygens and with two cysteine SH groups promotes the specific formation of the Cys₂-Fe²⁺ catalyst. Similarly, the interaction of the catalyst with ONPG is mediated by its Fe²⁺ with the substrate oxygens, leading to its hydrolysis. In addition, immobilized forms of the catalyst were synthesized on two carriers – Eupergit C and amino glass beads. These preparations were capable of catalyzing the formation of ONPG from β-D-galactose and o-nitrophenol (ONP) under anhydrous conditions. The ability of the catalyst to synthesize the substrate that mediates its own formation creates an autocatalytic cycle where ONPG catalyzes the formation of a catalyst which, in turn, catalyzes ONPG formation. Such autocatalytic cycle can only operate by switching between high and low water activity conditions, such as in tidal pools cycling between wet and dry environments. Implications of the substrate-dependent formation of catalytically active peptides to prebiotic processes are discussed     

Blocking the tunnel: engineering of Candida rugosa lipase mutants with short chain length specificity

The molecular basis of chain length specificity of Candida rugosa lipase 1 was investigated by molecular modeling and site-directed mutagenesis. The synthetic lip1 gene and the lipase mutants were expressed in Pichia pastoris and assayed for their chain length specificity in single substrate assays using triglycerides as well as in a competitive substrate assay using a randomized oil. Mutation of amino acids at different locations inside the tunnel (P246F, L413F, L410W, L410F/S300E, L410F/S365L) resulted in mutants with a different chain length specificity. Mutants P246F and L413F have a strong preference for short chain lengths whereas substrates longer than C10 are hardly hydrolyzed. Increasing the bulkiness of the amino acid at position 410 led to mutants that show a strong discrimination of chain lengths longer than C14. The results obtained can be explained by a simple mechanical model: the activity for a fatty acid sharply decreases as it becomes long enough to reach the mutated site. In contrast, a mutation at the entrance of the tunnel (L304F) has a strong impact on C4 and C6 substrates. This mutant is nevertheless capable of hydrolyzing chain lengths longer than C8.     

Superactivation of thermolysin by acylation with amino acid N-hydroxysuccinimide esters.

Synthesis of a series of active N-hydroxysuccinimide esters of aliphatic and aromatic amino acids has yielded a new class of reagents for the covalent modification of proteolytic enzymes such as thermolysin. The activities of aliphatic acyl amino acid thermolysins are from 1.7 to 3.6 times greater than that of the native enzyme when hydrolyzing durylacryloyl-Gly-Leu-NH2, the substrate employed most widely. By comparison, the aromatic acylamino acid derivatives are "superactive," their activities being as much as 70-fold greater. Apparently, the aromatic character of the amino acid introduced is a critical variable in the determination of the functional response. The increased activity is completely restored to that of the native enzyme by deacylation with nucleophiles, such as hydroxylamine, and the rate of restoration of native activity is a function of the particular acyl group incorporated. Preliminary evidence regarding the chemical properties of the modified enzyme suggests that tyrosine, rather than lysine, histidine, or arginine, may be the residue modified. The functional consequences of successive modification with different reagents, moreover, indicate that each of them reacts with the same protein residue. The competitive inhibitors beta-phenyl-propionyl-Phe and Zn-2+ do not prevent modification with these active esters. Hence, the site(s) of their inhibitory action differ(s) from that at which modification occurs. The structure of the substrate is also a significant variable which determines the rate at which each acyl amino acid thermolysin hydrolyzes peptides. Depending on the particular substrate, the activity of aromatic derivatives can be as much as 400-fold greater than that of the native enzyme, and the resultant activity patterns can be ordered in a series characteristic for each enzyme derivative.     

Substrate specificity and kinetic properties of a soluble nucleoside triphosphatase from bovine kidneys

Soluble nucleoside triphosphatase differing in its properties from all known proteins with NTPase activity was partially purified from bovine kidneys. The enzyme has pH optimum of 7.5, molecular mass of 60 kDa, as estimated by gel chromatography, and shows an absolute dependence on divalent metal ions. NTPase obeyed Michaelis-Menten kinetics in the range of substrate concentration tested from 45 to 440 microM; the apparent Km for inosine-5'-triphosphate was calculated to be 23.3 microM. The enzyme was found to possess a broad substrate specificity, being capable of hydrolyzing various nucleoside-5'-tri- as well as diphosphates.     

Selective plasmalogen substrate utilization by thrombin-stimulated Ca(2+)-independent PLA(2) in cardiomyocytes

Thrombin stimulation of rabbit ventricular myocytes activates a membrane-associated, Ca(2+)-independent phospholipase A(2) (PLA(2)) capable of hydrolyzing plasmenylcholine (choline plasmalogen), plasmanylcholine (alkylacyl choline phospholipid), and phosphatidylcholine substrates. To identify the endogenous phospholipid substrates, we quantified the effects of thrombin stimulation on diradyl phospholipid mass and arachidonic acid and lysophospholipid production. Thrombin stimulation resulted in a selective decrease in arachidonylated plasmenylcholine, with no change in arachidonylated phosphatidylcholine. The decrease in arachidonylated plasmenylcholine was accompanied by an increase in plasmenylcholine species containing linoleic and linolenic acids at the sn-2 position. A decrease in arachidonylated plasmenylethanolamine was also observed after thrombin stimulation, with no concomitant change in arachidonylated phosphatidylethanolamine. Thrombin stimulation resulted in the selective production of lysoplasmenylcholine, with no increase in lysophosphatidylcholine content. There was no evidence for significant acetylation of lysophospholipids to form platelet-activating factor. Arachidonic acid released after thrombin stimulation was rapidly oxidized to prostacyclin. Thus thrombin-stimulated Ca(2+)-independent PLA(2) selectively hydrolyzes arachidonylated plasmalogen substrates, resulting in production of lysoplasmalogens and prostacyclin as the principal bioactive products.     

Mode of action towards oligopeptides and proteins of hydrolase H, a high-molecular-weight aminoendopeptidase from rabbit skeletal muscle

The mode of action towards oligopeptides and proteins of hydrolase H purified from rabbit skeletal muscle was studied. The presence of protamine or alpha-N-benzoylarginine p-nitroanilide (an endopeptidase substrate) changed both the Km and V values of the enzyme towards Leu-beta-naphthylamide (an aminopeptidase substrate). This indicates that the binding site for an endopeptidase substrate is different from that for an aminopeptidase substrate. Hydrolase H as an aminopeptidase displayed broad specificity. The enzyme hydrolyzed various dipeptides readily except the dipeptides containing Pro or an amino acid with a hydrophobic beta-branched chain at the NH2 terminus. Pro and Val at the NH2 terminus of tripeptides were also difficult to release, whereas Ile and Val of tetrapeptides were easily released in contrast with those of dipeptides. The longer the peptide chain of Glyn (n = 2, 3, 4), the more susceptible was it to hydrolase H. Hydrolase H behaved as an endopeptidase only towards protamine among the proteins tested. The other proteins, casein, bovine serum albumin, myofibrils, troponin, hemoglobin, sarcoplasmic proteins, and myoglobin were probably attacked only by the aminopeptidase activity of the enzyme.     

New class of sensitive and selective fluorogenic substrates for serine proteinases. Amino acid and dipeptide derivatives of rhodamine.

A series of dipeptide derivatives of Rhodamine, each containing an arginine residue in the P1 position and one of ten representative benzyloxycarbonyl (Cbz)-blocked amino acids in the P2 position, has been synthesized, purified and characterized as substrates for serine proteinases. These substrates are easily prepared with high yields. Cleavage of a single amide bond converts the non-fluorescent bisamide substrate into a highly fluorescent monoamide product. Macroscopic kinetic constants for the interaction of these substrates with bovine trypsin, human and dog plasmin, and human thrombin are reported. Certain of these substrates exhibit extremely large specificity constants. For example, the kcat./Km for bovine trypsin with bis-(N-benzyloxycarbonylglycyl-argininamido)-Rhodamine [(Cbz-Gly-Arg-NH)2-Rhodamine] is 1 670 000 M-1 X S-1. Certain of these substrates are also highly selective. For example, the most specific substrate for human plasmin, (Cbz-Phe-Arg-NH2)-Rhodamine, is not hydrolysed by human thrombin, and the most specific substrate for human thrombin, (Cbz-Pro-Arg-NH)2-Rhodamine, is one of the least specific substrates for human plasmin. Comparison of the kinetic constants for hydrolysis of the dipeptide substrates with that of the single amino acid derivative, (Cbz-Arg-NH)2-Rhodamine, indicates that selection of the proper amino acid residue in the P2 position can effect large increases in substrate specificity. This occurs primarily as a result of an increase in kcat. as opposed to a decrease in Km and, in certain cases, is accompanied by a large increase in selectivity. Because of their high degree of sensitivity and selectivity, these Rhodamine-based dipeptide compounds should be extremely useful substrates for studying serine proteinases.     

Design of Factor XIII V34X activation peptides to control ability to interact with thrombin mutants

Thrombin helps to activate Factor XIII (FXIII) by hydrolyzing the R37-G38 peptide bond. The resultant transglutaminase introduces cross-links into the fibrin clot. With the development of therapeutic coagulation factors, there is a need to better understand interactions involving FXIII. Such knowledge will help predict ability to activate FXIII and thus ability to promote/hinder the generation of transglutaminase activity. Kinetic parameters have been determined for a series of thrombin species hydrolyzing the FXIII (28-41) V34X activation peptides (V34, V34L, V34F, and V34P). The V34P substitution introduces PAR4 character into the FXIII, and the V34F exhibits important similarities to the cardioprotective V34L. FXIII activation peptides containing V34, V34L, or V34P could each be accommodated by alanine mutants of thrombin lacking either the W60d or Y60a residue in the 60-insertion loop. By contrast, FXIII V34F AP could be cleaved by thrombin W60dA but not by Y60aA. FXIII V34P is highly reliant on the thrombin W215 platform for its strong substrate properties whereas FXIII V34F AP becomes the first segment that can maintain its K(m) upon loss of the critical thrombin W215 residue. Interestingly, FXIII V34F AP could also be readily accommodated by thrombin L99A and E217A. Hydrolysis of FXIII V34F AP by thrombin W217A/E217A (WE) was similar to that of FXIII V34L AP whereas WE could not effectively cleave FXIII V34P AP. FXIII V34F and V34P AP show promise for designing FXIII activation systems that are either tolerant of or greatly hindered by the presence of anticoagulant thrombins.