Effect of monovalent cations on bovine alpha- and beta-thrombin: importance of substrate structure

Kinetic pathway for the slow to fast transition of thrombin. Evidence of linked ligand binding at structurally distinct domains

The kinetic pathway for the Na+-induced slow --> fast transition of thrombin was characterized. The slow form was shown to consist of two conformers in a 3:1 ratio (ES2:ES1) at 5 degrees C, pH 7.4, Gamma/2 0.3. ES2 binds Na+ 3 orders of magnitude faster than does ES1. The small molecule active site-directed inhibitor L-371,912, and the exosite I binding ligand hirugen, like Na+, bind selectively to ES2 and induce the slow --> fast conversion of thrombin. The slow --> fast transition is limited by the rate of conversion of ES1 to ES2 (k approximately 28 s-1 at 5 degrees C). Replacement of Arg-221a or Lys-224 at the Na+ binding site with Ala appears to selectively alter the slow form and reduce the apparent affinity of the mutants for Na+ and L-371,912. This replacement, however, has little effect on the affinity for the inhibitor in the presence of saturating concentrations of Na+. The kinetically linked ligand binding at the Na+ binding site, exosite I, and the active site of thrombin characterized in the present study indicates the basis for the plasticity of this important enzyme, and suggests the possibility that the substrate specificity and, therefore, the procoagulant and anticoagulant activities of thrombin may be subject to allosteric regulation by as yet unidentified physiologically important effectors.

Affinity chromatography of platelets on immobilized thrombin: retention of catalytic activity by platelet-bound thrombin

Radioactivity from I125-labeled human platelets was measured to estimate the extent of binding of platelet surface proteins to immobilized thrombin. 1-3% of the radioactivity was bound with 10-20% of this amount apparently irreversibly bound to the thrombin matrix. Site-specific chemical modification of thrombin with pyridoxal-5'-phosphate, N-bromosuccinimide or tetranitromethane resulted in a variable reduction of the amount of radiolabel bound. When thrombin modified with H-D-PheProArg-chloromethyl ketone (PPACK) was coupled to the matrix, there was no difference in the binding of platelet membrane proteins when compared to a control thrombin preparation while thrombin modified with tosyl-Lys-chloromethyl ketone (TLCK) coupled to the matrix did not bind radiolabel any more effectively than albumin which served as the control. However, when thrombin was modified with PPACK after coupling to the agarose matrix, ability to bind radiolabel was lost. Thrombin bound to platelets remained catalytically active when assayed with a peptide nitroanilide substrate. These results suggest tight binding between thrombin and platelets that is not only not dependent on active site integrity but leaves the bound thrombin catalytically competent.

Influence of divalent and monovalent cations on some active site properties of human factor Xa

The effect of divalent and monovalent cations on the hydrolysis of BzIleGlu(OR)GlyArgpNA(S-2222) was compared to the rate of inactivation of factor Xa by dansyl-GluGlyArg-chloromethylketone(DERG-CK). At substrate concentrations below Km, an approximate four-fold increase in amidase activity was observed in the presence of manganese ions while a three-fold increase was observed with calcium ions. The presence of magnesium ions resulted in a two-fold increase in amidase activity. Similar increases in the rate of inactivation of factor Xa by DERG-CK were observed. Na+ ions had a marked enhancing effect of both factor Xa amidase activity and inactivation by DERG-CK. Kinetic parameters for the hydrolysis of S-2222 by factor Xa were obtained in the presence and absence of Ca++ and Na+. Vmax values increased in the presence of either Ca++ or Na+. Km values increased in the presence of Ca++ while there was a modest decrease in Km in the presence of Na+. It is suggested that the enhanced activity of factor Xa is a reflection of changes in the reactivity of active site residues.

The assay of glandular kallikrein and prekallikrein in human mixed saliva

The measurement of glandular kallikrein in biological fluids most often utilizes a synthetic substrate, H-D-valylleucylarginine-p-nitroanilide (S-2266), which assesses amidase activity. Although this substrate has reasonable specificity for glandular kallikrein, other tryptic-like proteases found in mixed saliva may also cause hydrolysis. The primary purpose of this study was to assess the accuracy of the use of this substrate for the measurement of glandular kallikrein in human mixed saliva. An additional objective was to determine the presence of prekallikrein in mixed saliva. The addition of soybean trypsin inhibitor (SBTI), which inhibits other tryptic-like enzymes but not glandular kallikrein, resulted in an approx. 30 per cent decrease in the hydrolysis of S-2266 by centrifuged mixed human saliva. A correlation of 0.918 was obtained between the biological assays for kinin release and amidase activity in 19 subject samples. Amidase activity increased following treatment of saliva with trypsin, indicating the presence of prekallikrein in human mixed saliva. It is concluded that S-2266 is an accurate substrate for the assay of glandular kallikrein in human mixed saliva; that the inclusion of SBTI in the assay mixture is needed to inhibit non-kallikrein proteases that may also hydrolyse the synthetic substrate; and that prekallikrein is present in mixed saliva. Thus any future studies of changes in the level of kallikrein in saliva may wish to consider the presence of both active and total levels of glandular kallikrein.