A sensitive colorimetric assay for thrombin, prothrombin and antithrombin III in human plasma using a new synthetic substrate

Benzoyl-L-leucyl-L-alanyl-L-arginine-alpha-naphthylester (Bz-Leu-Ala-Arg-NE) was synthesized as a new substrate for use in the assay of thrombin. In the assay alpha-naphthol released by the enzyme reaction was measured colorimetrically. With Bz-Leu-Ala-Arg-NE as substrate, the minimum detectable concentration of human thrombin was 0.0025 U. This assay using Bz-Leu-Ala-Arg-NE is a highly sensitive method for detecting prothrombin, thrombin and antithrombin III in human plasma. Prothrombin could be determined with 0.2 microliter of human plasma using Echis carinatus venom (ECV) as activator. Antithrombin III activity could be determined with 2 microliter of human plasma using human thrombin and heparin as cofactor. A zymogram of human prothrombin was prepared with Bz-Leu-Ala-Arg-NE as substrate. The preparation gave one band (pI 4.9) on polyacrylamide disc gel isoelectrophoresis.     

A kinetic micromethod of determining the activity of antithrombin III

A method for measuring the blood plasma antithrombin III (AT III) activity is suggested, based on measurement of the rate of inactivation of added standard volume (0.05 ml) of plasma thrombin AT III. The thrombin residual activity in the mixture is detectable over the course of fibrinogen tests. Curves are plotted, reflecting the rate of inactivation of thrombin AT III in the tested and reference plasma samples; by modeling and comparing these curves the values of the examined sample AT III activity are obtained, with the effects of fibrinogen and fast antithrombins various levels eliminated.     

Increased concentrations of heparin cofactor II in diabetic patients, and possible effects on thrombin inhibition assay of antithrombin III

We compared concentrations of antithrombin III (AT-III) in plasma, as determined by an immunological method and by a functional thrombin inhibition method, in the presence of heparin in 160 blood samples from Type I diabetics. Although the correlation was highly significant (P less than 0.001) between the results obtained by the two methods, our data demonstrated that results by the thrombin inhibition assay, 121 (SD 15)%, expressed as percentages of the results for a normal plasma pool, were significantly (P less than 0.001) higher than by the immunoreactive method, 104 (SD 15)%, indicating an overestimation of functionally active AT-III. Concentrations of functionally active AT-III determined by a factor Xa inhibition assay, 105 (SD 13)%, were in the same range as immunoreactive AT-III. Addition of IgG antiserum to normal pooled plasma quenched only about 90% of the AT-III activity determined by the thrombin inhibition assay, but all of the AT-III activity determined by a factor Xa inhibition assay. These results demonstrate that the factor Xa inhibition assay is more specific for the determination of AT-III than the thrombin inhibition assay. We suggest that the high concentrations of heparin cofactor II, 117 (SD 17)%, might have caused an overestimation of AT III in this group of patients with diabetes Type I, and should not be overlooked in other clinical situations.     

Fibrin moderates the catalytic action of heparin but not that of dermatan sulfate on thrombin inhibition in human plasma

Three recent studies have reported that fibrin in solution significantly inhibits the ability of heparin to catalyze the inhibition of thrombin by antithrombin III. In addition, heparin inhibits the release of fibrinopeptide A by clot-bound thrombin less effectively than it inhibits the release of fibrinopeptide A by thrombin in solution. We have also reported that dermatan sulfate, which catalyzes thrombin inhibition by heparin cofactor II, inhibits thrombus growth in rabbits more effectively than heparin. Because the results of these studies suggest that fibrin inhibits the reactivity of thrombin with antithrombin III-heparin but not with heparin cofactor II-dermatan sulfate, we compared the relative catalytic effects of heparin and dermatan sulfate on thrombin inhibition in plasma, both in the presence and absence of fibrin. We quantitated the rates of thrombin inhibition by antithrombin III and heparin cofactor II by specific enzyme-linked immunosorbent assays. When it was generated, fibrin was kept in solution by adding 2 mmol/L Gly-Pro-Arg-Pro to plasma. Fibrinogen-fibrin reduced the reactivity of thrombin with plasma antithrombin III, both in the presence of and in the absence of heparin. In contrast, the catalytic action of dermatan sulfate on thrombin inhibition by plasma heparin cofactor II was unimpaired by fibrinogen-fibrin. Based on the ability of dermatan sulfate to inhibit thrombus growth in rabbits, failure of fibrinogen-fibrin to moderate the catalytic action of dermatan sulfate may account for its greater antithrombotic effectiveness relative to that of heparin.     

The measurement of thrombin in clotting blood by radioimmunoassay.

We have developed a radioimmunoassay for human thrombin using rabbit anti-human thrombin IgG. The assay can measure 2 ng thrombin/ml plasma, 500-fold more sensitive than clotting assays. Human prothrombin is less reactive in the assay than thrombin by at least four orders of magnitude, and there is no demonstrable cross-reactivity with human factor Xa, the clotting factor structurally most similar to thrombin. The assay does not detect thrombin bound to anthithrombin III. Using the assay, we have demonstrated that plasma from 20 normal subjects does not contain detectable thrombin. We measured thrombin generation in clotting blood in polypropylene tubes and observed that thrombin appears (approximately equal to 3 ng/ml) within 45 S-5 min after venipuncture. This material is thrombin, not intermediates of prothrombin activation, since it disappears after addition of heparin, which promotes thrombin antithrombin III complex formation. After a plateau of 2-10 min, there is further thrombin generation, which results in clotting after 15-27 min at a level of 40-50 ng thrombin/ml. The thrombin generated 9-25 min before clotting may activate factors V and VIII and stimulate platelet aggregation and release. In contrast, the cascade hypothesis assigns a role for thrombin only late in blood clotting. Radioimmunoassay of thrombin and other clotting factors will be useful for clinical and physiological studies of blood clotting especially since the assay seems specific for thrombin and is independent of other activities that affect bioassays.     

Purification and characterization of hereditary abnormal antithrombin III with impaired thrombin binding

Investigations of a family predisposed to recurrent venous thromboses disclosed a hereditary antithrombin III deficiency. The reactive antithrombin III concentration in plasma was reduced approximately 50%, and the antigen concentration of the inhibitor was normal. Antithrombin III from two members of this family was purified by dextran sulfate precipitation, affinity chromatography on heparin-Sepharose, and ion-exchange chromatography on DEAE-Sephadex A-50. Sodium dodecyl sulfate-polyacrylamide gel electrophoresis and crossed immunoelectrophoresis showed that only approximately half of the purified antithrombin III was capable of forming a complex with thrombin. This corroborated the finding that approximately twice as much purified antithrombin III from these patients compared with antithrombin III from normal humans was needed for titration of a given amount of thrombin. The nonreactive as well as the reactive population of antithrombin III bound heparin with the same affinity as normal antithrombin III. This was shown by crossed immunoelectrophoresis using heparin in the first dimension, by the elution pattern during salt gradient elution of antithrombin III from heparin-Sepharose, and by heparin enhancement of intrinsic fluorescence. Kinetic studies in the absence and in the presence of heparin indicated that the fraction of antithrombin III that could inactivate thrombin was functionally normal. The affected family members appeared to be heterozygotes with two autosomal codominant alleles that encode a normal and an abnormal antithrombin III protein, respectively.     

A colorimetric assay for plasma antithrombin III using a new synthetic peptide substrate (PS-915)

A colorimetric assay for plasma antithrombin III (ATIII) has been developed, using a new synthetic peptide substrate, PS-915 (H-D-Phe-Pro-Arg-CHA). PS-915 is freely water-soluble and its aqueous solution is stable. It is highly specific for thrombin and its Km value is about the same as that of S-2238. By enzyme hydrolysis, the new substrate liberates 3-carboxy-4-hydroxyaniline (CHA), which turns blue in color due to the complex formation with added alkaline-pentacyanoammine ferroate. The assay is a three-stage kinetic, one-point procedure, based on the method of antithrombin (heparin cofactor activity) determination. Since absorption measurements of the CHA are usually obtained at 700 nm, no blank correction is necessary even when hyperbilirubinemic, lipemic and/or hemolyzed plasma are used. The calibration curve for ATIII is linear over the range of 0-175% of normal and has a high degree of reproducibility. The results obtained by this method are well correlated with data obtained by the commonly used chromogenic assay or by radial immunodiffusion.     

Human alpha2-macroglobulin and its antitrypsic and antithrombin activities in serum and plasma.

alpha2-Macroglobulin level, trypsin protein esterase and progressive antithrombin activities were measured in normal and nephrotic sera and plasma. Trypsin protein esterase activity was proportional to the alpha2-macroglobulin concentration in serum and plasma from both normal and nephrotic patients. The results were different, however, with progressive antithrombin activity: in normal plasma, antithrombin III is the main thrombin inhibitor, then alpha2-macroglobulin and alpha1-antitrypsin, whereas in nephrotic syndrome patients, alpha2-macroglobulin is the main thrombin inhibitor.     

Identification in vitro of an endothelial cell surface cofactor for antithrombin III. Parallel studies with isolated perfused rat hearts and microcarrier cultures of bovine endothelium.

Two in vitro systems were used to identify an antithrombin III cofactor activity on vascular endothelium. Langendorff rat heart preparations or columns packed with endothelium cultured on microcarrier beads were perfused with mixtures of purified thrombin and antithrombin III. With each preparation, accelerated inhibition of thrombin by antithrombin III occurred during passage over endothelium. Platelet factor 4, protamine sulfate and diisopropylphosphoryl thrombin, all antagonists of the antithrombin III cofactor activity of heparin, significantly reduced the capacity of the preparation to inhibit thrombin. It is concluded that a substance with the functional properties of a stationary phase cofactor for antithrombin III is present on the microvascular endothelium and there catalyzes the inactivation of circulating free thrombin.     

刺参酸性粘多糖介导肝素辅因子Ⅱ对凝血酶活性的抑制

目的：进一步澄清刺参酸性粘多糖（Ｓｊａｍｐ）的抗凝血酶机制。方法：用国产Ｓｊａｍｐ作为激动剂，在正常混合血浆体系、纯化的肝素辅因子Ⅱ（ＨＣⅡ）体系以及纯化的抗凝血酶Ⅲ（ＡＴ－Ⅲ）体系研究Ｓｊａｍｐ的抗凝血酶作用机制。结果：Ｓｊａｍｐ对凝血酶的抑制主要呈ＨＣⅡ依赖性，当存在ＨＣⅡ时，Ｓｊａｍｐ抗凝血酶作用的二级速率常数Ｋ２＝１．５６×１０７ｍ－１·ｍｉｎ－１，其抑制速率常数是ＡＴ－Ⅲ的４．６倍。结论：在抗凝血酶作用方面，Ｓｊａｍｐ的效率（Ｋ２值）及机制（ＨＣⅡ依赖性）与硫酸皮肤素类似。     

Internalization of antithrombin III by cultured human endothelial cells and its subcellular localization

The presence of antithrombin III was demonstrated in cultured human endothelial cells derived from the umbilical cord by using immunofluorescence, immunoelectron microscopy studies, and an enzyme-linked immunosorbent assay (ELISA) specific for antithrombin III. Immunofluorescence studies indicated the presence of antithrombin III in granule-like structures in the endothelial cell. Immunoelectron microscopy studies performed with ultrathin cryosections of endothelial cells showed a colocalization of antithrombin III and a lysosomal marker protein in low electron dense organelles, indicating a lysosomal localization of antithrombin III. By using the ELISA, 77 +/- 40 ng (n = 8) antithrombin III was quantitated in 10(6) endothelial cells. Immunoprecipitation studies performed with metabolically labeled cultured human endothelial cells indicated that antithrombin III was not synthesized by the cells. Endothelial cells cultured in antithrombin III-depleted human serum did not contain antithrombin III, as was measured by ELISA. Internalization studies performed with radiolabeled purified antithrombin III and antithrombin III-thrombin complexes indicated that endothelial cells internalize antithrombin III when it is complexed to thrombin. Antithrombin III alone was not internalized by the endothelial cells.     

Methods for semi micro or automated determination of thrombin, antithrombin, and heparin cofactor using he substrate, H-D-Phe-Pip-Arg-p-nitroanilide-2HCl.

Methods for the measurement of thrombin and plasma antithrombin, by end point determination at a semi micro level and also by rate assay measurement in a fully automated system have been devised using the thrombin specific chromogenic substrate, H-D-Phe-Pip-Arg-p-nitroanilide. Preliminary defibrination of plasma is avoided in both methods. The semi micro method has been correlated with antitrhombin measured in plasma of postoperative patients by established clotting and immunological assays. The automated method has been found to be highly reproducible and to have less scatter than the other procedures.     

A method of determining heparin in blood plasma based on its antithrombin activity]

The suggested method for measuring blood plasma heparin is based on heparin ability to enhance antithrombin activity of antithrombin III (AT-III), the major Xa and thrombin inhibitor. The method consists in measurement of blood plasma AT-III activity in the presence and absence of protamine sulfate that destroys the heparin--AT-III complex. Heparin content in U/ml is determined from the difference in the activities of heparin--AT-III complex and AT-III proper activity represented on the calibration curve. The method is sufficiently sensitive, it permits registration of heparin concentrations in a wide band (from 0.01 U/ml to 0.75 U/ml of plasma).     

Involvement of heparin cofactor II in chymotrypsin neutralization and in the pancreatic proteinase—antiproteinase interaction during acute pancreatitis in man

Heparin cofactor II is a proteinase inhibitor which inhibits both chymotrypsin and thrombin, and displays great similarities with antithrombin III, the main inhibitor of thrombin in human plasma. Since acute pancreatitis is known to be associated with modification of the proteinase-antiproteinase equilibrium, we studied heparin cofactor II and antithrombin III as well as other biochemical and haematological parameters in 10 patients experiencing attacks of acute pancreatitis. Heparin cofactor II activity decreased during the first week of illness, while its antigen concentration remained subnormal. This discrepancy between antigen concentration and activity which persisted during the first week of illness was due both to complex formation of heparin cofactor II with its target proteinases and to partial proteolysis of the inhibitor. Heparin cofactor II was shown to form a complex with chymotrypsin in the plasma of such patients. Antithrombin III levels remained unchanged throughout the study, with no discrepancy between its activity and antigen concentration. No modification of haemostasis was shown either, except for a rise in the fibrinogen level during the first days of illness. It is concluded that, unlike antithrombin III, heparin cofactor II is involved in the proteinase-inhibitor equilibrium in patients with acute pancreatitis, and that heparin cofactor II might react as an inhibitor of pancreatic proteinases rather than an inhibitor of thrombin.     

Standardization of coagulologic technique for antithrombin III estimation and its clinical application

A standard assay procedure for estimating antithrombin III activity was derived from the Abildgaard technique as follows: 1) to decrease errors at the preanalytical stage, by using preliminarily defibrinated lyophilized plasma-calibrator and 2) to increase measurement accuracy, by using the concentration of a fibrinogen preparation and simplifying the analytical procedure. The estimation of plasma antithrombin activity in patients with pulmonary thromboembolism or sepsis points to the changes in antithrombin III activity.     

Clot-bound thrombin is protected from inhibition by heparin-antithrombin III but is susceptible to inactivation by antithrombin III-independent inhibitors.

Propagation of venous thrombi or rethrombosis after coronary thrombolytic therapy can occur despite heparin administration. To explore potential mechanisms, we set out to determine whether clot-bound thrombin is relatively protected from inhibition by heparin-antithrombin III but susceptible to inactivation by antithrombin III-independent inhibitors. Using plasma fibrinopeptide A (FPA) levels as an index of thrombin activity, we compared the ability of thrombin inhibitors to block FPA release mediated by fluid-phase thrombin with their activity against the clot-bound enzyme. Incubation of thrombin with citrated plasma results in concentration-dependent FPA generation, which reaches a plateau within minutes. In contrast, there is progressive FPA generation when fibrin clots are incubated with citrated plasma. Heparin, hirudin, hirudin dodecapeptide (hirugen), and D-phenylalanyl-L-prolyl-L-arginyl chloromethyl ketone (PPACK) produce concentration-dependent inhibition of FPA release mediated by fluid-phase thrombin. However, heparin is much less effective at inhibiting thrombin bound to fibrin because a 20-fold higher concentration is necessary to block 70% of the activity of the clot-bound enzyme than is required for equivalent inhibition of fluid-phase thrombin (2.0 and 0.1 U/ml, respectively). In contrast, hirugen and PPACK are equally effective inhibitors of fluid- and solid-phase thrombin, while hirudin is only 50% as effective against the clot-bound enzyme. None of the inhibitors displace bound 125I-labeled thrombin from the clot. These studies indicate that (a) clot-bound thrombin is relatively protected from inhibition by heparin, possibly because the heparin binding site on thrombin is inaccessible when the enzyme is bound to fibrin, and (b) clot-bound thrombin is susceptible to inactivation by antithrombin III-independent inhibitors because the sites of their interaction are not masked by thrombin binding to fibrin. For these reasons, antithrombin III-independent inhibitors may be more effective than heparin in certain clinical settings.     

Heparin cofactor II activity in plasma during pregnancy and oral contraceptive use

Inhibition of thrombin by heparin is mediated by at least two plasma proteins, antithrombin III, and heparin cofactor II. The plasma titer of heparin cofactor II was significantly elevated in both pregnant women and users of oral contraceptives.     

The determination of antithrombin III, alpha 2-macroglobulin and alpha 2-antiplasmin in plasma by laser nephelometry

Specific assay procedures were developed to determine antithrombin III, alpha 2-macroglobulin, and alpha 2-antiplasmin in plasma with the aid of a Laser nephelometer. About 100 normal and pathological plasmas were examined and the results compared with those obtained by conventional immunological methods, such as radial immunodiffusion or rocket electrophoresis. Nephelometry proved to be a very rapid, precise, and reproducible method for the determination of antithrombin III and alpha 2-macroglobulin. The reproducibility of the alpha 2-antiplasmin assay was poor, probably as a consequence of the low concentration of this inhibitor in normal plasma.     

Effect of protamine sulfate on antithrombin III activity

When protamine sulfate was added to heparinized plasma in vitro for neutralization of heparin, the activities on both thrombin and Xa known as heparin cofactor in antithrombin action were completely abolished. However, progressive activities on thrombin and Xa both recovered within 30 minutes after protamine sulfate addition. When equivalent heparin was again added, heparin cofactor activity was immediately restored. Based on the fact that protamine sulfate did not show any direct action on the antithrombin III molecule, the presence of AT III with progressive activity was considered to play an important role in the rebound phenomenon of heparin after heparin neutralization with protamine sulfate.     

Identification of a congenital dysthrombin, thrombin Quick.

A dysprothrombin designated prothrombin Quick, is isolated from the plasma of an individual with < 2% of normal functional prothrombin activity and 34% of the normal prothrombin level by immunologic assay. With Factor Xa or taipan snake venom as activators, a fragmentation pattern identical to that of normal prothrombin is observed on gel electrophoresis in dodecylsulfate. This evidence combined with the observed barium citrate adsorption of prothrombin Quick and the low activity suggests that the defect in prothrombin Quick is in the thrombin portion of the molecule. Thrombin Quick is isolated and comigrates with thrombin on dodecyl sulfate gel electrophoresis, either reduced or nonreduced. The activity of thrombin Quick on several biological substrates of thrombin is investigated. Relative to normal thrombin, thrombin Quick is 1/200 as active on fibrinogen and 1/20-1/50 as effective in activating Factors V and VIII and aggregating platelets. A complex with antithrombin III is detected by dodecyl sulfate gel electrophoresis. Further investigation with the active site titrant, dansylanginine-N-(3-ethyl-1,5-pentanediyl)amide showed that the thrombin Quick preparation has the same affinity for the titrant as thrombin, but apparently only 40% active sites per mole protein are titrable.