The immunodepletion of factor VII from human plasma using a monoclonal antibody.

A murine hybridoma cell line which secretes monoclonal antibody to factor VII has been prepared to facilitate the immunodepletion of this clotting factor from plasma. Specific monoclonal antibody was purified from mouse ascites tumours by protein A-Sepharose chromatography and shown to be of the IgG1 immunoglobulin subclass. On immunoblotting, this antibody reacted with a single protein band identical to purified factor VII. The purified monoclonal antibody was coupled to Sepharose 4B and was used to immuno-deplete factor VII from pooled normal human plasma. The prothrombin time of plasma immunodepleted in this way was 35 s compared to 12 s for the starting plasma. Specific factor assays of the immunodepleted plasma showed factor VII activity to be less than 1% while the levels of the other clotting factors were unchanged. The immunodepleted plasma was equivalent to severe congenital factor VII deficient plasma as a substrate for factor VII assays. Bound factor VII could be eluted from the immunoaffinity column with citrate buffer, pH 6.0, with good recovery.

Placental transport of low molecular weight heparin in the pregnant sheep.

Standard heparin, an effective treatment for antepartum thromboembolic disease, is thought to be safe for the fetus since it does not cross the placenta. Recently, a number of low molecular weight heparins have been prepared which have been shown to produce less bleeding than standard heparin for an equivalent antithrombotic effect in experimental animals. These observations suggest that the low molecular weight heparins may also provide superior antithrombotic therapy in antepartum thromboembolic disease. However, it is not known whether the low molecular weight heparins cross the placenta. To determine this, we examined the pharmacokinetics of 125I-labelled standard heparin and a low molecular weight heparin, and their anticoagulant effects in mother and fetus, using a pregnant sheep model. Catheters were inserted into maternal and fetal femoral arteries at 108-119 d gestation (term: 147 d). 1-3 days later the mothers were given a bolus i.v. injection of 5000 anti-Xa units of 125I-labelled standard heparin or low molecular weight heparin, CY 222. Nine serial blood samples were collected over 4 h from both mother and fetus for measurements of radioactivity, anti-Xa activity (chromogenic) and activated partial thromboplastin times. When therapeutic levels of standard and CY 222 heparins were achieved in the mother, there was no detectable radioactivity or anticoagulant effect in the fetus. We conclude that standard heparin and the low molecular weight CY 222 do not cross the placenta in the pregnant sheep.

Effects of heparin fractions of different affinities to antithrombin III and thrombin on the inactivation of thrombin and factor Xa by antithrombin III.

To investigate the relative contribution of heparin-binding thrombin and antithrombin III to the enhancement of the rate of inactivation of thrombin by antithrombin III, standard heparin was fractionated on matrix-linked thrombin and (or) antithrombin III. There was a good correlation between heparin affinity for antithrombin III and its ability to enhance the inactivation of thrombin and factor Xa. In addition, there was a good correlation between affinity of heparin for thrombin and its catalytic activity on the inactivation of thrombin by antithrombin III. Thus fractions with high affinity to thrombin had similar rate-enhancing activity for thrombin inactivation to that of fractions with high affinity to antithrombin III. Fractions with high affinity to both proteins were more potent than fractions with high affinity to either protein alone. No significant differences in mean molecular weight were observed among the various heparin fractions. A heparin fraction with very low affinity to thrombin and high affinity to antithrombin III was prepared by repeated fractionation of a low molecular weight heparin on the two affinity columns. This fraction had very weak rate-enhancing activity for the inactivation of thrombin by antithrombin III, but retained substantial activity for the inactivation of factor Xa. The results of these studies support the concept that, for both standard and low molecular weight heparin, the enhancement of the inactivation of thrombin by antithrombin III requires the interaction of the heparin with both thrombin and antithrombin III.

Heparan sulfate and dermatan sulfate inhibit the generation of thrombin activity in plasma by complementary pathways.

Heparan with a low affinity for antithrombin III has previously been demonstrated to inhibit thrombin generation in both normal plasma and plasma depleted of antithrombin III. In addition, standard heparin and heparin with a low affinity for antithrombin III have been demonstrated to have equivalent inhibitory actions on thrombin generation in plasma depleted of antithrombin III. These observations prompted the investigation of the effects of four normal vessel wall glycosaminoglycans (heparan sulfate, dermatan sulfate, chondroitin-4-sulfate, and chondroitin-6-sulfate) on the intrinsic pathway generation of thrombin and factor Xa and on the inactivation of thrombin and factor Xa in plasma. Heparan sulfate inhibited thrombin generation and accelerated the inactivation of added thrombin and factor Xa in normal plasma but not in antithrombin III-depleted plasma. In contrast, dermatan sulfate inhibited thrombin generation in both normal and antithrombin III-depleted plasma. In addition, heparan sulfate was an effective inhibitor of factor Xa generation, while dermatan sulfate was not. Neither chondroitin-4-sulfate nor chondroitin-6-sulfate inhibited the generation of thrombin or factor Xa nor did they accelerate the inactivation of factor Xa or thrombin by plasma. These results suggest that heparan sulfate acts primarily by potentiating antithrombin III, while dermatan sulfate acts by potentiating heparin cofactor II. The inhibition of thrombin generation by heparan sulfate and dermatan sulfate thus appears to occur by complementary pathways, both of which may contribute to the anticoagulation of blood in vivo.

A comparison of the antithrombotic and haemorrhagic effects of low molecular weight heparin fractions: the influence of the method of preparation.

Bleeding is an important complication of heparin therapy. A number of low molecular weight heparin fractions produce less bleeding than standard heparin for an equivalent antithrombotic effect in experimental animals. Low molecular weight heparin fractions and fragments are produced by a number of different procedures but their relative effects on haemostasis and thrombosis have not been evaluated. We have compared the antithrombotic and haemorrhagic effects of two low molecular weight heparin fragments and of a heparinoid with porcine mucosa heparin and related these in vivo findings to the results of ex vivo tests of blood coagulation and in vitro tests of platelet vivo tests of blood coagulation and in vitro tests of platelet function. Haemorrhage was assessed using a rabbit ear bleeding model. The antithrombotic effects were assessed by measuring inhibition of a tissue thromboplastin-induced jugular vein thrombus and by inhibition of fibrin and platelet accumulation in an arterial-venous shunt. The ex vivo anticoagulant effects were assessed with the thrombin clotting time, activated partial thromboplastin time and anti-Xa assay, and the effect of these glycosaminoglycans on platelet function was assessed by measuring collagen-induced platelet aggregation. For a similar antithrombotic effect, standard heparin produced significantly more bleeding than the other 3 glycosaminoglycans. The antithrombotic effects of all 4 glycosaminoglycans occurred at similar levels of anti-Xa activity but there was no relationship between blood loss and the effects of these glycosaminoglycans on any of the other tests of blood coagulation. Standard heparin had a greater inhibitory effect on collagen-induced platelet aggregation than the low molecular weight glycosaminoglycans, supporting the possibility that the increased bleeding observed with heparin is related in part to its inhibitory effect on platelet function.

The inhibition of the anticoagulant activity of heparin by platelets, brain phospholipids, and tissue factor.

Platelets and phospholipids have been shown to protect factor Xa from inhibition by the heparin--antithrombin III complex. The studies reported herein investigated the effects of gel filtered platelets, activated platelets, brain phospholipids (cephalin), and brain tissue factor on the inactivation of thrombin and factor Xa by the heparin--antithrombin III complex. In addition, the relative anticoagulant effects of heparin on the extrinsic and intrinsic coagulation pathways were investigated. Our results suggest that gel filtered platelets, activated platelets, cephalin and tissue factor protect thrombin, as well as factor Xa, from inactivation by the heparin--antithrombin III complex. Tissue factor had the greatest anti-heparin activity. Activated platelets, gel filtered platelets, cephalin and tissue factor did not alter the protease--antithrombin III reaction rates measured in the absence of heparin. These observations are consistent with the hypothesis that platelets, brain phospholipids, and tissue factor, in the presence of calcium, partition heparin from antithrombin III, and thus prevent full expression of the antithrombin III-dependent anticoagulant activity of heparin.

Enhanced prothrombin-converting activity and factor Xa binding of platelets activated by the alternative complement pathway.

Platelet prothrombin-converting activity and factor Xa binding were studied after exposure of human platelet rich plasma (PRP) to various conditions leading to platelet activation. Zymosan resulted in increased platelet-bound C3, enhanced prothrombin-converting activity and increased factor Xa binding. Similar findings were observed with normal platelets resuspended in factor XII-deficient plasma. The combined use of zymosan and thrombin to activate platelets resulted in synergistic prothrombin-converting activity and factor Xa binding. In contrast, no synergism was obtained with the concomitant use of zymosan and collagen, suggesting that collagen and zymosan share the same pathway for platelet activation. Heterologous antibody to factor V completely inhibited the platelet prothrombin-converting activity for all modes of platelet activation, indicating that this activity is mediated by factor V.

Heparin with low affinity to antithrombin III inhibits the activation of prothrombin in normal plasma.

Standard unfractionated heparin is known to have two actions on blood clotting. Unfractionated heparin enhances the rates at which antithrombin III inactivates activated clotting factors, and inhibits the activation of both Factor X and prothrombin by disrupting the calcium and phospholipid dependent assembly of the Factor X and prothrombin activator complexes. This latter inhibitory action of heparin occurs independently of antithrombin III. A heparin fraction with low affinity to antithrombin III was prepared from standard heparin by affinity chromatography on antithrombin-III-Sepharose and its properties compared with unfractionated heparin. The low affinity heparin fraction and the unfractionated heparin had equivalent inhibitory effects on prothrombin activation in antithrombin III depleted plasma. In normal plasma, the low affinity fraction inhibited the activation of prothrombin. Unlike the unfractionated heparin, however, the fraction of heparin with low affinity to antithrombin III did not enhance the inactivation of either Factor Xa or thrombin. This antithrombin III independent inhibition of the activation of prothrombin was also evident when activated platelets were used as the source of the procoagulant phospholipids. The antithrombin III independent effect of heparin is unlikely to be important therapeutically, however, if this property of heparin is shared by other naturally occurring glycosaminoglycans, it could be important in maintaining the fluidity of blood under physiological conditions.

Synthesis of thromboxane B2 and prostaglandins by bovine gastric mucosal microsomes.

Bovine gastric mucosal microsomes synthesize prostaglandins from arachidonic acid but thromboxane B2 is the principal product. Thromboxane B2 synthesis occurs at an appreciable rate from endogenous precursor but more rapidly with added arachidonate. Nonsteroidal antiinflammatory drugs inhibited synthesis of prostaglandins and thromboxanes with the following decreasing order of potency: indomethacin, fenoprofen, acetylsalicylic acid, phenylbutazone, sulfinpyrazone, and acetaminophen.