Standard assays underestimate the concentration of heparin in neonatal plasma

Heparin is commonly used to treat neonatal thrombosis. Drug monitoring often involves assays that measure the inhibition of added factor Xa or thrombin by the antithrombin III (AT-III) heparin complex. We examined whether the neonatal AT-III deficiency affects heparin recovery in such assays at therapeutic drug concentrations (0.1 to 0.6 U/ml). The chromogenic anti-factor Xa assay (Teien AN, Lie M, Abildgaard U. Thromb Res 1976;8:413-6) and the protamine titration test were performed in eight pooled cord plasma samples and in normal adult plasma. Only 65% to 70% of heparin activity detected in adult plasma was recovered by the assay of Teien et al. In cord plasma; recovery by the protamine test was 80% or less. Heparin recovery in cord plasma was significantly improved by raising the AT-III concentration to normal adult levels in both assays. We conclude that heparin assays underestimate drug levels in neonatal plasma unless the neonatal AT-III deficiency is fully corrected in the test system. The use of standard assays may lead to over-heparinization of newborn infants, thereby placing them at a higher risk of bleeding.     

Abnormal antithrombin III with defective serine protease binding (antithrombin III "Denver")

A hereditary (three family members) deficiency of antithrombin III (AT-III) in which AT-III antigen (AT-III ag) is normal in spite of low heparin cofactor and antithrombin activity is described. Plasma levels were: AT-III ag, 0.92-0.96 U/ml; AT-III heparin cofactor activity, 0.54-0.62 U/ml; progressive antithrombin activity index, 0.13-0.18; anti-Xa activity, 0.50-0.56 U/ml. Plasma crossed immunoelectrophoresis (CIE) patterns performed with and without added heparin were normal, but serum CIE revealed a decreased complex peak. Purification of the patient's plasma AT-III by heparin-sepharose affinity chromatography showed a normal protein recovery and elution profile, but the purified AT-III fraction showed only 50% of the normal progressive thrombin neutralization and anti-Xa activity. When thrombin-antithrombin (TAT) complexes were formed by incubating with excess thrombin, SDS-polyacrylamide gel electrophoresis (PAGE) analysis revealed that half the patient AT-III formed TAT complexes while the remainder migrated as free AT-III. All the control AT-III formed TAT complexes. The patient's nonreacting AT-III (AT-III "Denver"), isolated by affinity chromatography, showed CIE and SDS-PAGE migration patterns characteristic of normal AT-III but failed to bind thrombin or Xa. Calculations from turnover studies in one patient and normal subjects with autologous 131I-AT-III suggested that AT-III "Denver" is removed from the plasma slightly more rapidly than normal. These studies indicate that the patients' variant AT-III molecule was characterized by normal heparin interaction but defective binding and inhibition of thrombin and Xa. These characteristics allow isolation of the nonreactive variant molecule by heparin-sepharose affinity chromatography.     

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).     

The effect of a sulfated polysaccharide on antithrombin III

A major naturally occurring inhibitor of blood is AT-III. We have investigated the potentiation of AT-III inhibition of factors Xa, IIa, and plasmin by the heparinoid substance SP-54. Both coagulation and amidolytic methods were used. SP-54 potentiated AT-III inhibition of factors Xa and IIa in the absence of heparin. When heparin was present, potentiation of inhibition of factor Xa usually occurred, but not of factor IIa. SP-54 also potentiated the AT-III inhibition of plasmin action. Laurell immunoelectrophoresis showed no changes in AT-III in the presence of SP-54. In view of the recent importance placed on the role of AT-III and factor Xa in thrombogenesis, an oral agent which potentiates AT-III activity can have important implications for thrombotic therapy.     

Development and characterization of an automated assay of effective heparin activity in plasma

We describe a fully automated assay for determining effective heparin activity in plasma, based on heparin-catalyzed inhibition of Factor Xa (EC 3.4.21.6) by antithrombin III (AT III). Residual Factor Xa is determined kinetically by the Du Pont aca discrete clinical analyzer with a chromogenic substrate and is inversely related to heparin activity. Because the test plasma is the sole source of AT III, the assay result is dependent on AT III activity and reflects effective rather than total heparin activity. The assay range is 20-1200 USP units/L, and the assay shows equivalent sensitivity to standard and low-molecular-mass heparins. Within-run reproducibility (CV) is 1.6% at 390 units/L. There was no interference from common blood components or drugs. Results agreed well with those by the Coatest heparin kit (Kabi) adapted to the Cobas-Bio analyzer (r = 0.85, n = 122).     

Synthetic peptide substrates in hemostatic testing

Since the introduction of synthetic chromogenic and fluorogenic peptide substrates from serine proteases, the testing of coagulation has undergone a dramatic conceptual and methodological change. The concept of coagulation profiling has emerged and automated methodologies are being introduced. Synthetic substrate methods for the evaluation of antithrombin-III; progressive antithrombin; plasminogen; antiplasmin; prekallikrein; antikallikrein ; alpha 1-antitrypsin; prothrombin; heparin; platelet factor IV; urokinase; tissue activator of plasminogen; factor assays; amidolytic equivalents of prothrombin time; and partial thromboplastin time have been developed. Studies on antithrombin-III indicate that immunological methods evaluate the total immunoreactive-antithrombin-III (antigenic) level and do not discriminate between functionally active forms and the AT-III serine protease complex. The clinical significance of AT-III measured by immunological methods is highly questionable. The coagulant assays for the measurement of AT-III require purified alpha-thrombin preparations. The noncoagulant forms of thrombin (beta- and gamma-) result in falsely low antithrombin-III quantitation. The molecular heterogeneity in a given thrombin preparation if standardized in terms of its amidolytic activity does not produce any errors in the quantitation of AT-III levels with synthetic peptide methods. None of the immunological methods provide clinically relevant information except in normal plasma where the immunological and functional activities are identical. Analysis of pathologic plasma samples using laser nephelometry, radial immunodiffusion and radioimmunoassay methods revealed that the functional activity of various serine protease inhibitors is greatly reduced but the reduction in the immunological quantities is minimal. Since coagulation proteins are functional, a ratio between their functional activity and absolute protein levels may be a useful parameter. Employing human and bovine thrombin; bovine and human Xa with their respective substrates, the absolute quantitation of heparin is satisfactorily carried out, however, these assays only measure heparin concentrations and do not reflect the overall anticoagulant effect of heparin. Using the synthetic substrates, the value of measuring absolute concentrations of heparin in a patient on heparin therapy is questionable. With the introduction of fluorogenic substrates, the presence of activated coagulation factors may be demonstrated in patients with thrombotic disorders.(ABSTRACT TRUNCATED AT 400 WORDS)     

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.     

A Simple Amidolytic Method for the Determination of Functionally Active Antithrombin III

A simple amidolytic method for the determination of the concentration of functionally active antithrombin III is described. Plasma is diluted with buffer containing EDTA and Polybrene®. In stage I, diluted plasma is incubated with thrombin. EDTA retards fibrin polymerization, and plasma fibrinogen does not influence the assay. Polybrene makes the assay result independent of heparin. In stage II, remaining thrombin is determined with the chromogenic substrate benzoyl-Phe-Arg-p-NA. The method is simpler and has a higher accuracy than clotting methods. There is a close correlation between the results obtained with this assay and with immunoassay of antithrombin III.     

Preservation of antithrombin III activity in stored whole blood

Antithrombin III (AT-III) is the major inhibitor of thrombin, Factor Xa, and other coagulation enzymes. Congenital and acquired deficiencies of AT-III are thought to contribute to thrombosis and disseminated intravascular coagulation. Because a recent report suggested reduced AT III in stored blood, we evaluated blood bank storage effects. Serial samples were taken from 6 units of whole blood drawn into citrate-phosphate-dextrose-adenine over 42 days, and assays for AT-III functional activity were performed on the same day. The values (mean +/- SD) were as follows: day 0,91.8 +/- 10.7 percent; day 2, 101.9 +/- 10.7 percent; day 8, 107.3 +/- 7.4 percent; day 15, 118.9 +/- 11.1 percent; day 22, 105.4 +/- 9.8 percent; day 35, 93.4 +/- 8.8 percent; and day 42, 97.4 +/- 7.5 percent. The rise from day 0 to day 15 was significant but presumably secondary to interassay variation because analysis of frozen aliquots showed no significant change when all samples from each unit were assayed in one batch. Immunoassay of AT-III also showed no change with storage. The results indicate AT-III retains functional activity in whole blood stored at 2 to 6 degrees C for 42 days, and AT-III replacement does not require fresh blood or fresh-frozen plasma. Low values may reflect individual donor differences or dilution of plasma by anticoagulant.     

Pharmacologic properties of an unfractionated heparin butyryl derivative with long-lasting effects.

This article reports on the pharmacologic properties of an O-acylated butyryl derivative (C4-UH) of unfractionated heparin (UH). In a purified system, the ability of C4-UH to catalyze the inhibition of thrombin and of factor Xa in the presence of antithrombin III was similar to that of UH. Addition of albumin (10 mg/ml) to the reagents reduced the antithrombin and antifactor Xa catalytic potency of C4-UH 68-fold and 20-fold, respectively, and did not alter those of UH. As judged from the prolongation of the activated partial thromboplastin time and the thrombin clotting time, the anticoagulant activities of C4-UH were two times weaker than those of UH. After calibration against UH, the antifactor Xa-specific and antithrombin-specific activities were two and 6.6 times lower, respectively. After bolus intravenous injection into rabbits, the apparent clearances of C4-UH were reduced 2.4 (antifactor Xa activity) and 3.2 times (antithrombin activity) in comparison with those of UH. This property accounted for the higher plasma concentrations generated during a constant infusion of the same dose. In the Wessler thromboplastin model, the minimum doses providing the maximum antithrombotic effect after bolus injection were equivalent for both compounds when expressed as antifactor Xa units; the duration of the antithrombotic effect of this derivative was prolonged, whereas the hemorrhagic potential was unaffected. This study opens a new concept for heparin derivatives having lower clearances and long-lasting effects. These properties could be linked to nonspecific binding of C4-UH to plasma proteins, thereby reducing the amount of free compound available to interact with antithrombin III.     

Importance of factor Xa in determining the procoagulant activity of whole-blood clots.

The binding of thrombin to fibrin is thought to be an important mechanism by which thrombi exhibit procoagulant activity; however, the extent to which other procoagulants are associated with thrombi has not been previously defined. This study was designed to determine whether clotting factors other than thrombin are bound to whole-blood clots and can thereby contribute to significant procoagulant activity. Clots formed in vitro from human blood exhibited minimal thrombin activity when incubated in plasma depleted of vitamin K-dependent factors by barium-citrate adsorption, as indicated by increases in the concentration of fibrinopeptide A (FPA), a marker of fibrin formation, to 72 nM after 30 min. Incubation of clots in barium-absorbed plasma repleted with 0.9 microM human prothrombin under the same conditions resulted in marked increases in the concentration of FPA (> 1,000 nM) and clotting by 30 min. The increases in FPA were attributable to activation of the added prothrombin by clot-associated Factor Xa, judging from concomitant increases in the concentration of prothrombin fragment 1.2. Similar results were obtained with thrombi induced in the axillary arteries of dogs by vascular injury and incubated with plasma in vitro. Activation of prothrombin was inhibited in a dose-dependent manner by tick anticoagulant peptide, a direct inhibitor of Factor Xa, at concentrations of 0.5-5.0 microM. Clot-associated Factor Xa activity was resistant to inhibition by anti-thrombin III, judging from the lack of inhibition of prothrombin activation during incubation of clots in plasma containing heparin pentasaccharide, an anti-thrombin III-mediated inhibitor of Factor Xa. Thus, the activity of Factor Xa appears to be an important determinant of the procoagulant activity of whole-blood clots and arterial thrombi, and is resistant to inhibition by anti-thrombin III-dependent inhibitors.     

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.     

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.     

Modulation of heparin cofactor II activity by histidine-rich glycoprotein and platelet factor 4.

Heparin cofactor II is a plasma protein that inhibits thrombin rapidly in the presence of either heparin or dermatan sulfate. We have determined the effects of two glycosaminoglycan-binding proteins, i.e., histidine-rich glycoprotein and platelet factor 4, on these reactions. Inhibition of thrombin by heparin cofactor II and heparin was completely prevented by purified histidine-rich glycoprotein at the ratio of 13 micrograms histidine-rich glycoprotein/microgram heparin. In contrast, histidine-rich glycoprotein had no effect on inhibition of thrombin by heparin cofactor II and dermatan sulfate at ratios of less than or equal to 128 micrograms histidine-rich glycoprotein/microgram dermatan sulfate. Removal of 85-90% of the histidine-rich glycoprotein from plasma resulted in a fourfold reduction in the amount of heparin required to prolong the thrombin clotting time from 14 s to greater than 180 s but had no effect on the amount of dermatan sulfate required for similar anti-coagulant activity. In contrast to histidine-rich glycoprotein, purified platelet factor 4 prevented inhibition of thrombin by heparin cofactor II in the presence of either heparin or dermatan sulfate at the ratio of 2 micrograms platelet factor 4/micrograms glycosaminoglycan. Furthermore, the supernatant medium from platelets treated with arachidonic acid to cause secretion of platelet factor 4 prevented inhibition of thrombin by heparin cofactor II in the presence of heparin or dermatan sulfate. We conclude that histidine-rich glycoprotein and platelet factor 4 can regulate the antithrombin activity of heparin cofactor II.     

Defective enzyme protein in lipoprotein lipase deficiency

A monoclonal antibody to lipoprotein lipase (LPL) has been used in an enzyme-linked immunosorbent assay (ELISA) for LPL protein mass. Measurement of LPL immunoreactive mass in pre- and postheparin plasma distinguished three classes of abnormalities in patients with classical deficiency of lipoprotein lipase activity. The class I defect consisted of the absence of LPL immunoreactive homodimer in pre- and postheparin plasma compatible with a potential 'null allele'. Patients with a class II defect had almost no LPL immunoreactive mass in preheparin plasma but showed an increase in their LPL mass of 68 +/- 23 ng ml-1 (mean +/- SD) after heparin. Patients with the class III defect had considerable amounts of LPL immunoreactive material in preheparin plasma (159 +/- 190 ng ml-1). Heparin administration, however, caused very little additional release of LPL into the plasma (16 +/- 51 ng ml-1). Thus although both class II and class III patients had an LPL protein with abnormal catalytic activity, class III patients also appeared to have a defect in heparin binding of LPL. To test this hypothesis, postheparin plasma of classes II and III patients was analysed by heparin-Sepharose chromatography. In contrast to class II patients, the LPL immunoreactive mass of class III patients did not show affinity for the heparin and eluted in the column void volume, suggesting the class III defect is also associated with a defect in heparin binding.     

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.     

Elevated factor Xa activity in the blood of asymptomatic patients with congenital antithrombin deficiency.

The presence of congenital antithrombin deficiency has been consistently shown to predispose patients to venous thrombosis. We have utilized the prothrombin fragment F1+2 radioimmunoassay to quantitate factor Xa activity in the blood of 22 asymptomatic individuals with this clinical disorder not receiving antithrombotic therapy. The mean level of F1+2 was significantly elevated in these patients as compared to normal controls (3.91 vs. 1.97 nM, P less than 0.001). The metabolic behavior of 131 I-F1+2 was found to be similar in antithrombin-deficient subjects and normal individuals. The hemostatic system hyperactivity as measured by the F1+2 assay could be specifically corrected by raising the plasma antithrombin levels of the above asymptomatic individuals into the normal range. This study provides the first demonstration that the prethrombotic state can be biochemically defined as an imbalance between the production and inhibition of factor Xa enzymatic activity within the human circulation. It is known that antithrombin and alpha 1-proteinase inhibitor (PI) are the major inhibitors of factor Xa in human plasma in the absence of heparin. To further evaluate the mechanism by which antithrombin functions as an inhibitor of factor Xa in humans, we studied five patients who exhibited severe congenital deficiencies of alpha 1-PI. Our results indicated that the plasma of these subjects showed virtually identical decreases in plasma antifactor Xa activity in the absence of heparin when compared to antithrombin-deficient individuals, but the plasma F1+2 levels in the alpha 1-PI deficient population were not significantly different than normal. This data suggests that alpha 1-PI does not function as a major inhibitor of factor Xa in vivo, and that a tonically active heparin-dependent mechanism exists in humans for accelerating the neutralization of this enzyme by antithrombin.     

Low molecular weight heparin inhibits plasma thrombin generation via direct targeting of factor IXa: contribution of the serpin‐independent mechanism

Summary. Background: Although heparin possesses multiple mechanisms of action, enhanced factor Xa inhibition by antithrombin is accepted as the predominant therapeutic mechanism. The contribution of FIXa inhibition to heparin activity in human plasma remains incompletely defined. Objectives: To determine the relevance of FIXa as a therapeutic target for heparins, particularly serpin‐independent inhibition of intrinsic tenase (FIXa–FVIIIa) activity. Patients/Methods: Thrombin generation was detected by fluorogenic substrate cleavage. The inhibitory potencies (EC₅₀s) of low molecular weight heparin (LMWH), super‐sulfated LMWH (ssLMWH), fondaparinux and unfractionated heparin (UFH) were determined by plotting concentration vs. relative velocity index (ratio ± heparin). Inhibition was compared under FIX‐dependent and FIX‐independent conditions (0.2 or 4 pm tissue factor [TF], respectively) in normal plasma, and in mock‐depleted or antithrombin/FIX‐depleted plasma supplemented with recombinant FIX. Results: UFH and fondaparinux demonstrated similar potency under FIX‐dependent and FIX‐independent conditions, whereas LMWH (2.9‐fold) and ssLMWH (5.1‐fold) demonstrated increased potency with limiting TF. UFH (62‐fold) and fondaparinux (42‐fold) demonstrated markedly increased EC₅₀ values in antithrombin‐depleted plasma, whereas LMWH (9.4‐fold) and ssLMWH (two‐fold) were less affected, with an EC₅₀ within the therapeutic range for LMWH. The molecular target for LMWH/ssLMWH was confirmed by supplementing FIX/antithrombin‐depleted plasma with 90 nm recombinant FIX possessing mutations in the heparin‐binding exosite. Mutated FIX demonstrated resistance to inhibition of thrombin generation by LMWH and ssLMWH that paralleled the effect of these mutations on intrinsic tenase inhibition. Conclusions: Therapeutic LMWH concentrations inhibit plasma thrombin generation via antithrombin‐independent interaction with the FIXa heparin‐binding exosite.     

Interference of coumarin therapy with the "Heptest" owing to declining prothrombin concentrations

The Heptest kit (Haemachem, Inc., St. Louis, MO) for quantifying heparin in plasma is based on heparin-mediated inhibition of factor Xa, resulting in prolongation of clotting time. In 19 of 55 plasma samples obtained from 32 patients concurrently receiving coumarin and heparin, Heptest results exceeded true heparin values by more than 0.2 int. unit/mL; four samples showed a deviation exceeding 0.4 int. unit/mL. We show here that these deviations are caused by coumarin-induced decreases of plasma prothrombin. This problem can be circumvented by adding purified prothrombin or normal plasma to the assay mixture.     

Assembly of the prothrombin activator complex on rabbit alveolar macrophage high-affinity factor Xa receptors. A kinetic study

Efficient prothrombin activation occurs after assembly of factors Va, Xa, and phospholipid surface cofactor as a multimolecular complex. These components are provided by platelets and plasma within the vascular space, but molecules and membranes for prothrombin activator assembly in extravascular spaces have not been identified. In the present study, purified alveolar macrophages were found to produce high-affinity factor Xa receptors that mediate formation of enzymatic prothrombinase complexes and rapid prothrombin to thrombin conversion in the absence of exogenous factor V/Va or platelets. Thus, in reaction mixtures with alveolar macrophages cultured for 20 h in serum-free medium, the thrombin formation rate was 152 nM/min/0.66 X 10(6) cells, after adding prothrombin (1.5 microM), Ca2+ (5 mM), and factor Xa (3.7 nM). The observed Kd of factor Xa interaction with macrophage receptors is 2.1 +/- 0.94 X 10(-10) M. Kinetic analysis and inhibition studies using isolated factor V and anti-factor V antibody show that macrophage Xa receptors are functionally and antigenically similar to plasma factor V. By contrast, freshly isolated cells lacked receptors promoting prothrombin conversion at high rates. Inhibitors of protein synthesis and glycosylation, puromycin and monensin, respectively, abrogated production of Xa receptors in culture. Additionally, subcellular fractionation and enzyme-marker studies (alkaline phosphodiesterase I) indicate that internal and external membranes of alveolar macrophages have phospholipid surface cofactor activity required for prothrombinase complexes. Pulmonary surfactant is also shown to express this cofactor activity. Alveolar macrophages and surfactant comprise an efficient prothrombin activator system that is independent of plasma factor V. This system may facilitate rapid extravascular alveolar thrombin formation even at very low concentrations of factor Xa during lung defense reactions to inflammation or edema.