Inactivation of factor XIa by plasma protease inhibitors: predominant role of alpha 1-protease inhibitor and protective effect of high molecular weight kininogen

Histidine-rich glycoprotein inhibits contact activation of blood coagulation

Histidine-rich glycoprotein has been purified from bovine plasma employing two different purification procedures. The first procedure was one-step ion-exchange chromatography using phosphocellulose, while the second procedure involved fractionation using polyethyleneglycol 6000 followed by column chromatography employing CM-Sepharose and heparin-Sepharose. The effect of purified bovine histidine-rich glycoprotein on the contact activation of blood coagulation was studied in human plasma by using as activating surface either an ellagic acid-phospholipid suspension (Cephotest) or sulfatide. Contact activation was monitored by the generation of amidolytic activity towards a synthetic chromogenic substrate (S-2302) for factor XIIa and plasma kallikrein. Bovine histidine-rich glycoprotein inhibits the contact activation induced by both of these activating surfaces.

Normal haemostasis and its regulation

Regulation of normal haemostasis and blood flow involves complex interactions between plasma proteins and blood cells, including platelets, leukocytes and the endothelial lining of blood vessels. Thrombin acts as a pivot in the maintenance of the haemostatic balance; the vascular endothelial cell in particular limits the generation of thrombin by localisation of anticoagulant processes on its luminal membrane. The endothelial cell synthesises key molecules in this process and also binds exogenously derived molecules, as well as releasing proteins of the fibrinolysis cascade. The thromboresistance of the luminal surface is further regulated by lipoxygenase and cyclo-oxygenase metabolites of unsaturated fatty acids synthesised by the endothelial cell. In response to trauma, inflammatory reactions, normal wound healing and in association with a variety of disease states, the anticoagulant and fibrinolytic mechanisms are downregulated and the procoagulant and thrombotic mechanisms predominate with resultant generation of thrombin, fibrin clot formation and subsequent platelet adhesion and aggregation. Pro-inflammatory and prothrombotic cytokines downregulate the fibrinolytic and activated protein C pathways as well as inducing synthesis of specific procoagulant and prothrombotic mediators by platelets and leukocytes as well as endothelium.

The molecular genetics of factor XI deficiency

Hereditary factor XI deficiency is characterised by a functional deficiency of factor XI and the absence of factor XI-related antigen in circulation. It occurs with a high frequency in the Ashkenazi Jewish population. Cloning of abnormal factor XI genes and studies on the molecular genetics of factor XI deficiency show that the cause for factor XI deficiency is heterogeneous. So far, two independent single base substitutions, one at the conserved intron donor consensus dinucleotide of intron N (type I) and a nonsense mutation at the codon for Glu117 (type II), have been identified. These two types of mutation together account for approximately half of the genetic changes in abnormal factor XI genes. At least one or more types of genetic change has yet to be defined. In the course of these studies, rapid methods that utilize the polymerase chain reaction and subsequent restriction endonuclease analysis have been developed.

Effect of heparin on the inhibition of the contact system enzymes

1. One can accurately predict the contribution of each inhibitor to the total inactivation of an enzyme in plasma once its pseudo-first-order reaction rate constant and concentration are known. 2. Because the mechanism of augmentation of the inactivation rate of an enzyme by ATIII occurs via formation of an ATIII-heparin complex, the degree of potentiation can be predicted by knowing the binding capacity (sites per mole) of the heparin preparation and the concentration of heparin in the reaction (to calculate the concentration of the ATIII-heparin complex). 3. The augmentation by heparin of the inactivation rate of a particular enzyme by ATIII is dependent upon the presence of other enzymes with higher kassoc, since these would strongly compete for the ATIII-heparin complex. 4. In a plasma environment, using therapeutic levels of heparin, there is no augmentation of the inactivation rate of any of the contact enzymes.

Antithrombin III activity (residual thrombin activity) in plasma from non-medicated or heparinized horses

Two synthetic substrate assays (fluorometric and chromogenic) were used to measure antithrombin-III (AT-III) activity (residual thrombin activity) in non-medicated and heparin (sodium) treated horses. In 18 non-medicated horses the fluorometric substrate assay (FSA) values were similar to previous reports but they reflected inconsistent trends and larger deviations in the heparin-treated groups (Group 2: 40 and 100 U/kg IV, n = 6; Group 3: 240 U/kg IV, n = 5; Group 4: 80 U/kg IV followed by 160 U/kg SC, n = 8) when compared to the chromogenic substrate assay (CSA) values. The CSA values for the 18 non-medicated horses indicated a higher AT-III activity (lower residual thrombin activity) than the FSA. AT-III activity was quantified in 18 non-medicated horses (29 mg/dl) and compared well with values for humans (30 mg/dl) and dogs (40 mg/dl). Plasma heparin concentrations, determined by the FSA, correlated well with the 'therapeutic range' (1.5 fold to 2.5 fold prolongation of the activated partial thromboplastin time (APTT) normal value) and values reported for humans. The effect of heparin therapy on AT-III activity in four treatment regimens was evaluated. AT-III activity was not significantly affected (with one exception) by a single dose of intravenous (IV) heparin (40 and 100 U/kg) nor by repeated subcutaneous (SC) injections of heparin (240 U/kg). A transient increase in residual thrombin activity was measured 12 h after an intravenous (80 U/kg) injection of heparin. Large doses of heparin (80 U/kg IV followed by 160 U/kg SC) given every 12 h produced a progressive prolongation of the APTT. In this group the APTT remained prolonged 48 h after the last treatment.

The heparin-catalysed inhibition of human factor XIa by antithrombin III is dependent on the heparin type

The effect of various well-characterized heparin preparations on the inactivation of human Factor XIa by human antithrombin III was studied. The heparin preparations used were unfractionated heparin and four heparin fractions obtained after anion-exchange chromatography. Inactivation of Factor XIa was monitored with S2366 as chromogenic substrate and followed pseudo-first-order reaction kinetics under all reaction conditions tested. Enhancement of the rate of inhibition of Factor XIa in the presence of unfractionated heparin correlated to the binding of antithrombin III to heparin. From the kinetic data a binding constant of 0.1 microM was inferred. The maximum rate enhancement, achieved at saturating heparin concentrations, was 30-fold. The rate enhancement achieved in the presence of each of the heparin fractions could also be correlated to the binding of antithrombin III to the heparin. The binding constant inferred from the kinetic data varied from 0.10 to 0.28 microM and the number of binding sites for antithrombin III varied from 0.06 to 0.74 site per heparin molecule. The maximum rate enhancements, achieved at saturating heparin concentrations, were strongly dependent on the type of heparin used and varied from 7-fold for fraction A to 41-fold for fraction D. Therefore, although the stimulation of Factor XIa inactivation by antithrombin III could be quantitatively correlated to the binding of antithrombin III to heparin, the heparin-catalysed inhibition of Factor XIa is dependent not only upon the degree of binding of antithrombin III to heparin but also upon the type of heparin to which antithrombin III is bound.

Contact activation of blood coagulation is inhibited by plasma factor XIII b-chain

The effect of the purified bovine plasma factor XIII b-chain on contact activation of blood coagulation was studied in human and bovine plasma using either an ellagic acid-phospholipid suspension (Cephotest) or dextran sulfate as activating surface. Contact activation was monitored by the generation of amidolytic activity towards a synthetic chromogenic substrate (S-2302) for factor XIIa and plasma kallikrein. The factor XIII b-chain, which is released from tetrameric factor XIII (a2b2) in the late stages of blood coagulation, inhibits contact activation induced by both activation surfaces mentioned. It was shown that a 5 min preincubation of the factor XIII b-chain with the activation surface increases its inhibitory effect. Light scattering measurements indicated a concurrent binding of the factor XIII b-chain to the Cephotest material. Because factor XIII (a2b2) itself had no such inhibitory activity, the present finding that the factor XIII b-chain inhibits contact activation may point to a novel feed-back inhibition mechanism of blood coagulation.

A new assay for high molecular weight kininogen in human plasma using a chromogenic substrate

High molecular weight kininogen (HK), the cofactor of contact-activated plasma proteolysis, is currently assayed by coagulant or immunological methods. The former is limited by the need for rare, congenitally-deficient plasma and a high coefficient of variation (CV), and the latter, by failure to distinguish nonfunctional protein. The surface activation of factor XI requires HK as its cofactor to transport its zymogen form to a negatively-charged surface where it is converted to its enzymatic form by factor XIIa. Based on this principle, we developed an assay for HK using the chromogenic substrate pyroGlu-Pro-Arg-p-nitroanilide (S-2366, KabiVitrum), which is hydrolyzed by factor XIa. Plasma is first acidified to inactivate protease inhibitors. After neutralization and dilution, the plasma is incubated with an excess of factor XI, factor XIIa, and soybean trypsin inhibitor (to inactivate generated kallikrein), in the presence of a negatively-charged surface (kaolin) in order to form factor XIa. EDTA is included in the buffer to prevent calcium-dependent reactions. This activation process is stopped by adding corn trypsin inhibitor to inactivate the enzyme in this reaction, factor XIIa. Then, S-2366 is added and is hydrolyzed by the factor XIa that was formed. Since factor XI and factor XIIa are in excess of the concentration of HK in the diluted plasma, HK is the rate-limiting protein in this assay for the formation of factor XIa (after subtracting the small amount of factor XIa generated in the absence of HK). The assay is specific for HK, since no activity is detected in kininogen-deficient plasma, and when compared with the HK coagulant assay, r = 0.95 and slope = 0.95. The mean of 21 normal donors was 0.98 U/ml (range 0.68 - 1.28 U/ml) as compared with pooled, normal plasma. The CV for 1 U/ml HK for the chromogenic assay was 2% as compared with 9.5% for the coagulant assay. When purified reagents become commercially available, this assay could prove useful in clinical laboratories or intensive care units for monitoring the progression of various disease states in which contact activation occurs.

Regulation of factor XIa activity by platelets and alpha 1-protease inhibitor

We have studied the complex interrelationships between platelets, Factor XIa, alpha 1-protease inhibitor and Factor IX activation. Platelets were shown to secrete an inhibitor of Factor XIa, and to protect Factor XIa from inactivation in the presence of alpha 1-protease inhibitor and the secreted platelet inhibitor. This protection of Factor XIa did not arise from the binding of Factor XIa to platelets, the presence of high molecular weight kininogen, or the inactivation of alpha 1-protease inhibitor by platelets. The formation of a complex between alpha 1-protease inhibitor and the active-site-containing light chain of Factor XIa was inhibited by activated platelets and by platelet releasates, but not by high molecular weight kininogen. These results support the hypothesis that platelets can regulate Factor XIa-catalyzed Factor IX activation by secreting an inhibitor of Factor XIa that may act primarily outside the platelet microenvironment and by protecting Factor XIa from inhibition, thereby localizing Factor IX activation to the platelet plug.

Effect of negatively charged activating compounds on inactivation of factor XIIa by Cl inhibitor

Human factor XII, upon exposure to negatively charged surfaces such as kaolin, sulfatides, and heparin, is converted to enzymatic forms, factor XIIa and factor XIIf. Cl inhibitor has been quantitatively demonstrated to be the primary plasma inhibitor of both factor XIIa and factor XIIf. Studies were performed to determine whether the presence of artificial, negatively charged surfaces influenced the ability of Cl inhibitor to inhibit factors XIIa and XIIf. Kaolin and sulfatides slowed the rate of inhibition of factor XIIa by Cl inhibitor 4.8- and 2-fold, respectively, whereas they had no effect on the inhibition of factor XIIf by Cl inhibitor. Heparin in a concentration of 65 U/ml decreased the inhibition rate of factor XIIa by Cl inhibitor, but, at the same concentration, had less of an effect on the ability of Cl inhibitor to inhibit factor XIIf. These studies indicate that negatively charged surfaces protect factor XIIa but not factor XIIf from inhibition from Cl inhibitor. Since the difference between factors XIIa and XIIf consists of the presence of a surface binding region in factor XIIa, the basis of this protection must reside in the surface binding residues of factor XII. These in vitro events suggest that surface-bound factor XIIa may hydrolyze its physiologic substrates, factor XI and prekallikrein, in an environment partially protected from inhibition by Cl inhibitor.

Intrinsic versus extrinsic coagulation. Kinetic considerations

A study to compare the kinetics of activation of factor IX by Factor XIa/Ca2+ and by Factor VIIa/tissue factor/Ca2+ has been undertaken. When purified human proteins, detergent-extracted brain tissue factor and tritiated-activation-peptide-release assays were utilized, the kinetic constants obtained were: Km = 310 nM, kcat. = 25 min-1 for Factor XIa and Km = 210 nM, kcat. = 15 min-1 for Factor VIIa. The kinetic constants for the activation of Factor X by Factor VIIa/brain tissue factor were: Km = 205 nM, kcat. = 70 min-1. Predicted rates for the generation of Factor IXa and Factor Xa were obtained when human monocytic tumour U937 cells (source of tissue factor) and Factor VIIa were used to form the activator. In other experiments, inclusion of high-Mr kininogen did not increase the activation rates of Factor IX by Factor XIa in the presence or absence of platelets and/or denuded rabbit aorta. These kinetic data strongly indicate that both Factor XIa and Factor VIIa play physiologically significant roles in the activation of Factor IX.

Congenital thrombotic disorders

The investigation of kindreds with recurrent thrombotic disease has advanced the understanding of the mechanisms of coagulation and fibrinolysis. In those cases where an etiology has been established, congenital thrombotic disorders are associated either with deficiencies or qualitative abnormalities in inhibitors of activated coagulation factors, qualitative abnormalities of fibrinogen, fibrinolytic defects that impair clot lysis, or an inborn error of metabolism, homocystinuria. The etiologies of congenital thrombotic disorders, their clinical features, and an approach to their laboratory diagnosis are summarized in this review.

Alpha-1-antitrypsin-Pittsburgh. A potent inhibitor of human plasma factor XIa, kallikrein, and factor XIIf

Alpha-1-antitrypsin-Pittsburgh is a human variant that resulted from a point mutation in the plasma protease inhibitor, alpha 1-antitrypsin (358 Met----Arg). This defect in the alpha 1-antitrypsin molecule causes it to have greatly diminished anti-elastase activity but markedly increased antithrombin activity. In this report, we demonstrate that this variant protein also has greatly increased inhibitory activity towards the arginine-specific enzymes of the contact system of plasma proteolysis (Factor XIa, kallikrein, and Factor XIIf), in contrast to normal alpha 1-antitrypsin, which has modest to no inhibitory activity towards these enzymes. We determined the second-order-inactivation rate constant (k'') of purified, human Factor XIa by purified alpha 1-antitrypsin-Pittsburgh and found it to be 5.1 X 10(5) M-1 s-1 (23 degrees C), which is a 7,700-fold increase over the k'' for Factor XIa by its major inhibitor, normal purified alpha 1-antitrypsin (i.e., 6.6 X 10(1) M-1 s-1). Human plasma kallikrein, which is poorly inhibited by alpha 1-antitrypsin (k'' = 4.2 M-1 s-1), exhibited a k'' for alpha 1-antitrypsin-Pittsburgh of 8.9 X 10(4) M-1 s-1 (a 21,000-fold increase), making it a more efficient inhibitor than either of the naturally occurring major inhibitors of kallikrein (C-1-inhibitor and alpha 2-macroglobulin). Factor XIIf, which is not inhibited by normal alpha 1-antitrypsin, displayed a k'' for alpha 1-antitrypsin-Pittsburgh of 2.5 X 10(4) M-1 s-1. This enhanced inhibitory activity is similar to the effect of alpha 1-antitrypsin-Pittsburgh that has been reported for thrombin. In addition to its potential as an anticoagulant, this recently cloned protein may prove to be clinically valuable in the management of septic shock, hereditary angioedema, or other syndromes involving activation of the surface-mediated plasma proteolytic system.

The contact activation system: biochemistry and interactions of these surface-mediated defense reactions

This review is intended to be a critical state-of-the-art overview of the activation and inhibition of the proteins (factor XII, prekallikrein, high molecular weight kininogen, and factor XI) of the contact phase of coagulation. Specifically, this review will reconsider the concept of the reciprocal activation of the proteases of the contact phase of coagulation, factor XII, and prekallikrein, in light of much recent evidence indicating that factor XII, itself, autoactivates when associated with negatively charged surfaces. In addition, the mechanisms for amplification of activation of the proteins of the contact phase of coagulation will be discussed from the pivotal role of high molecular weight kininogen, or one of its altered forms, serving as a cofactor to order the activation of the zymogens it is associated with. The role and relative importance of each of the naturally occurring plasma protease inhibitors (C1-inhibitor, alpha-2-macroglobulin, alpha-1-antitrypsin, antithrombin III, and alpha-1-antiplasmin) will be assessed as they relate to the dampening of contact phase activation. Finally, the contact phase of coagulation activation will be discussed not only as a plasma proteolytic mechanism, but also as it interacts with platelets.

Stoichiometry of binding of high molecular weight kininogen to factor XI/XIa

Factor XI is a dimeric protein and circulates in plasma complexed with high molecular weight kininogen (HMWK). We investigated the binding of HMWK to factor XIa utilizing two active site directed fluorescent probes: nitrobenzoxadiazole aminopentyl methylphosphonofluoridate for serine and dansyl-glu-gly-arg-chloromethyl ketone for histidine. In the presence of saturating amounts of HMWK, the fluorescence of factor XIa-fluorophore was quenched by approximately 28% for each probe. Titrations of the fluorescent factor XIa with HMWK revealed that each subunit of factor XIa binds one molecule of HMWK with a Kd approximately 3.4 X 10(-8)M.

Blood coagulation factor XIa binds specifically to a site on activated human platelets distinct from that for factor XI

Binding of 125I-Factor XIa to platelets required the presence of high molecular weight kininogen, was enhanced when platelets were stimulated with thrombin, and reached a plateau after 4-6 min of incubation at 37 degrees C. Factor XIa binding was specific: 50- to 100-fold molar excesses of unlabeled Factor XIa prevented binding, whereas Factor XI, prekallikrein, Factor XIIa, and prothrombin did not. When washed erythrocytes, added at concentrations calculated to provide an equivalent surface area to platelets, were incubated with Factor XIa, only a low level of nonspecific, nonsaturable binding was detected. Factor XIa binding to platelets was partially reversible and was saturable at concentrations of added Factor XIa of 0.2-0.4 microgram/ml (1.25-2.5 microM). The number of Factor XIa binding sites on activated platelets was estimated to be 225 per platelet (range, 110-450). We conclude that specific, high affinity, saturable binding sites for Factor XIa are present on activated platelets, are distinct from those previously demonstrated for Factor XI, and require the presence of high molecular weight kininogen.

Cleavage of human high molecular weight kininogen markedly enhances its coagulant activity. Evidence that this molecule exists as a procofactor

High molecular weight kininogen (HMW)-kininogen, the cofactor of contact-activated blood coagulation, accelerates the activation of Factor XII, prekallikrein, and Factor XI on a negatively charged surface. Although prekallikrein and Factor XI circulate as a complex with HMW-kininogen, no physical association has been demonstrated between Factor XII and HMW-kininogen, nor has the order of adsorption to surfaces of these proteins been fully clarified. In this report we explore the requirements for adsorption of HMW-kininogen to a clot-promoting surface (kaolin), in purified systems, as well as in normal plasma and plasma genetically deficient in each of the proteins of the contact system. The fraction of each coagulant protein associated with the kaolin pellet was determined by measuring the difference in coagulant activity between the initial sample and supernatants after incubation with kaolin, or by directly quantifying the amount of 125I-HMW-kininogen that was associated with the kaolin pellet. In normal plasma, the adsorption of HMW-kininogen to kaolin increased as the quantity of kaolin was increased in the incubation mixture. However, the HMW-kininogen in Factor XII-deficient plasma did not absorb appreciably to kaolin. Furthermore, the quantity of HMW-kininogen from prekallikrein-deficient plasma that adsorbed to kaolin was decreased as compared with normal plasma. These observations suggested that HMW-kininogen in plasma must be altered by a reaction involving both Factor XII and prekallikrein in order for HMW-kininogen to adsorb to kaolin, and to express its coagulant activity. Subsequently, the consequence of the inability of HMW-kininogen to associate with a negatively charged surface results in decreased surface activation. This assessment was derived from the further observation of the lack of prekallikrein adsorption and the diminished Factor XI adsorption in both Factor XII-deficient and HMW-kininogen-deficient plasmas, since these two zymogens (prekallikrein and Factor XI) are transported to a negatively charged surface in complex with HMW-kininogen. The percentage of HMW-kininogen coagulant activity that adsorbed to kaolin closely correlated (r = 0.98, slope = 0.97) with the amount of 125I-HMW-kininogen adsorbed, suggesting that adsorption of HMW-kininogen results in the expression of its coagulant activity. Since kallikrein, which is known to cleave HMW-kininogen, is generated when kaolin is added to plasma, we tested the hypothesis that proteolysis by kallikrein was responsible for the enhanced adsorption of HMW-kininogen to kaolin. When purified HMW-kininogen was incubated with purified kallikrein, its ability to absorb to kaolin increased with time of digestion until a maximum was reached. Moreover, (125)I-HMW-kininogen, after cleavage by kallikrein, had markedly increased affinity for kaolin than the uncleaved starting material. Furthermore, fibrinogen, at plasma concentration (3 mg/ml), markedly curtailed the adsorption of a mixture of cleaved and uncleaved HMW-kininogen to kaolin, but was unable to prevent fully cleaved HMW-kininogen from adsorbing to the kaolin. Addition of purified kallikrein to Factor XII-deficient plasma, which bypasses Factor XII-dependent contact-activation amplified the ability of its HMW-kininogen to adsorb to kaolin. These observations indicate that HMW-kininogen is a procofactor that is activated by kallikrein, a product of a reaction which it accelerates. This cleavage, which enhances its association with a clot-promoting surface in a plasma environment, is an event that is necessary for expression of its cofactor activity. These interactions would allow coordination of HMW-kininogen adsorption with the adsorption of Factor XII, which adsorbs independently of cleavage, to the same negatively charged surface.

Hepatocyte uptake of alpha 1-proteinase inhibitor-trypsin complexes in vitro: evidence for a shared uptake mechanism for proteinase complexes of alpha 1-proteinase inhibitor and antithrombin III

In vivo clearance studies have indicated that the clearance of proteinase complexes of the homologous serine proteinase inhibitors alpha 1-proteinase inhibitor and antithrombin III occurs via a specific and saturable pathway located on hepatocytes. In vitro hepatocyte-uptake studies with antithrombin III-proteinase complexes confirmed the hepatocyte uptake and degradation of these complexes, and demonstrated the formation of a disulfide interchange product between the ligand and a cellular protein. We now report the results of in vitro hepatocyte uptake studies with alpha 1-proteinase inhibitor-trypsin complexes. Trypsin complexes of alpha 1-proteinase inhibitor were prepared and purified to homogeneity. Uptake of these complexes by hepatocytes was time and concentration-dependent. Competition experiments with alpha 1-proteinase inhibitor, alpha 1-proteinase inhibitor-trypsin, and antithrombin III-thrombin indicated that the proteinase complexes of these two inhibitors are recognized by the same uptake mechanism, whereas the native inhibitor is not. Uptake studies were performed at 37 degrees C with 125I-alpha 1-proteinase inhibitor-trypsin and analyzed by sodium dodecyl sulfate-gel electrophoresis in conjunction with autoradiography. These studies demonstrated time-dependent uptake and degradation of the ligand to low molecular weight peptides. In addition, there was a time-dependent accumulation of a high molecular weight complex of ligand and a cellular protein. This complex disappeared when gels were performed under reducing conditions. The sole cysteine residue in alpha 1-proteinase inhibitor was reduced and alkylated with iodoacetamide. Trypsin complexes of the modified inhibitor were prepared and purified to homogeneity. Uptake and degradation studies demonstrated no differences in the results obtained with this modified complex as compared to unmodified alpha 1-proteinase inhibitor-trypsin complex. In addition, the high molecular weight disulfide interchange product was still present on sodium dodecyl sulfate-polyacrylamide gel electrophoresis of solubilized cells. Clearance and clearance competition studies with alpha 1-proteinase inhibitor-trypsin, alkylated alpha 1-proteinase inhibitor-trypsin, antithrombin III-thrombin, and anti-thrombin III-factor IXa further demonstrated the shared hepatocyte uptake mechanism for all these complexes.

Regulation of factor Xa in vitro in human and mouse plasma and in vivo in mouse. Role of the endothelium and plasma proteinase inhibitors

The regulation of human Factor Xa was studied in vitro in human and mouse plasma, and in vivo in mouse. In human plasma, 125I-Factor Xa bound to alpha 1-proteinase inhibitor, antithrombin III, and alpha 2-macroglobulin in a ratio of 4.9:1.9:1 as determined by gel electrophoresis and by adsorption to IgG-(antiproteinase inhibitor)-Sepharose beads. The distribution of Factor Xa in mouse plasma was similar. The clearance of Factor Xa in mice was rapid (50% clearance in 3 min) and biphasic. alpha 1-Proteinase inhibitor-trypsin, even at a 2,000-fold molar excess, failed to inhibit the clearance of Factor Xa, while alpha 2-macroglobulin-trypsin inhibited only the later phase of clearance. The plasma clearance of diisopropylphosphoryl-Factor Xa was more rapid than native Factor Xa (50% clearance in 2.5 min), and the clearance was blocked by diisopropylphosphoryl-thrombin. Electrophoresis experiments confirmed that by 2 min after injection into the murine circulation, 90% of the bound Factor Xa was on alpha 2-macroglobulin, in marked contrast to the in vitro results. Organ distribution studies at 3 and 15 min with 125I-Factor Xa demonstrated that the majority of radioactivity was in the liver, with significant radioactivity also present in lung and kidney. Autopsies performed 30 s after injection of 125I-Factor Xa also demonstrated significant binding to the aorta and vena cava. These studies indicate that Factor Xa binds to specific thrombin-binding sites on endothelial cells, and that this binding alters its proteinase inhibitor specificity. Factor Xa binds to alpha 2-macroglobulin in vivo, whereas the predominant in vitro inhibitor of Factor Xa is alpha 1-proteinase inhibitor.

Purified human plasma kallikrein aggregates human blood neutrophils

Exposure of human blood polymorphonuclear leukocytes (PMN) to purified active plasma kallikrein resulted in PMN aggregation when kallikrein was present at concentrations ranging from 0.4 to 0.6 U/ml (0.18-0.27 microM). Kallikrein-induced PMN aggregation was not mediated through C5-derived peptides, because identical responses were observed whether or not kallikrein had been preincubated with an antibody to C5. Moreover, kallikrein was specific for aggregating PMN, because no aggregation was observed with Factor XII active fragments (23 nM), Factor XIa (0.6 U/ml or 15nM), thrombin (1.6 microM), plasmin (2 microM), porcine pancreatic elastase (2 microM), bovine pancreatic chymotrypsin (2 microM), or bradykinin (1 microM). Bovine pancreatic trypsin (2 microM) aggregated PMN, but to a lesser extent than kallikrein (0.18 microM). Kallikrein was a potent aggregant agent for PMN because similar responses were observed with kallikrein (0.5 U/ml or 0.23 microM) and an optimal dose (0.2 microM) of N-formyl-methionyl-leucyl-phenylalanine. In addition, PMN incubation with kallikrein resulted in stimulation of their oxidative metabolism as assessed by an increased oxygen uptake. Neutropenia and leukostasis observed in diseases associated with activation of the contact phase system may be the result of PMN aggregation by plasma kallikrein.