Plasma prekallikrein: quantitative determination by direct activation with Hageman factor fragment (beta-XIIa)

This report describes a plasma prekallikrein assay which, unlike methods that employ contact activation, is not affected by the factor XII or HMW kininogen content of the plasma analyzed. In this assay beta-XIIa, a potent fluid-phase activator of prekallikrein, is added to diluted plasma in the presence of 20% acetone (to inactivate kallikrein inhibitors) at 30 degrees C and the kallikrein generated is measured with the chromogenic substrate S-2302. Prekallikrein is fully activated under these conditions and the activity remains stable for at least 30 hr. The mean prekallikrein concentration in plasma samples from 24 healthy individuals was 1.50 +/- 0.35 (S.D.) S-2302 U/ml, corresponding to 20.3 +/- 4.7 micrograms/ml prekallikrein (the specific activity of highly purified human prekallikrein was determined to be 74 S-2302 U/mg). In contrast, the mean concentration in five plasma samples from patients deficient in HMW kininogen was 0.38 +/- 0.02 S-2302 U/ml. No activity was generated in prekallikrein-deficient plasma, and essentially normal levels (1.35 +/- 0.18 S-2302 U/ml) were measured in plasmas from three patients with factor XII deficiency. Plasma prekallikrein was also quantitated by radial immunodiffusion, which gave results similar to those obtained by functional assay with beta-XIIa. The determination of plasma prekallikrein by direct activation with beta-XIIa in the presence of acetone offers several advantages over the use of contact activators such as dextran sulfate. These advantages include complete inactivation of kallikrein inhibitors and total activation of prekallikrein (even in plasmas deficient in other contact factors) without simultaneous generation of plasmin.     

Plasma Kallikrein Activation and Inhibition during Typhoid Fever

As an ancillary part of a typhoid fever vaccine study, 10 healthy adult male volunteers (nonimmunized controls) were serially bled 6 days before to 30 days after ingesting 10(5)Salmonella typhi organisms. Five persons developed typhoid fever 6-10 days after challenge, while five remained well. During the febrile illness, significant changes (P < 0.05) in the following hematological parameters were measured: a rise in alpha(1)-antitrypsin antigen concentration and high molecular weight kininogen clotting activity; a progressive decrease of platelet count (to 60% of the predisease state), functional prekallikrein (55%) and kallikrein inhibitor (47%) with a nadir reached on day 5 of the fever and a subsequent overshoot during convalescence. Despite the drop in functional prekallikrein and kallikrein inhibitor, there was no change in factor XII clotting activity or antigenic concentrations of prekallikrein and the kallikrein inhibitors, C1 esterase inhibitor (C1-INH) and alpha(2)-macroglobulin. Plasma from febrile patients subjected to immunoelectrophoresis and crossed immunoelectrophoresis contained a new complex displaying antigenic characteristics of both prekallikrein and C1-INH; the alpha(2)-macroglobulin, antithrombin III, and alpha(1)-antitrypsin immunoprecipitates were unchanged. Plasma drawn from infected-well subjects showed no significant change in these components of the kinin generating system. The finding of a reduction in functional prekallikrein and kallikrein inhibitor (C1-INH) and the formation of a kallikrein C1-INH complex is consistent with prekallikrein activation in typhoid fever. The correlation of these changes with the drop in platelet count suggests that a common mechanism may be responsible.     

Plasma prekallikrein assay: reversible inhibition of C-1 inhibitor by chloroform and its use in measuring prekallikrein in different mammalian species

The assay of plasma prekallikrein requires activation of prekallikrein to kallikrein and sufficient inactivation of the plasma protease inhibitors of kallikrein to accurately measure the generated kallikrein activity. One method of elimination of the plasma protease inhibitors to kallikrein is to chemically pretreat the plasma. Methylamine has previously been employed to selectively inactivate alpha 2-macroglobulin. Our study examines the effect of sequential preincubation of plasma with chloroform and methylamine on the plasma prekallikrein assay. Chloroform was demonstrated to be a chemical inhibitor of purified C-1 inhibitor, but alpha 2-macroglobulin was not. Chloroform inhibition of C-1 inhibitor was not caused by precipitation of the protein into the interface between the water and organic solvent phase. Greater than 95% of C-1 inhibitor antigen was recovered in the supernatant of chloroform-treated purified C-1 inhibitor, and chloroform-saturated buffer inhibited purified C-1 inhibitor. Chloroform did not dissociate a preformed complex of kallikrein and C-1 inhibitor, but its inhibition of C-1 inhibitor was reversible. The addition of methylamine to plasma pretreated with chloroform in the plasma prekallikrein assay allowed for only a slight increase in the amount of kallikrein measured at 1 minute kaolin activation times, but provided for sustained measurement of activated prekallikrein when kaolin activation times were 5 to 7 minutes. Without chemical pretreatment, prekallikrein was not measurable in rabbit plasma. Both rabbit and pig plasma prekallikrein was measurable after exposure of the plasma to chloroform and methylamine, although the peak activation times and the contribution of each animals' protease inhibitors varied with the species. Our results show that chloroform is a reversible inhibitor of C-1 inhibitor, and that the plasma prekallikrein assay in which it is used is useful for the measurement of prekallikrein in nonhuman mammalian plasma samples.     

Function and Immunochemistry of Prekallikrein-High Molecular Weight Kininogen Complex in Plasma

Plasma from individuals with high molecular weight (HMW) kininogen deficiency has been reported to be deficient in prekallikrein as measured by radial immunodiffusion, prekallikrein coagulant activity, and/or kaolin-activated arginine esterase activity. The discovery that prekallikrein and HMW kininogen circulate as a complex in plasma led us to reevaluate the antigenic and functional properties of prekallikrein in HMW kininogen-deficient plasma as well as in normal plasma.     

Anaphylactic release of a prekallikrein activator from human lung in vitro.

We have demonstrated the in vitro IgE-mediated release of a prekallikrein activator from human lung. The lung prekallikrein activator was partially purified by sequential chromatography on sulfopropyl-Sephadex, DEAE-Sephacel, and Sepharose 6B. Purified human prekallikrein was converted to its active form (kallikrein) by the lung protease. The generated kallikrein was shown to be biologically active; that is, it generates bradykinin from purified human high-molecular weight kininogen and also cleaves benzoyl-propyl-phenyl-arginyl-p-nitroanilide, a known synthetic substrate of kallikrein. The lung prekallikrein activator differs from the known physiologic activators of prekallikrein (the activated forms of Hageman factor) with respect to: (a) size (it has a mol wt of approximately 175,000); (b) synthetic substrate specificity (D-propyl/phenyl/arginyl-p-nitroanilide is a substrate for the activated forms of Hageman factor, but not the lung protease); (c) antigenic specificity (an anti-Hageman factor immunoadsorbent column did not remove significant amounts of the lung protease, while it removed most of the activity of activated Hageman factor fragments); and (d) inhibition profile (the lung proteases was not inhibited by corn trypsin inhibitor). This prekallikrein activator provides a physiologic mechanism by which prekallikrein can be directly activated during IgE-mediated reactions of the lung. While the role of this lung prekallikrein activator in immediate hypersensitivity reactions and in other inflammatory processes is not clear, it does represent a first and important interface between IgE-mediated reactions and the Hageman factor-dependent pathways of the inflammatory response.     

Prorenin-renin conversion by the contact activation system in human plasma: role of plasma protease inhibitors

Acid-pretreated normal human plasma generates renin activity at 0 degree C and neutral pH by the activation of prorenin. The activation is caused by kallikrein generated from prekallikrein by activated factor XII. Nonacidified plasma also generates renin at 0 degree C, but at a lower rate (cold-promoted activation). In normal plasma, 14% +/- 1% of prorenin (mean +/- SEM, n = 30) was activated during incubation at 0 degree C for 7 days (range 6% to 26%). Cold-promoted activation of prorenin was within the normal range in plasma deficient in factor XI, X, IX, VIIIC, VII, V, prothrombin, or high mol wt kininogen. Cold-promoted activation of prorenin was less than or equal to 1% in plasma deficient in factor XII or prekallikrein. Reconstitution of these plasmas with highly purified factor XII or prekallikrein restored normal prorenin activation. Correction of high mol wt kininogen deficiency had no effect. Thus cold-promoted activation of prorenin depends on the presence of factor XII and prekallikrein, whereas the other clotting factors are not essential. The influence of the inhibitors C1 esterase-inhibitor, alpha 2-macroglobulin, antithrombin III, and alpha 1-antitrypsin on the activation of prorenin was studied in factor XII-deficient plasma from which one or more of these inhibitors had been selectively removed by immunoadsorption. Factor XII was subsequently added, and the generation of renin at 37 degrees C was observed after complete factor XII-high mol wt kininogen-mediated activation of prekallikrein induced by dextran sulfate. No activation of prorenin was observed at 37 degrees C after depletion of C1 esterase inhibitor, alpha 2-macroglobulin, antithrombin III, or alpha 1-antitrypsin. When prekallikrein was activated in plasma depleted of both C1 esterase-inhibitor and alpha 2-macroglobulin, 6% of prorenin was activated in 2 hours at 37 degrees C. After additional depletion of antithrombin III, the activation increased to 47%. These results indicate that the contact activation system is capable of activating prorenin in plasma at physiologic pH and temperature when the three most important kallikrein inhibitors, C1 esterase-inhibitor, alpha 2-macroglobulin, and antithrombin III, are absent.     

Potentiation of the function of Hageman factor fragments by high molecular weight kininogen.

Patients lacking high molecular weight (HMW) kininogen have profound abnormalities of the Hageman factor-dependent pathways of coagulation, kinin formation, and fibrinolysis. The ability of HMW kininogen to potentiate the Hageman factor fragments (HFf) activation of prekallikrein and Factor XI in plasma was studied. HFf only partially converted Factor XI to XIa and prekallikrein to kallikrein in plasma deficient in HMW kininogen (Williams trait), while enhanced activation of Factor XI and prekallikrein by HFf resulted after reconstitution with HMW kininogen. In a system using highly purified components, HMW kininogen increased the initial rate of prekallikrein activation whether the kallikrein formed was assayed by arginine esterase activity or kininforming ability. The potentiation of prekallikrein activation occurred over a 12-fold range of enzyme (HFf) concentration and was nonhyperbolic with respect to substrate (prekallikrein). HMW kininogen exerted its effect even in the absence of prekallikrein since the hydrolysis of acetylglycyl-lysine methyl ester by HFf was increased by HMW kininogen. These results suggest that one of the functions of HMW kininogen is to augment the catalytic action of HFf.     

Alteration of factor VII activity by activated Fletcher factor (a plasma kallikrein): a potential link between the intrinsic and extrinsic blood-clotting systems.

Although surface contact is known to accelerate the one-stage prothrombin time of human plasma through the participation of Hageman factor (factor XII) and factor VII, it has not been clear whether Hageman factor interacts with factor VII directly or indirectly. Recently, Gj?nnaess reported experiments suggesting that plasma kallikrein was an intermediate between Hageman factor and factor VII. The present study was undertaken to elucidate the interaction of plasma kallikrein and factor VII. Incubation of Fletcher-trait plasma (deficient in a plasma prekallikrein) with kaolin at 0 degrees C. did not induce shortening of the Thrombotest time or enhancement of factor VII activity, in contrast to studies of normal plasma. Monospecific rabbit antiserum against plasma kallikrein blocked the shortening of the Thrombotest time of normal plasma brought about by kaolin. Purified Hageman factor fragments (prekallikrein activator) induced an increase in factor VII activity in normal or Hageman-trait plasma, but not in Fletcher-trait plasma. A purified plasma kallikrein preparation enhanced factor VII activity in all plasmas, including that of Fletcher-trait plasma. The effect of the kallikrein preparation was blocked by soybean trypsin inhibitor, Trasylol, or rabbit antiserum against kallikrein, but not by lima bean trypsin inhibitor or antiserum against Hageman factor. The activity of partially purified factor VII was enhanced by purified kallikrein in the presence, but not in the absence of factor VII-deficient plasma. These results further support the idea that the enhancement of factor VII activity by surface contact is via Hageman factor and plasma kallikrein, suggesting a possible link between the intrinsic and extrinsic pathway of blood clotting. The significance of this phenomenon in hemostasis in vivo remains to be elucidated.     

Radial-immunodiffusion assay of human apolipoprotein A-I with use of two monoclonal antibodies combined

We produced and characterized several monoclonal antibodies directed toward human plasma apolipoprotein A-I. Two of them, A-I-12 and A-I-57, individually precipitated purified or native high-density lipoprotein in agarose gel by double immunodiffusion. Because radial immunodiffusion performed with a single monoclonal antibody gave faint and diffuse rings of precipitation, we developed and optimized working conditions for using these two monoclonal antibodies combined to determine apolipoprotein A-I in human plasma. This combination gave easy-to-measure, clear, sharp rings, and linear and parallel standard curves for HDL3 (the primary standard) and a reference serum (the secondary standard). Moreover, no pretreatment of samples with dissociating agents or detergents is necessary. The assay was complete after overnight incubation, as compared with two to three days when polyclonal antisera were used. Apolipoprotein A-I concentrations as measured in 128 normolipidemic subjects and in 72 patients with various lipid disorders by the radial immunodiffusion technique with monoclonal antibodies (x) compared well (r = 0.882; y = 1.029x-0.036) with those measured by radial immunodiffusion with polyclonal antisera (y).     

Part of purified human plasma kallikrein removed together with a remaining IgG fraction--immunoblot experiments and functional tests

In the present study it is shown that a preparation of highly purified plasma kallikrein (specific activity 81 S-2302 U/mg) still contained small amounts of an IgG fraction.Amidase assays of the fresh enzyme with four peptide substrates (S-2302, Bz-Pro-Phe-Arg-pNA, S-2366, S-2222) did not reveal any inhomogeneity, and immunoblot experiments with antibodies against prekallikrein yielded only an 85 kD double band. After a storage period (2 years at : 70°C), S-2366 and S-2222 amidase activities not reflecting the initial kallikrein appeared. Immunoblot studies with Fc-specific antibodies against IgG showed a 170 kD band, and immunoblots with a monoclonal antibody against prekallikrein demonstrated that, in addition to the 85 kD band, a band with a mol weight of about 152 kD could also be detected. Immunoblots showed that only 85 kD kallikrein was recovered in the eluate from Protein G columns, and amidase assays based on S-2302 and Bz-Pro-Phe-Arg-pNA showed a recovery of about 70%. The other part of the kallikrein (30%) was removed along with the additional S-2366 and S-2222 activities and the IgG3 fraction present. The theory is advanced that the additional activity reflects a kallikrein fraction with a mol weight of about 152 kD, and is present in the fresh enzyme preparation in inactive complex with IgG. Storage of the kallikrein preparation led to some weakening of this complex and the appearance of functional activities of the kallikrein fraction involved.     

Part of purified human plasma kallikrein removed together with a remaining IgG fraction--immunoblot experiments and functional tests

In the present study it is shown that a preparation of highly purified plasma kallikrein (specific activity 81 S-2302 U/mg) still contained small amounts of an IgG fraction. Amidase assays of the fresh enzyme with four peptide substrates (S-2302, Bz-Pro-Phe-Arg-pNA, S-2366, S-2222) did not reveal any inhomogeneity, and immunoblot experiments with antibodies against prekallikrein yielded only an 85 kD double band. After a storage period (2 years at -70 degrees C), S-2366 and S-2222 amidase activities not reflecting the initial kallikrein appeared. Immunoblot studies with Fc-specific antibodies against IgG showed a 170 kD band, and immunoblots with a monoclonal antibody against prekallikrein demonstrated that, in addition to the 85 kD band, a band with a mol weight of about 152 kD could also be detected. Immunoblots showed that only 85 kD kallikrein was recovered in the eluate from Protein G columns, and amidase assays based on S-2302 and Bz-Pro-Phe-Arg-pNA showed a recovery of about 70%. The other part of the kallikrein (30%) was removed along with the additional S-2366 and S-2222 activities and the IgG3 fraction present. The theory is advanced that the additional activity reflects a kallikrein fraction with a mol weight of about 152 kD, and is present in the fresh enzyme preparation in inactive complex with IgG. Storage of the kallikrein preparation led to some weakening of this complex and the appearance of functional activities of the kallikrein fraction involved.     

Human plasma prekallikrein (Fletcher factor) clotting activity and antigen in health and disease

Human plasma prekallikrein (Fletcher factor) clotting activity and antigen levels have been examined in various clinical conditions. Prekallikrein antigen was measured by a newly developed, specific, and sensitive radioimmunoassay. The assay had no demonstrable cross-reactivity with human urinary kallikrein nor, in the species tested, animal plasma prekallikrein. This assay was able to measure plasma kallikrein after its biological functions had been inactivated by plasma inhibitors. Normal human pooled plasma contained approximately 50 microgram/ml prekallikrein. Quantitative measurement of plasma prekallikrein was possible for concentrations as low as 0.3% of that of normal pooled plasma. A good correlation (correlation coefficient = 0.71) existed between titers of plasma prekallikrein measured by Fletcher factor clotting assays and radioimmunoassays among 40 normal subjects. Both prekallikrein clotting activity and antigen were significantly reduced in plasmas of patients with advanced hepatic cirrhosis or DIC. Prekallikrein activity and antigen were mildly decreased in plasmas or serums of patients with chronic renal failure and nephrotic syndrome but were normal in those of patients under treatment with warfarin or suffering from SLE, rheumatoid arthritis, sarcoidosis, or HANE. Human cord serum contained a lower titer of prekallikrein antigen than adult serum. Strenuous physical exercise did not significantly change plasma prekallikrein levels.     

Heterogeneity of human factor V deficiency. Evidence for the existence of antigen-positive variants

Functional human Factor V has been purified using a rapid immunoaffinity method. Following barium citrate adsorption of plasma, Factor V was precipitated with polyethylene glycol at a concentration between 5 and 14%. The resulting preparation was applied to a column containing an immobilized immunoadsorbent consisting of an IgG fraction containing a naturally occurring human monoclonal (IgG(4)lambda) antibody with inhibitory activity against human Factor V. The solid phase immunoglobulin quantitatively bound Factor V from human plasma. The bound Factor V was effectively eluted with a Tris buffer pH 7.2 containing 1.2 M NaCl and 1 M alpha-methyl-D-mannoside. The isolated native Factor V with high specific activity (92 U/mg) showed a single band (M(r), 350,000) on both reduced and nonreduced sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Factor V was purified 5,100-fold over plasma with an overall yield of 77%. The purified Factor V when subjected to thrombin activation exhibited an 18-fold increase in coagulant activity.The isolated Factor V neutralized the inhibitory activities of the monoclonal antibody that was used to purify it, as well as the rabbit antibodies produced by immunizing the animals with the purified Factor V. Immunoelectrophoresis of purified Factor V against the polyclonal rabbit antiserum resulted in a single precipitin arc of identical mobility to the Factor V in normal human plasma. Analysis by double immunodiffusion showed a line of identity between plasma and purified Factor V and crossed immunoelectrophoresis showed a single species in normal plasma.A competitive enzyme-linked immunosorbent assay using the rabbit antibody against Factor V was applied to quantify Factor V antigen level in human plasma. Reconstitution of congenitally deficient or immunodepleted plasma with normal plasma or purified Factor V gave parallel dose-response curves. In 14 normal plasma the coagulant activity was 0.98+/-0.02 U/ml (mean+/-SEM) and antigen concentration was 11.1+/-0.4 mug/ml. A pool of 14 patients with congenital Factor V deficiency were studied. 10 patients had Factor V antigen ranging from 1.0 to 2.4 mug/ml with corresponding coagulant activities (0-0.17 U/ml) indicating a low concentration of normal Factor V, presumably due to decreased synthesis or increased degradation. When these patient plasmas and the normal plasmas were analyzed together an excellent correlation (r = 0.97, P < 0.01) was obtained. However, four patients with coagulant activity (0-0.08 U/ml) had Factor V antigen concentrations ranging from 4.4 to 6.1 mug/ml, indicating the presence of a reduced concentration of abnormal Factor V protein. The presence of patients with antigen similar in concentration to coagulant activity and antigen in excess of Factor V activity indicates the heterogeneity of congenital Factor V deficiency.     

The use of the kallikrein-kininogen system indices in the prognosis of the development of hemorrhagic erysipelas]

A number of the kallikrein-kinin system parameters (kallikrein, prekallikrein, total arginine esterase activity, alpha 1 protease inhibitor, and alpha 2 macroglobulin) were measured in 59 patients with erythematous erysipelas and in 51 ones with hemorrhagic erysipelas over the course of the disease. Marked activation of the blood kallikrein-kinin system was seen in all the patients during the initial period of the disease, manifesting by elevated levels of kallikrein, total arginine esterase activity, alpha 1 protease inhibitor, alpha 2 macroglobulin, and a lowered prekallikrein concentration. In erythematous erysipelas the peak of activation was recorded in the first days of the disease, whereas in hemorrhagic condition it was observed during the second week of erysipelatous inflammation. Different patterns of changes in the kallikrein-kinin system over the course of the disease permit using one of its parameters, kallikrein activity, for the prediction of the development of local hemorrhagic syndrome in erysipelas patients already during the earliest (prehemorrhagic) stage of the condition.     

Removal of IgG from normal plasma and plasma from untreated patients with active Crohn's disease--effect on levels of contact factors

Protein G columns were used to remove IgG from human plasma, and the effect on levels of factor XII, factor XI and prekallikrein was studied in functional tests. IgG was detected in PAGE immunoblot experiments with Fc-specific antibodies. Removal of the bulk of IgG in a procedure based on a low plasma dilution (1+2.5) allowed the passage of an IgG fraction along with the contact factors. This fraction was found to be present in higher amounts in plasma from patients with Crohn's disease (n=5) than in control plasma (n=12). In a previous study, PAGE immunoblot experiments showed that part of the prekallikrein was removed along with IgG when a higher plasma dilution (1+10.8) was used (Scand J Clin Lab Invest 1999; 59: 55-64). This observation was supported by results in the present work based on parallel assays with the peptide substrates S-2302 and Bz-Pro-Phe-Arg-pNA. The prekallikrein fraction removed was present in a functional state differing from the main part of prekallikrein by yielding kallikrein with a significantly increased activity against the substrate S-2366. This prekallikrein fraction was present in higher amounts in patient plasma than in control plasma. Part of the corresponding amidase activity was blocked by lima bean trypsin inhibitor, suggesting its presence in association with factor XI. The results also indicated that prekallikrein activator activity was connected with this fraction. With the high dilution procedure an extensive removal of IgG from the patient plasma was obtained compared to the control plasma.     

Urinary excretion of diazepam metabolites in healthy volunteers and drug users

Protein G columns were used to remove IgG from human plasma, and the effect on levels of factor XII, factor XI and prekallikrein was studied in functional tests. IgG was detected in PAGE immunoblot experiments with Fc-specific antibodies. Removal of the bulk of IgG in a procedure based on a low plasma dilution (1+2.5) allowed the passage of an IgG fraction along with the contact factors. This fraction was found to be present in higher amounts in plasma from patients with Crohn's disease (n=5) than in control plasma (n=12). In a previous study, PAGE immunoblot experiments showed that part of the prekallikrein was removed along with IgG when a higher plasma dilution (1+10.8) was used (Scand J Clin Lab Invest 1999; 59: 55-64). This observation was supported by results in the present work based on parallel assays with the peptide substrates S-2302 and Bz-Pro-Phe-Arg-pNA. The prekallikrein fraction removed was present in a functional state differing from the main part of prekallikrein by yielding kallikrein with a significantly increased activity against the substrate S-2366. This prekallikrein fraction was present in higher amounts in patient plasma than in control plasma. Part of the corresponding amidase activity was blocked by lima bean trypsin inhibitor, suggesting its presence in association with factor XI. The results also indicated that prekallikrein activator activity was connected with this fraction. With the high dilution procedure an extensive removal of IgG from the patient plasma was obtained compared to the control plasma.     

Activation of Human Factor VII in Plasma and in Purified Systems: ROLES OF ACTIVATED FACTOR IX, KALLIKREIN, AND ACTIVATED FACTOR XII

Factor VII can be activated, to a molecule giving shorter clotting times with tissue factor, by incubating plasma with kaolin or by clotting plasma. The mechanisms of activation differ. With kaolin, activated Factor XII (XII(a)) was the apparent principal activator. Thus, Factor VII was not activated in Factor XII-deficient plasma, was partially activated in prekallikrein and high-molecular weight kininogen (HMW kininogen)-deficient plasmas, but was activated in other deficient plasmas. After clotting, activated Factor IX (IX(a)) was the apparent principal activator. Thus, Factor VII was not activated in Factor XII-,HMW kininogen-, XI-, and IX-deficient plasmas, but was activated in Factor VIII-, X-, and V-deficient plasmas. In further studies, purified small-fragment Factor XII(a) (beta-XII(a)), kallikrein, and Factor IX(a) were added to partially purified Factor VII and to plasma. High concentrations of beta-XII(a) activated Factor VII in a purified system; much lower concentrations of beta-XII(a) activated Factor VII in normal plasma but not in prekallikrein or HWM kininogen-deficient plasmas. Kallikrein alone failed to activate partially purified Factor VII but did so when purified Factor IX was added. Kallikrein also activated Factor VII in normal, Factor XII-, and Factor IX-deficient plasmas. Purified Factor IX(a) activated partially purified Factor VII and had no additional indirect activating effect in the presence of plasma. These results demonstrate that both Factor XII(a) and Factor IX(a) directly activate human Factor VII, whereas kallikrein, through generation of Factor XII(a) and Factor IX(a), functions as an indirect activator of Factor VII.     

Separation of Plasma Thromboplastin Antecedent from Kallikrein by the Plasma α2-Macroglobulin, Kallikrein Inhibitor

Plasma thromboplastin antecedent (PTA, factor XI) is an important intermediate in the intrinsic coagulation system, and plasma kallikrein has been implicated as a mediator of the inflammatory process. Whereas their biologic activities are functionally distinct, their identity as separate entities in plasma has not been fully established, and the nature of their plasma inhibitors has not been completely characterized. A partially purified preparation containing the clotting, tosyl arginine methyl ester (TAMe) esterase and kinin-producing activities of these substances has been prepared by DEAE-cellulose chromatography of a Celite eluate obtained from acid-treated human plasma. These activities were not separable by acrylamide gel electrophoresis nor by isoelectric focusing, their pI being approximately 8.7. Human plasma alpha(2)-macroglobulin has been shown to inhibit the proteolytic activity of kallikrein and to inhibit partially its TAMe esterase activity. An alpha(2)-macroglobulin, PTA, kallikrein incubation mixture was separated by gel filtration chromatography. The alpha(2)-macroglobulin formed a high molecular weight complex with kallikrein and appeared in early chromatographic fractions. The PTA-clotting activity was not inhibited by the alpha(2)-macroglobulin; 64% of the initial PTA activity was isolated in later fractions free of kallikrein-induced kinin-like activity. In contrast, clotting, TAMe esterase, and kinin-forming activities were inhibited after gel filtration chromatography of an incubation mixture of these activities and partially purified C1 inactivator (C1 esterase inhibitor). Electrofocusing of an incubation mixture of an activated PTA, kallikrein preparation, and alpha(2)-macroglobulin resulted in the isolation of a PTA fraction free of kallikrein proteolytic activity, and with 4% of the original TAMe esterase activity. In this manner, activated PTA and plasma kallikrein have been shown to be distinct substances, and methods have been introduced for the further purification of active coagulation factor XI.     

Changes in the indicators of the fibrinolytic and kallikrein-kinin systems in patients with calculous pyelonephritis

A total of 48 patients with calculous pyelonephritis were examined before and after surgery. A study was made of the fibrinolytic system (according to the status of XIIa kallikrein-dependent fibrinolysis, lysis of the plasma clots and euglobulin lysis) and of the kallikrein-kinin system of the plasma (according to kallikrein activity, kininogen content, kininase activity, spontaneous esterase activity and prekallikrein content). The patients with calculos pyelonephritis demonstrated KKS activation and fibrinolysis reduction related to both the lowering of the activator levels and elevation of antiplasmin levels, which in turn created the risk of thrombophilia in this group of patients.     

Contact activation of human plasma prorenin in vitro

Acid activation of plasma prorenin occurs during dialysis to pH 3.3. and also during subsequent dialysis to pH 7.4. The latter, alkaline phase, involves Hageman factor-dependent formation of kallikrein, which in turn activates prorenin. The present study evaluates whether prorenin activation always occurs whenever kallikrein is activated in plasma. TAME esterase activity was used as a measure of plasma kallikrein activity an increase was observed during the alkaline phase of acid activation of prorenin. TAME esterase activity was absent when Hageman factor- or prekallikrein-deficient plasmas were similarly assayed and prorenin was not activated. Kaolin treatment of normal plasma rapidly increased TAME esterase activity at both 25 degrees and -4 degrees C, but no prorenin activation occurred. Similar changes in TAME esterase activity were observed in acid-treated plasma, in which setting prorenin was activated. No change in TAME esterase or renin activity occurred after addition of kaolin to acid-treated plasma deficient in Hageman factor; however, both enzymatic activities increased slightly in acidified prekallikrein-deficient plasma. Mixtures of these deficient plasmas exhibited normal kaolin activation of both TAME esterase and prorenin after acidification. Thus both Hageman factor and prekallikrein are needed for optimal contact activation of prorenin. These results demonstrate that prorenin activation does not always occur when active kallikrein is present in plasma. Prior acidification appears to be a prerequisite. Acidified prorenin may be more susceptible to cleavage; alternatively, competing substrates and/or inhibitors of kallikrein may be destroyed at acid pH, thereby permitting kallikrein to activate prorenin. Under normal conditions, activation of the plasma kallikrein-kinin system appears unlikely to result in activation of prorenin in vivo.