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.     

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.     

Determination of prekallikrein in human plasma: optimal conditions for activating prekallikrein

A method for the assay of human plasma prekallikrein in which a chromogenic synthetic tripeptide, PPAN, is used as a substrate for kallikrein is described. The conversion of prekallikrein to kallikrein is achieved by cold activation (0 degrees C) with water-soluble dextran sulfate. Conditions for obtaining optimal amounts of free kallikrein with respect to concentration of dextran sulfate, activation time, inhibitors (C-1-inactivator), and requirement of factor XII have been determined. The activation procedure is compared to other known procedures. The assay system was worked out for pooled normal plasma and is applicable to any plasma sample not liable to unwanted preactivation or incomplete inactivation, as revealed by control experiments. A survey in 15 apparently health individuals showed a mean activity of 476 +/- 58 (S.D.) mU/ml with a range of 385 to 586 mU/ml.     

Enzymes of the contact phase of blood coagulation: kinetics with various chromogenic substrates and a two-substrate assay for the joint estimation of plasma prekallikrein and factor XI

Kinetic constants (Km and kcat) of kallikrein and factor XIa for the chromogenic substrates H-D-L-prolyl-L-phenylanyl-L-arginine-p-nitroanilide (S-2302) and L-pyroglutamyl-L-propyl-L-arginine-p-nitroanilide (S-2366) were determined. The determined constants allow the use of S-2302 and S-2366 in an assay that leads to the joint estimation of factor XI and prekallikrein in activated plasma. The assay reports approximately 3.1 micrograms/ml factor XIa and 34.5 micrograms/ml kallikrein in kaolin-activated plasma (kaolin content 2 mg/ml). The dual-substrate amidolytic assay shows good correlation with the coagulant assay of both factors (0.92 with the prekallikrein assay and 0.98 with the factor XI assay). It is capable, through the joint estimation of factor XI and prekallikrein levels, of differentiating among plasma samples deficient in components of the contact phase of blood coagulation. Kinetic constants of factor beta-XIIa (factor XII fragment) for these substrates and for N-benzol-L-isoleusyl-L-glutamyl-glycyl-L-arginine-P-nitro ani lide (S-2222) were determined, and they allowed the assessment of the contribution of this factor to this assay and its estimation in the activated phase.     

Prekallikrein activator (Hageman factor fragment) in human plasma fractions

The recent finding that hypotensive reactions to blood products can be attributed to the presence of a prekallikrein activator in the products, prompted us to measure the distribution of this substance among plasma fractions produced by the cold ethanol method. While the levels observed varied among different production lots, prekallikrein activator was found to be present in four lots of fibrinogen, four lots of immune serum globulin, one lot of immune serum globulin for intravenous use, and nine lots of antihemophilic factor. Nineteen lots of 25% albumin were tested and found to be free of detectable amounts of prekallikrein activator. In addition to 25% albumin and the fraction V rework fractions leading to it, only supernatant III from the fraction II + III reworks was found to be free of the prekallikrein activator. All other fractions contained significant amounts of activity. Chloroform treatment, used to move kallikrein inhibitors was found to destroy the prekallikrein activator in fractions with low protein levels. The prekallikrein activator in antihemophilic factor preparations was formed during contact with glass, and its behavior led to the conclusion that these concentrates contained Hageman factor (Factor XII).     

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.     

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.     

Surface and fluid phase activities of two forms of activated Hageman factor produced during contact activation of plasma

The ability of the two forms of activated Hageman factor (HFa) produced during contact activation of plasma to activate prekallikrein and factor XI was studied. alpha-HFa, defined as an 80,000 mol wt two-chain enzyme which remains bound to the surface was capable of cleaving surface-bound prekallikrein and factor XI. beta-HFa, a 28,000 mol wt single chain molecule, released from the surface during contact activation was able to cleave prekallikrein but showed no activity on factor XI. Cleavage of prekallikrein by beta-HFa occurred irrespective of whether the substrate was surface-bound or in solution. Cleavage of factor XI occurred only when it was surface bound and only the alpha- form of HFa was capable of this proteolytic action. Factor XI was found to remain bound to the surface while prekallikrein and kallikrein rapidly dissociated from the surface into the supernate. These findings suggest that the initiation of intrinsic coagulation through the activation factor XI is a localized event occurring at the site of contact activation and is the result of the action of alpha-HFa. By contrast, kinin generation and fibrinolysis resulting from the formation of kallikrein can be initiated either at the site of contact activation, by alpha-HFa action, or throughout the plasma, by beta-HFa; further dissemination of these activities is assured by the rapid dissociation of kallikrein itself from the surface.     

Immunochemical Studies of Plasma Kallikrein

A monospecific antibody against human plasma kallikrein has been prepared in rabbits with kallikrein further purified to remove gamma globulins. The antisera produced contained antikallikrein and also anti-IgG, in spite of only 8% contamination of kallikrein preparation with IgG. The latter antibody was removed by adsorption of antisera with either Fletcher factor-deficient plasma or with purified IgG. Both kallikrein and prekallikrein (in plasma) cross-react with the antibody with no apparent difference between the precipitation arcs developed during immunoelectrophoresis and no significant difference in reactivity when quantified by radial immunodiffusion.Kallikrein antibody partially inhibits the esterolytic and fully inhibits the proteolytic activity of kallikrein. In addition, the antibody inhibits the activation of prekallikrein, as measured by esterase or kinin release. The magnitude of the inhibition is related to the molecular weight of the activator used. Thus, for the four activators tested, the greatest inhibition is observed with kaolin and factor XII(A), while large activator and the low molecular weight prekallikrein activators are less inhibited.With the kallikrein antibody, the incubation of kallikrein with either plasma or partially purified C1 esterase inactivator results in a new precipitin arc, as detected by immunoelectrophoresis. This finding provides physical evidence for the interaction of the enzyme and inhibitor. No new arc could be demonstrated between kallikrein and alpha(2)-macroglobulin, or alpha(1)-antitrypsin, although the concentration of free kallikrein antigen decreases after interaction with the former inhibitor.By radial immunodiffusion, plasma from healthy individuals contained 103+/-13 mug/ml prekallikrein antigen. Although in mild liver disease, functional and immunologic kallikrein are proportionally depressed, the levels of prekallikrein antigen in plasma samples from patients with severe liver disease remains 40% of normal, while the functional kallikrein activity was about 8%. These observations suggest that the livers of these patients have synthesized a proenzyme that cannot be converted to active kallikrein.     

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.     

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.     

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.     

Mechanized assay of plasma prekallikrein by activation with Pseudomonas aeruginosa elastase and amidolysis of chromogenic substrate.

An automated assay of plasma prekallikrein is described. Prekallikrein was converted to kallikrein with Pseudomonas aeruginosa elastase, and the hydrolytic activity of kallikrein to H-D-Pro-Phe-Arg-paranitroanilide subsequently measured.

The conversion was complete within 8 minutes and the amidolytic activity remained stable at least another 10 min at 37 ° C. This method worked in plasma deficient in Hageman factor (blood coagulation factor XII). Using anti-prekallikrein antibody and plasma deficient in prekallikrein, the amidolytic activity generated in normal plasma was identified as due to kallikrein. With plasma samples, the coefficients of variation (CV) for multiple measurements within run (n = 10) and between run (n = 10) were as low as 5.0% and 6.6%, respectively, and the minimum measurable concentration of prekallikrein in plasma was 10% of the normal level.     

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.     

Mechanized assay of plasma prekallikrein by activation with Pseudomonas aeruginosa elastase and amidolysis of chromogenic substrate

An automated assay of plasma prekallikrein is described. Prekallikrein was converted to kallikrein with Pseudomonas aeruginosa elastase, and the hydrolytic activity of kallikrein to H-D-Pro-Phe-Arg-paranitroanilide subsequently measured.The conversion was complete within 8 minutes and the amidolytic activity remained stable at least another 10 min at 37 ° C. This method worked in plasma deficient in Hageman factor (blood coagulation factor XII). Using anti-prekallikrein antibody and plasma deficient in prekallikrein, the amidolytic activity generated in normal plasma was identified as due to kallikrein. With plasma samples, the coefficients of variation (CV) for multiple measurements within run (n = 10) and between run (n = 10) were as low as 5.0% and 6.6%, respectively, and the minimum measurable concentration of prekallikrein in plasma was 10% of the normal level.     

Evaluation of the plasma kinin system in dengue hemorrhagic fever.

The role of the plasma kinin system in the pathogenesis of dengue hemorrhagic fever (DHF) ws explored by simultaneously measuring factor XLL (Hageman), prekallikrein, kallikrein inhibitors, bradykinin, and complement (C3) in the blood of Thai children with DHF and acute febrile illnesses other than dengue. Prekallikrein, factor XII, and C3 levels were significantly lower in DHF patients compared to fever control patients with the lowest mean levels found in dengue patients with shock. However, bradykinin concentrations were not elevated and mean activity levels of kallikrein inhibitors were not depressed in dengue patients. Two dengue patients first studies at least 2 days before onset of shock had falling C3 levels which were more closely related temporally to the onset of shock than were their rising levels of prekallikrein. The results fail to provide convincing evidence ofr activation of the plasma kinin system leading to free bradykinin or a significant role for bradykinin in the immunopathogenesis of DHF. By contrast, the results refocus attention on complement as a potentially important humoral mediator of the dengue shock syndrome.     

Fletcher factor deficiency. A diminished rate of Hageman factor activation caused by absence of prekallikrein with abnormalities of coagulation, fibrinolysis, chemotactic activity, and kinin generation

Fletcher factor-deficient plasma is deficient in prekallikrein and therefore generates no bradykinin upon activation with kaolin. It also possesses a diminished rate of kaolin-activable coagulation and fibrinolysis and possesses a defect in kaolin-activable chemotactic activity. These abnormalities are also corrected by reconstitution with purified prekallikrein. Addition of intact activated Hageman factor corrected the coagulation, fibrinolytic, and chemotactic defects and addition of Hageman factor fragments corrected the fibrinolytic defect and partially corrected the chemotactic defect; neither of these corrected the kinin-generating defect. Although the Hageman factor-dependent pathways appear to be initiated by contact activation of Hageman factor, the kallikrein generated activates more Hageman factor; this feedback is necessary for the Hageman factor-dependent pathways to proceed at a normal rate. It is the absence of this feedback in Fletcher factor-deficient plasma that accounts for the diminished rate of activation of Hageman factor and therefore a diminished rate of activation of the coagulation and fibrinolytic pathways. The ability of prekallikrein to correct the coagulation, fibrinolytic, kinin-generating, and chemotactic defects of Fletcher factor-deficient plasma is consistent with the identity of the Fletcher factor and prekallikrein.     

Activation and function of human Hageman factor. The role of high molecular weight kininogen and prekallikrein.

The activation and function of surface-bound Hageman factor in human plasma are dependent upon both high molecular weight (HMW) kininogen and prekallikrein. HMW kininogen does not affect the binding of Hageman factor to surfaces, but it enhances the function of surface-bound Hageman factor as assessed by its ability to activate prekallikrein and Factor XI. The initial conversion of prekallikrein to kallikrein by the surface-bound Hageman factor in the presence of HMW kininogen is followed by a rapid enzymatic activation of Hageman factor by kallikrein. The latter interaction is also facilitated by HMW kininogen. Kallikrein therefore functions as an activator of Hageman factor by a positive feedback mechanism and generates most of the activated Hageman factor during brief exposure of plasma to activating surfaces. HMW kininogen is a cofactor in the enzymatic activation of Hageman factor by kallikrein and it also augments the function of the activated Hageman factor generated. The stoichiometry of the Hagman factor interaction with HMW kininogen suggests that it enhances the activity of the active site of Hageman factor. Since HMW kininogen and prekallikrein circulate as a complex, HMW kininogen may also place the prekallikrein in an optimal position for its reciprocal interaction with Hageman factor to proceed. The surface appears to play a passive role upon which bound Hageman factor and the prekallikrein-HMW kininogen complex can interact.     

Dissemination of contact activation in plasma by plasma kallikrein

The dissemination of contact activation of plasma was examined by measuring the cleavage of Hageman factor (HF) molecules on two separate sets of kaolin particles, one of which contained all of the components of the contact activation system, HF, prekallikrein (PK) and high molecular weight kininogen (HMWK) in whole normal plasma, and the second set of particles containing only HF and HMWK, being prepared with PK-deficient plasma. After mixing of the particles, cleavage of HF on the second set of particles occurred at a rate similar to that occurring on the first set of particles. This indicated that rapid dissemination and burst of activity of the contact reaction takes place in fluid phase. A supernatant factor, responsibel for the dissemination of the contact reaction, was identified as kallikrein. A rapid appearance of cleaved PK (kallikrein) and HMWK on both the kaolin surface and in the supernate was observed. Within 40 s, > 70-80% of the PK and HMWK in the supernate was cleaved. On the surface, approximately 70% of each radiolabeled protein was cleaved at the earliest measurement. Cleavage of PK by activated HF occurred at least 17 times faster on the surface than in the fluid phase, as virtually no cleavage of PK occurred in fluid phase. Each molecule of surface-bound, activated HF was calculated to cleave at a minimum, 20 molecules of PK per minute. It is concluded that the contact activaton of plasma may be divided into three phases: (a) the reciprocal activation of a few molecules of zymogen HF and PK on the surface, with HMWK acting as cofactor to bring these molecules into apposition; (b) the rapid release of kallikrein into the fluid phase and the continued conversion of PK to kallikrein by each surface-bound molecule of activated HF; and (c) the activation by fluid-phase kallikrein of multiple surface-bound HF molecules, and the cleavage of multiple molecules of MHWK both in fluid phase and on the surface by the soluble kallikrein. The evidence suggests that steps b and c account for a great majority of the generation of contact activation of plasma.