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.     

Factor XII-induced fibrinolysis. Diminished proactivator activity and drastic reduction of activator activity in Fletcher factor-deficient plasma gamma globulin

Fibrinolytic studies in gamma G fractions of three Fletcher factor-deficient plasmas (functionally deficient in prekallikrein) revealed weak or no factor XII-independent activator activity. Two of the three Fletcher trait patients showed no plasminogen activator activity in clot lysis, fibrin plate, and amidolytic assays. The third patient showed no activator activity as determined by clot lysis and amidolytic assays but gave 10% of the activator activity detected in normal undiluted gamma G fraction in absence of HFf when determined by fibrin plate assay. Normal plasma gamma G fractions showed detectable and significant plasminogen activator activity. These fractions did not contain kallikrein or activated factor XI activities, thus indicating that the activator activity could not be attributed to the presence in these fractions or trace of these activated factors. Furthermore, factor XI-deficient plasma gamma G fraction, which was shown to contain no activated prekallikrein, showed normal plasminogen activator activity. Finally, specific antibodies to prekallikrein were shown not to quench the activity of plasminogen activator present in normal plasma gamma fraction. A double genetic deficiency to explain the absence in Fletcher factor-deficient plasma gamma G fractions of both prekallikrein proactivator and activator activities is not likely. Thus plasma prekallikrein, besides being a known plasminogen proactivator, appears to be required for the expression of a plasminogen activator activity.     

Kallikrein modification with affinity to IgG present in higher amounts than normal in plasma from patients with Crohn's disease

This study presents immunological and functional evidence to suggest that the activation of prekallikrein (PK) in human plasma yields two modifications of kallikrein. One of these modifications showed amidolytic properties strongly deviating from those registered for the main part of the enzyme. The substrates were S‐2302, Bz‐Pro‐Phe‐Arg‐pNA, S‐2366 and S‐2222. In PAGE immunoblots the PK heavy chain mAb 13G11 was found to detect the kallikrein 85?kD double band and bands with mol. weights of about 152 and 135?kD. Such a 152?kD band could be removed together with an IgG fraction on a Protein G column. In this study the kallikrein identity was confirmed by an estimation of the levels obtained in amidolytic assays of mixtures of normal plasma and plasma deficient in FXI, which in immunological assays showed a PK level of 140–150% of normal. A comparison in amidolytic assays of normal plasma and plasma from patients with Crohn's disease showed that patients' plasma contained a significantly higher level than normal of modified kallikrein. An IgG removal procedure removed all modified kallikrein, and did not affect ordinary kallikrein levels.     

Kallikrein modification with affinity to IgG present in higher amounts than normal in plasma from patients with Crohn's disease

This study presents immunological and functional evidence to suggest that the activation of prekallikrein (PK) in human plasma yields two modifications of kallikrein. One of these modifications showed amidolytic properties strongly deviating from those registered for the main part of the enzyme. The substrates were S-2302, Bz-Pro-Phe-Arg-pNA, S-2366 and S-2222. In PAGE immunoblots the PK heavy chain mAb 13G11 was found to detect the kallikrein 85 kD double band and bands with mol. weights of about 152 and 135 kD. Such a 152 kD band could be removed together with an IgG fraction on a Protein G column. In this study the kallikrein identity was confirmed by an estimation of the levels obtained in amidolytic assays of mixtures of normal plasma and plasma deficient in FXI, which in immunological assays showed a PK level of 140-150%, of normal. A comparison in amidolytic assays of normal plasma and plasma from patients with Crohn's disease showed that patients' plasma contained a significantly higher level than normal of modified kallikrein. An IgG removal procedure removed all modified kallikrein, and did not affect ordinary kallikrein levels.     

Centrifugal analysis for plasma kallikrein activity, with use of the chromogenic substrate S-2302

The amidolytic activity of activated kallikrein in plasma can be measured by use of the chromogenic substrate, S-2302 (H-D-Pro-Phe-Arg-pNA). Plasma prekallikrein was activated to kallikrein by exposure to 50 mg/L dextran sulfate in acetone/water (35/65 by vol) at 0 degrees C for 15 min. The acetone slows anti-kallikrein activity and increases the kallikrein activity by 30%. The 37 degrees C reaction mixture contained 0.54 mmol of S-2302 substrate per liter of Tris buffer (pH 7.5 at 37 degrees C). We monitored the change in absorbance at 405 nm for 60 s. The specificity of the substrate for kallikrein was demonstrated by using plasma deficient in prekallikrein (Fletcher trait) diluted with pooled normal human plasma. We recommend collecting blood specimens with sodium citrate as the anticoagulant and with use of a double-syringe technique and all-plastic containers. Plasma kallikrein activity with Chromozym-PK (Bz-Pro-Phe-Arg-pNA) as substrate (y-axis) compared with S-2302 as substrate (x-axis) gave the relation: y = 0.28x + 0.82 (r = 0.94). Day-to-day analytical variation was 2.4% for a pooled plasma with a mean value of 85.9 mukat/L. The mean (and 2 SD) for 50 healthy adults was 86.4 (32.4) mukat/L.     

Activation of Hageman factor (factor XII) by sulfatides and other agents in the absence of plasma proteases

Incubation of purified human HF (factor XII) with sulfatides, EA, kaolin, or glass resulted in the generation of amidolytic activity in the apparent absence of other enzymes. Sulfatides or EA rapidly and efficiently initiated intrinsic coagulation in normal plasma but, under the conditions tested, only trivially corrected the prolonged partial thromboplastin clotting times of plasma deficient in prekallikrein or HMWK. Preliminary incubation of HF with crude IgG directed against plasma kallikrein or SBTI did not influence the results. The presence of albumin greatly enhanced activation of the amidolytic properties of purified HF by EA, even when albumin had been lipid-extracted or treated with DFP or SBTI; albumin also increased activation of HF by sulfatides. Internal cleavage and minimal scission of the HF molecule accompanied the generation of amidolytic properties in mixtures of HF and sulfatides; cleavage was not blocked by SBTI. These experiments demonstrate that negatively charged substances can activate HF in absence of other enzymes and that this activation is accompanied by formation of a two-chain species of HF.     

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.     

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.     

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.     

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.     

Characterization of a variant prekallikrein, prekallikrein Long Beach, from a family with mixed cross-reacting material-positive and cross-reacting material-negative prekallikrein deficiency.

Studies of plasma prekallikrein in a family with prekallikrein deficiency were made. Three children had no clotting activity but approximately 35% antigen levels, and the mother and five children had twice as much prekallikrein antigen as clotting activity, suggesting the presence of a dysfunctional molecule. A nonfunctional variant form of prekallikrein was purified that contained no prekallikrein clotting activity. The variant and normal molecules were both 80,000 mol wt, immunologically indistinguishable and complexed similarly with high molecular weight kininogen. Isoelectric focusing studies suggested a difference of one charged amino acid residue. The variant was cleaved by beta-Factor XIIa 200 times slower than the normal molecule, and no amidolytic activity was detected for the cleaved variant. These data and other observations suggest that an amino acid was substituted in the variant near the NH2-terminal end of the kallikrein light chain resulting in slower cleavage by beta-Factor XIIa and the absence of enzymatic activity.     

Plasma kallikrein and prorenin in patients with hereditary angioedema

Recent evidence indicates that plasma kallikrein is activated during acute attacks of hereditary angioedema. Plasma kallikrein is known to convert inactive renin, or prorenin, into an active proteolytic enzyme in plasma exposed to acid or low temperatures as well as in purified systems. To establish whether plasma kallikrein could activate prorenin under physiologic or pathologic conditions, prorenin to renin conversion was assessed at neutral pH in plasma deficient in C1 inhibitor (hereditary angioedema). In these plasma samples lacking the two major inhibitors of kallikrein and possessing less than 10% of the inhibitory activity of normal plasma, prorenin was not converted to an active enzyme despite conditions under which prekallikrein was completely activated to plasma kallikrein and despite normal prorenin concentrations and activability.     

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.     

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.     

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.     

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.     

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.     

Inactivation of kallikrein in human plasma

Human plasma kallikrein is inactivated by plasma protease inhibitors. This study was designed to determine the nature of these protease inhibitors and to assess their relative importance in the inactivation of kallikrein. Therefore, the kinetics of kallikrein inactivation and the formation of kallikrein inhibitor complexes were studied in normal plasma and in plasma depleted of either alpha 2-macroglobulin (alpha 2M), C1 inhibitor, or antithrombin (AT III). Prekallikrein was activated by incubation of plasma with dextran sulfate at 4 degrees C. After maximal activation, kallikrein was inactivated at 37 degrees C. Inhibition of kallikrein amidolytic activity in AT III-deficient plasma closely paralleled the inactivation rate of kallikrein in normal plasma. The inactivation rate of kallikrein in alpha 2M-deficient plasma was slightly decreased compared with normal plasma, but in contrast to normal, C1 inhibitor-deficient, and AT III-deficient plasma, no kallikrein amidolytic activity remained after inactivation that was resistant to inhibition by soybean trypsin inhibitor. Suppression of kallikrein activity in C1 inhibitor-deficient plasma was markedly decreased, and this was even more pronounced in plasma deficient in both C1 inhibitor and alpha 2M. The pseudo first-order rate constants for kallikrein inactivation in normal, AT III-deficient, alpha 2M-deficient, C1 inhibitor-deficient plasma, and plasma deficient in both alpha 2M and C1 inhibitor, were 0.68, 0.60, 0.43, 0.07, and 0.016 min-1, respectively. Sodium dodecyl sulfate gradient polyacrylamide slab gel electrophoresis showed that during inactivation of kallikrein in plasma, high-Mr complexes were formed with Mr at 400,000-1,000,000, 185,000, and 125,000-135,000, which were identified as complexes of 125I-kallikrein with alpha 2M, C1 inhibitor, and AT III, respectively. In addition, the presence of an unidentified kallikrein-inhibitor complex was observed in AT III-deficient plasma. 52% of the 125I-kallikrein was associated with C1-inhibitor, 35% with alpha 2M, and 13% with AT III and another protease inhibitor. A similar distribution of 125I-kallikrein was observed when the 125I-kallikrein inhibitor complexes were removed from plasma by immunoadsorption with insolubilized anti-C1 inhibitor, anti-alpha 2M, or anti-AT III antibodies. These results suggest that only covalent complexes are formed between kallikrein and its inhibitors in plasma. As a function of time, 125I-kallikrein formed complexes with C1 inhibitor at a higher rate than with alpha 2M. No difference was observed between the inactivation rate of kallikrein in high-Mr kininogen-deficient plasma and that in high-Mr kininogen-deficient plasma reconstituted with high-Mr kininogen; this suggests that high-Mr kininogen does not protect kallikrein from inactivation in the plasma milieu. These results have quantitatively demonstrated the major roles of C1 inhibitor and alpha 2M in the inactivation of kallikrein in plasma.     

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.     

Fitzgerald Trait: Deficiency of a Hitherto Unrecognized Agent, Fitzgerald Factor, Participating in Surface-Mediated Reactions of Clotting, Fibrinolysis, Generation of Kinins, and the Property of Diluted Plasma Enhancing Vascular Permeability (PF/Dil)

The prolonged partial thromboplastin time observed in the plasma of a 71-yr-old asymptomatic man was related to the deficiency of a hitherto unrecognized agent. The patient's plasma also exhibited impaired surface-mediated fibrinolysis and esterolytic activity and impaired generation of kinins and of the property enhancing vascular permeability designated PF/Dil. The patient's plasma contained normal amounts of all known clotting factors except Fletcher factor (a plasma prekallikrein) which was present at a concentration of 10-15% of pooled normal plasma. Fletcher trait plasma, however, contained normal amounts of the agent missing from the patient's plasma and corrected the defects in clotting, fibrinolysis, and vascular permeability. Fletcher trait plasma was less effective in correcting generation of kinins and esterolytic activity, presumably because of the patient's partial deficiency of prekallikrein. The site of action of the factor deficient in the patient's plasma appeared to be subsequent to the activation of Hageman factor and plasma prekallikrein. A fraction of normal plasma, devoid of other clotting factors, corrected the defect in clotting in the patient's plasma; a similar fraction of the patient's plasma did not correct this abnormality. No evidence yet exists pointing to the familial nature of the patient's defect. Tentatively, the patient's disorder may be referred to by his surname as Fitzgerald trait, and the agent apparently deficient in his plasma as Fitzgerald factor.