Purification of high molecular weight kininogen and the role of this agent in blood coagulation

Profiling of hydroxyurea-treated β-thalassemia/ serum proteome through nano-LC-ESI-MS/ MS in combination with microsol-isoelectric focusing

Advancements in proteomic tools offer a comprehensive solution to studying the complexity of diseases at molecular level. This study focusses on the clinical proteomic profiling of pre- and post-hydroxyurea (HU)-treated β-thalassemia patients in parallel with healthy individuals to better understand the role of HU in the treatment of β-thalassemia. The strategy encompasses sequential high-resolution protein fractionation using MicroSol-isoelectric focusing (ZOOM- IEF) followed by one-dimensional SDS-PAGE before nano-RP-LC-MS/ MS analysis of tryptic peptides. Protein identification was performed through Mascot search using NCBInr and SwissProt databases. Several different proteins were observed in pool serum samples of each of the three study groups. Approximately, 1250 proteins exclusive to each group were identified, and after removing the redundant and low sequence coverage proteins, the number was reduced to 576 (201 in healthy, 187 in HU-untreated and 188 in HU-treated group). Uniquely identified proteins in the HU-treated group regulate the focal adhesion, ECM-receptor interaction, PI3K-Akt signaling, Rap1 signaling, cAMP signaling, platelet activation, and Ca²⁺ signaling pathways in the HU-treated group. The proteomic profile presented here will add to the current state of understanding of molecular mechanisms involved in hydroxyurea treatment of β-thalassemia.

Novel interactomics approach identifies ABCA1 as direct target of evodiamine, which increases macrophage cholesterol efflux

Evodiamine, a bioactive alkaloid from the fruits of the traditional Chinese medicine Evodia rutaecarpa (Juss.) Benth. (Fructus Evodiae, Wuzhuyu), recently gained attention as a dietary supplement for weight loss and optimization of lipid metabolism. In light of its use by patients and consumers, there is an urgent need to elucidate the molecular targets affected by this natural product. Using a novel interactomics approach, the Nematic Protein Organisation Technique (NPOT), we report the identification of ATP-binding cassette transporter A1 (ABCA1), a key membrane transporter contributing to cholesterol efflux (ChE), as a direct binding target of evodiamine. The binding of evodiamine to ABCA1 is confirmed by surface plasmon resonance (SPR) experiments. Examining the functional consequences of ABCA1 binding reveals that evodiamine treatment results in increased ABCA1 stability, elevated cellular ABCA1 protein levels, and ultimately increased ChE from THP-1-derived human macrophages. The protein levels of other relevant cholesterol transporters, ABCG1 and SR-B1, remain unaffected in the presence of evodiamine, and the ABCA1 mRNA level is also not altered.

Key parameters in blood-surface interactions of 3D bioinspired ceramic materials

Direct contact of materials with blood components may trigger numerous processes which ultimately lead to hemolysis, clot formation and recruitment of inflammatory cells. In this study, the blood-surface interactions for two inert bioinspired ceramic scaffolds obtained from natural resources; biomorphic carbon and silicon carbides (bioSiC) from different origins have been studied. The response of the blood in contact with carbon is well known, however little has been identified on the influence of their 3D porous structure. Moreover, to our knowledge, there is no reference in the literature about the hemocompatibility of biomorphic silicon carbide as a porous scaffold. The experimental results showed the surface energy to be crucial to evaluate the hemocompatibility of a material however the surface topography and material porosity are also parameters to be considered. Surface roughness modifies clot formation whereas for protein adsorption total sample porosity seems to be the key parameter to be considered for hydrophilic materials (biomorphic silicon carbides), while the size of the pores determines the hemolytic response.

Structural gene encoding human factor XII is located at 5q33-qter

The gene encoding human factor XII (F12) or Hageman factor has been mapped to 5q33-qter. This has been achieved by analyzing the results obtained from hybridizing a cloned fragment from the factor XII gene to a panel of human-hamster somatic cell hybrid DNAs and also by in situ hybridization to normal human metaphase cells. The previously reported results localizing F12 to 6p23 are discussed.

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

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

Radioimmunoassays of human high and low molecular weight kininogens in plasmas and platelets

Radioimmunoassays of human high molecular weight kininogen (HMWK) and low molecular weight kininogen (LMWK) were developed using antibodies directed against the light and the heavy chains of kallikrein-cleaved HMWK. With the anti-light chain antibodies, the radioimmunoassay was specific for HMWK with a detection limit of 0.4 ng. The anti-heavy chain antibodies were used to quantify the concentration of total kininogen antigens. In four different plasmas with a congenital deficiency in HMWK procoagulant activity, there was no detectable antigen in two cases and trace amounts, less than 1 micrograms/ml in the other plasmas (normal concentration: 72 +/- 6 micrograms/ml). In the absence of HMWK, the radioimmunoassay performed with the anti-heavy chain antibodies was specific for LMWK. The amount of LMWK was different in each of these patients' plasmas, ranging from no detectable antigen, i.e. less than 0.15 micrograms/ml, to a normal content. Antigens immunologically indistinguishable from plasma kininogens were detected in lysates of five times washed platelets. HMWK antigen concentration was 3.17 +/- 0.87 micrograms per 10(11) platelets (mean value in 11 donors). LMWK was also present in platelet lysates and the relative concentration versus HMWK was the same as in plasma.

Rodent kinin-forming enzyme systems--I. Purification and characterization of plasma kininogen

Low molecular weight (LMW) kininogen was purified 70-fold with a 16% yield from fresh rat plasma by DEAE-Sephadex chromatography, ammonium sulfate precipitation, Sephadex G-200 gel filtration, SP-Sephadex chromatography, CM-cellulose chromatography, and Sephadex G-200 gel filtration. Ferguson plots of polyacrylamide gel electrophoretic patterns revealed four bands with relative molecular weights of 64,000, 123,500, 252,436 and 357,900 (ratio of 1:2:4:6). Sodium dodecyl sulfate (SDS)-polyacrylamide gel electrophoresis provided a single protein band with a molecular weight of 72,000, suggesting that the four kininogen bands had been caused by the aggregation of a single oligomeric protein. The purified LMW rat kininogen Fraction B (3.9 micrograms bradykinin/mg) was used to elicit an antiserum in the rabbit. Monospecificity of the antiserum was demonstrated by immunoelectrophoresis (Laurell rocket and Grabar methods) and, thus, the homogeneity of the kininogen was also. The purified kininogen (both Fractions A and B) formed kinin with human urinary kallikrein, rat urinary kallikrein and hog pancreatic kallikrein. Murphy-Sturm lymphosarcoma acid protease also formed kinin when incubated with the kininogen at pH 3.0. The isoelectric point for both fractions was at pH 4.3. Amino acid analyses showed the two kininogen fractions to be rich in acidic amino acids and to have a total carbohydrate content of 8.5% consisting of galactose (1.2 to 1.5%), mannose (1.9 to 2.1%), N-acetylglucosamine (4.3 to 5.1%), N-acetylgalactosamine (0.3%), and sialic acid (0.68%).

Studies on a family with combined functional deficiencies of vitamin K-dependent coagulation factors

Two siblings with m ild hemorrhagic symptoms had combined functional deficiencies of vitamin K-dependent clotting factors. Prothrombin (0.18-0.20 U/ml) and Stuart factor (Factor X, 0.18-0.20 U/ml) and Stuart factor (Factor X, 0.18-0.20 U/ml) were most severely affected. Antigenic amounts of affected coagulation factors were normal and normal generation of thrombin activity occurred in the patients' plasmas after treatment with nonophysiologic activators that do not require calcium for prothrombin activation. Hepatobilary disease, malabsorptive disorders, and plasma warfarin were not present. Both parents had normal levels of all coagulation factors. The patients' plasmas contained prothrombin that reacted both with antibody directed against des-gamma-carboxyprothrombin and native prothrombin. Crossed immunoelectrophoresis of patients' plasmas and studies of partially purified patient prothrombin suggested the presence of a relatively homogeneous species of dysfunctional prothrombin, distinct from the heterologous species found in the plasma of warfarin-treated persons. These studies are most consistent with a posttranslational defect in hepatic carboxylation of vitamin K-dependent factors. This kindred uniquely possesses an autosomal recessive disorder of vitamin K-dependent factor formation that causes production of an apparently homogeneous species of dysfunctional prothrombin; the functional deficiencies in clotting factors are totally corrected by oral or parenteral administration of vitamin K1.

Some molecular and functional changes in high molecular weight kininogen induced by plasmin and trypsin

When purified human HMW-kininogen was digested by plasmin, its specific antigenic properties were initially enhanced and then gradually destroyed, but its clot-promoting activity (Fitzgerald factor activity) was only slightly decreased. When endogenous serum plasminogen was activated by streptokinase, similar alterations in specific HMW-kininogen antigens and Fitzgerald factor activity occurred. In contrast, trypsin induced increased antigenic properties initially, but readily destroyed the Fitzgerald factor activity and less readily destroyed the specific HMW-kininogen antigenic properties in purified HMW-kininogen and in normal human serum. When normal serum was treated with streptokinase, the antigenic properties shared by HMW and LMW-kininogens were in Sephadex G-200 fractions of lower molecular weight than in the case of untreated serum, but the elution volumes of specific HMW-kininogen antigens and Fitzgerald factor activity were not significantly altered. When prekallikrein-deficient serum was subjected to the same G-200 gel filtration process, there was a broad overlap in the elution volumes of antigens shared by both HMW and LMW-kininogens with specific HMW-kininogen antigenic and coagulant properties, which remained after streptokinase treatment of the serum. Depsite the disparate rates of destruction of the antigenic and clot-promoting portion of HMW-kininogen by proteases these properties did not separate from one another during ion exchange chromatography.

Contact activation of factor XI

Factor XI is a circulating trace plasma protein composed of two similar or identical chains of about 80 000 daltons which upon activation undergo proteolytic cleavage. Recently, we have shown that trypsin activation leads to an active factor XI (factor XIa) which, on reduction, yields three chains of 46 000, 37 000 and 26 000 daltons. Herein, we re-evaluate the effect of contact activation of factor XI at an activating surface both in normal human plasma and in a mixture of purified factors XI, XII, and high molecular weight kininogen (HMWK). Mixtures were analysed by coagulant activity and by reduced sodium dodecyl sulphate polyacrylamide gel electrophoresis using [125I]factor XI. In the purified system, fully activated factor XI on reduction yielded chains of 46 000, 37 000 and 23 000 daltons. In contrast, factor XI activated by surface contact in plasma yielded on reduction only chains of 46 000 and 37 000 daltons in addition to some uncleaved 80 000 chain. We propose that factor XIa containing only 46 000 and 37 000 chains be designated factor XIa alpha, and that factor XIa containing the third chain of 23 000 daltons be designated factor XI a beta. Sequential elution of contact activated plasma factor XI revealed that factor XIa was attached to the glass surface through the 46 000 dalton chain.

Activation of factor XII in rat plasma: protection by benzamidine of the cofactor function of high molecular weight kininogen

Factor XII has been assayed as kaolin-activated prekallikrein activator in rat citrated plasma pretreated with acetone (Briseid et al. 1978 & 1979; Briseid & Berstad 1979). In the present work benzamidine added during blood collection increased the extent of activation by a factor of 6. Rat high molecular weight kininogen (HMWK) added to acetone-treated citrated plasma likewise increased the activation, providing evidence of the protection by benzamidine of the cofactor function of HMWK. All cofactor capacity was retained after the removal of the kinin part of HMWK. Experiments carried out with plasminogen-free plasma showed that plasmin could hardly be the the factor responsible for the destruction of HMWK. The stoichiometric factor XII concentration-effect curve obtained by diluting acetone-treated rat plasma with acetone-treated human factor XII deficient plasma showed that factor XII is present in functional excess, the concentration of HMWK deciding the extent of activation. By diluting acetone-treated rat plasma with buffer, HMWK concentration-effect curves were obtained which were approximately linear over a range of 0.03-0.40 microgram (bradykinin equivalents) per ml kaolin incubate. No further activation of factor XII was obtained at 0.80 microgram/ml.

A convenient large-scale preparation of high molecular weight kininogen from human plasma

Human high molecular weight (HMW) kininogen was purified by chromatography on DEAE-Sephadex A-50 and CM-Sephadex C-50, followed by gel filtration on Sephadex G-50. From 5 l fresh human plasma approximately 120 mg HMW kininogen was obtained. The yield was 40%. The preparation had a specific activity of 14 microgram bradykinin equivalent/A280 unit. Upon polyacrylamide disc gel electrophoresis HMW kininogen was separated into two close bands, whereas only one band with an apparent Mr of 120 000 was obtained in sodium dodecyl sulfate electrophoresis. Both protein fractions separated in disc gel electrophoresis released kinins upon incubation with kallikreins. The purified HMW kininogen had an isoelectric point of 4.65 when measured by isoelectric focusing. The amino acid composition of the purified HMW kininogen is given. The amino terminus of the molecule is blocked. In oligomerization studies adducts with molecular weights up to 810 000 were obtained. HMW kininogen gave a single precipitin arc in immunoelectrophoresis with antiserum directed against HMW kininogen.

Protection of human plasma kallikrein from inactivation by C1 inhibitor and other protease inhibitors. The role of high molecular weight kininogen

High Mr kininogen increases the activation rate of prekallikrein by activated factor XII on a surface. The resulting serine protease, plasma kallikrein, Mr 88 000, is inhibited in plasma by C1 inhibitor, Mr 105 000. Since prekallikrein circulates in plasma with high Mr kininogen as a complex and a kallikrein-high Mr kininogen complex can be formed in purified systems, we studied whether the inhibition of kallikrein by C1 inhibitor was influenced by high Mr kininogen. With C1 inhibitor in excess, the inactivation of kallikrein followed pseudo-first-order kinetics. The second-order rate constant for the reaction was 1.7 X 10(4) M-1 s-1, and a kallikrein-C1 inhibitor complex, Mr 190 000 was identified on polyacrylamide gel electrophoresis in the presence of sodium dodecyl sulfate. Kallikrein and C1 inhibitor formed an irreversible complex without measurable prior equilibrium. The rate of this reaction was decreased by 50% in the presence of high Mr kininogen (1 unit/mL or 0.73 muM). Kinetic analysis indicated that this protection was the result of the formation of a reversible complex between kallikrein and high Mr kininogen, which had a dissociation constant of 0.75 muM. However, low Mr kininogen did not protect kallikrein from inactivation by C1 inhibitor. High Mr kininogen also protected kallikrein from inactivation by diisopropyl fluorophosphate. These findings suggest that the kallikrein-high Mr kininogen complex was formed by noncovalent interactions between the light chains of both kallikrein and high Mr kininogen.

Activation of factor XII in plasma from rats pretreated with tranexamic acid. Inhibition of a plasmin-induced loss of the functional activity of high molecular weight kininogen

Incubation of plasma from rats pretreated with tranexamic acid (40 mg/100 g) with acetone (23% V/V) yielded enzyme preparations in which all the plasminogen present was recovered as plasmin and a plasmin-like substance without affinity for lysine-Sepharose. This substance, designated "plasmin", was separated from plasmin and kallikrein in a three-step procedure using columns of lysine-Sepharose, DEAE-Sephadex A-50, and arginine-Sepharose. The ratios of fibrinolytic, caseinolytic, LEe esterase, BAEe esterase and kininogenase activities of "plasmin" corresponded well with those of rat plasmin and human plasmin. Both rat plasmin and "plasmin" destroyed the capacity of high molecular weight kininogen (HMWK) to function as a cofactor in the activation of factor XII in rat plasma, without causing a corresponding release of the kinin part of the molecule. Rat plasma kallikrein induced full release of kinin from HMWK, but the functional capacity was retained. It is suggested that the reduced extent of activation of factor XII observed in plasma from rats injected intravenously with dextran, or rat plasma that has been passed through a column with lysine-Sepharose, is due to the loss of functional HMWK caused by plasmin activated in vivo or on the column.

Surface activation of blood coagulation, fibrinolysis and kinin formation

The activation of plasma prekallikrein by single-chain factor XII has been studied in the presence of high molecular weight kininogen and kaolin. The data indicate that factor XII can initiate blood coagulation, fibrinolysis or kinin generation in the presence of kaolin and does so by converting prekallikrein to kallikrein. An enzyme cascade is then generated leading to the formation of fibrin, plasmin or bradykinin in three closely related physiological events.

Purification of a high molecular weight kininogen from rat plasma

A high molecular weight kininogen has been isolated from rat plasma and purified. At each preparative step the kininogen concentration and purity were monitored by assay on the perfused isolated rat uterus in terms of bradykinin equivalents formed per mg protein following incubation of the plasma fractions with rodent acid protease for 24 hours at 37 degrees and pH 4.0. Kinin formation by crystalline trypsin and human pancreatic kallikrein also was compared. Citrated rat plasma first was precipitated with 43% ammonium sulfate. The kininogen fractions then were subjected to a series of gel filtration ion exchange chromatographic columns that included G-200 Sephadex, G-200: G-100 Sephadex interconnected columns, DEAE-A50 Sephadex, and hydroxylapatite. The kininogen fractions finally were subjected to preparative polyacrylamide gel electrophoresis, resulting in a final purification of 92.9-fold compared to the initial rat plasma. A single major kininogen protein band and a minor band of protein impurity were obtained on disc gel electrophoresis. Only the pancreatic kallikrein did not form kinin from this purified kininogen. The apparent molecular weight was estimated by SDS polyacrylamide gel technique to be 110,000.

Molecular assembly in the contact phase of the Hageman factor system

Data obtained in the past few years have defined the molecular mechanisms of contact activation of the Hageman factor pathways of plasma, i.e., the kinin-forming, intrinsic clotting and fibrinolytic systems. Involved are four molecules: Hageman factor, high molecular weight (MW) kininogen, prekallikrein and factor XI. High MW kininogen serves as a surface cofactor to assemble prekallikrein or factor XI in proximity to surface-bound Hageman factor. Reciprocal proteolytic activation of Hageman factor and prekallikrein represents an essential step in the rapid activation of the contact phase. Although Hageman factor does undergo cleavage and activation in the absence of prekallikrein or high MW kininogen, the rate is approximately 50 and 100 times slower than when these molecules are present. Once Hageman factor is activated on the surface, it cleaves and activates clotting factor XI. Activated Hageman factor (HFa) exhibits two molecular forms. One of these, alpha HFa, activates prekallikrein and factor XI, and the intrinsic clotting system on the surface. alpha HFa and clotting factor XI remain surface bound. The other form of activated Hageman factor, beta HFa, leaves the surface, going into solution where it readily activates additional prekallikrein but not factor XI. Of perhaps even greater importance, kallikrein rapidly dissociates from the surface. Thus the formation of bradykinin and fibrinolysis is disseminated whereas clotting via the intrinsic system remains localized. Reviewed here is the molecular mechanism of contact activation of the Hageman factor pathways and discussed in the interaction of Hageman factor with the negatively charged surface, prekallikrein, factor XI and high MW kininogen. The multiple forms of activated Hageman factor and their potential biologic significance are also discussed.

Platelets and surface-mediated clotting activity

In contrast to previously reported studies, no evidence could be adduced for the activation of Hageman factor (factor XII) by platelets, whether or not these cells had been incubated with adenosine diphosphate (ADP).

Relation between structure and correcting activity of bovine high molecular weight kininogen upon the clotting time of Fitzgerald-trait plasma

Bovine high molecular weight kininogen (bHMWK) partially corrects the activated plasma thromboplastin time (aPTT) of Fitzgerald trait plasma which is congenitally deficient in HMWK. The relationship between the structure and activity of HMWK was clarified by studying the effects of different fragments of bHMWK on the aPTT of Fitzgerald-trait plasma. The peptides studied were lys-bradykinin-free HMWK, bradykinin-fragment 1-2-free HMWK, heavy chain, fragment 1-2-light chain, and light chain. All fragments were tested in equimolar concentrations. Bradykinin-fragment 1-2-free HMWK, heavy chain, and light chain have little or no correcting activity upon Fitzgerald-trait plasma aPTr. Fragment 1-2 light chain has the same correcting activity as intact bHMWK, while that of lys-bradykinin-free HMWK appears to be higher. Both fragment 1-2 and fragment 2 inhibit the clotting time of normal human plasma. When compared on a molar basis, fragment 2 is a more active inhibitor than fragment 1-2. When the effects of bovine plasma kallikrein upon bHMWK and hHMWK were studied, it was found that it released kinins from both kininogens. However, while the correcting activity of bHMWK was completely destroyed after 60 min of incubation, that of hHMWK was fully retained. These data suggest that: (a) the active part of bHMWK is comprised of the fragment 1-2 light chain portion; (b) fragment 1-2 or fragment 2 is the binding site to negatively charged surfaces, while the light chain interacts with other components of the surface-mediated reactions; and (c) bovine plasma kallikrein releases kinins, but probably does not cause the release of fragment 1-2 from human HMWK.

Inhibitory spectrum of alpha 2-plasmin inhibitor

alpha 2-Plasmin inhibitor (alpha 2PI) has been recently characterized as a fast-reacting inhibitor of plasmin in human plasma and appears to play an important role in the regulation of fibrinolysis in vivo. We have studied the effect of purified alpha 2PI upon various proteases participating in human blood coagulation and kinin generation. At physiological concentration (50 microgram/ml), alpha 2PI inhibited the clot-promoting and prekallikrein-activating activity of Hageman factor fragments, the amidolytic, kininogenase, and clot-promoting activities of plasma kallikrein, and the clot-promoting properties of activated plasma thromboplastin antecedent (PTA, Factor XIa) and thrombin. alpha 2PI had minimal inhibitory effect on surface-bound activated PTA and activated Stuart factor (Factor Xa). alpha 2PI did not inhibit the activity of activated Christmas factor (Factor IXa) or urinary kallikrein. Heparin (1.5-2.0 units/ml) did not enhance the inhibitory function of alpha 2PI. These results suggest that, like other plasma protease inhibitors, alpha 2PI possesses a broad in vitro spectrum of inhibitory properties.

Amidolytic properties of single-chain activated Hageman factor

Activation of Hageman factor (Factor XII) upon exposure to negatively charged agents has been attributed to proteolytic cleavage of this molecule. To examine this question, purified Hageman factor was exposed to Sephadex gels to which ellagic acid had been adsorbed. Such Hageman factor, separated from the gels and studied in the fluid phase, was amidolytic. Nonetheless, no cleavage of Hageman factor treated in this way could be demonstrated by sodium dodecyl sulfate/polyacrylamide gel electrophoresis. Thus, activation of Hageman factor by negatively charged agents was not necessarily accompanied by molecular scission.

Interactions among Hageman factor, plasma prekallikrein, high molecular weight kininogen, and plasma thromboplastin antecedent

To investigate the earliest steps of the intrinsic clotting pathway, Hageman factor (Factor XII) was exposed to Sephadex gels to which ellagic acid had been adsorbed; Hageman factor was then separated from the gels and studied in the fluid phase. Sephadex-ellagic acid-exposed Hageman factor, whether purified or in plasma, activated plasma thromboplastin antecedent, but only when high molecular weight kininogen was presnet. In the absence of plasma prekallikrein, maximal activation of plasma thromboplastin antecedent was slightly delayed in plasma, a delay not observed with similarly treated purified Hageman factor. Thus, high molecular weight kininogen was needed for expression of Hageman factor's clot-promoting properties and plasma prekallikrein played a minor role in the interaction of ellagic acid-treated Hageman factor and plasma thromboplastin antecedent.