Binding of coagulation factor XI to washed human platelets

The binding of human coagulation factor XI to washed human platelets was studied in the presence of zinc ions, calcium ions, and high molecular weight kininogen. Significant factor XI binding occurred at physiological levels of these metal ions when high molecular weight kininogen was present. Binding required platelet stimulation and was specific, reversible, and saturable. Scatchard analysis of the binding yielded approximately 1500 binding sites per platelet with an apparent dissociation constant of approximately 10 nM. Since the concentration of factor XI in plasma is about 25 nM, this suggests that in plasma factor XI binding sites on stimulated platelets might be saturated. Calcium ions and high molecular weight kininogen acted synergistically to enhance the ability of low concentrations of zinc ions to promote factor XI binding. The similarity between the concentrations of metal ions optimal for factor XI binding and those optimal for high molecular weight kininogen binding, as well as the ability of high molecular weight kininogen to modulate these metal ion effects, implies that factor XI and high molecular weight kininogen may form a complex on the platelet surface as they do in solution and on artificial negatively charged surfaces.     

Factor XI binding to the platelet glycoprotein Ib-IX-V complex promotes factor XI activation by thrombin.

Factor XI binds to high affinity sites on the surface of stimulated platelets where it is efficiently activated by thrombin. Here, we provide evidence that the factor XI binding site on platelets is in the glycoprotein (GP) Ibalpha subunit of the GP Ib-IX-V complex as follows. 1) Bernard-Soulier platelets, lacking the complex, are deficient in factor XI binding; 2) two GP Ibalpha ligands, SZ-2 (a monoclonal antibody) and bovine von Willebrand factor, inhibit factor XI binding to platelets; 3) by surface plasmon resonance, factor XI bound specifically to glycocalicin (the extracellular domain of GP Ibalpha) in Zn(2+)-dependent fashion (K(d)( app) approximately 52 nm). We then investigated whether glycocalicin could promote factor XI activation by thrombin, another GP Ibalpha ligand. In the presence of high molecular weight kininogen (45 nm), Zn(2+) and Ca(2+) ions, thrombin activated factor XI in the presence of glycocalicin at rates comparable with those seen in the presence of dextran sulfate (1 microg/ml). With higher high molecular weight kininogen concentrations (360 nm), the rate of thrombin-catalyzed factor XI activation in the presence of glycocalicin was comparable with that on activated platelets. Thus, factor XI binds to the GP Ib-IX-V complex, promoting its activation by thrombin.     

Low molecular weight kininogen binds to platelets to modulate thrombin-induced platelet activation

The kininogens, high molecular weight kininogen (HK) and low molecular weight kininogen (LK), are multifunctional, single-gene products that contain bradykinin and identical amino-terminal heavy chains. Studies were performed to determine if LK would bind directly to platelets. 125I-LK specifically bound to gel-filtered platelets in the presence of 50 microM Zn2+. HK effectively competed with 125I-LK for the same binding site (Ki = 27 +/- 9 nM, n = 5). Similarly, the Ki for LK inhibition of 125I-LK binding was 12 +/- 1 nM (n = 3). Albumin, fibrinogen, factor XIII, and kallikrein did not inhibit 125I-LK binding to unstimulated platelets. 125I-LK (66 kDa) was not cleaved upon binding to platelets. The binding of 125I-LK to unstimulated platelets was found to be fully reversible by the addition of a 50 molar excess of unlabeled LK at both 10 and 20 min. LK binding to platelets was saturable with an apparent Kd of 27 +/- 2 nM (mean +/- S.E., n = 9) and 647 +/- 147 binding sites/platelet. Both LK and HK at plasma concentrations inhibited thrombin-induced platelet aggregation. LK and HK at about 5% of plasma concentration also inhibited thrombin-induced secretion of both stirred and unstirred platelets. Both kininogens were found to be noncompetitive inhibitors of proteolytically active thrombin binding to platelets. The kininogens did not inhibit D-phenylalanyl-prolyl-arginine chloromethyl ketone-treated thrombin from binding to platelets. These studies indicated that both kininogens have a region on their heavy chain which allows them to bind to platelets. Further, kininogen binding by its heavy chain modulates thrombin activation of platelets since it prevents proteolytically active thrombin from binding to its receptor.     

Activation of the kinin-forming cascade on the surface of endothelial cells

Activation of the plasma kallikrein-kinin forming cascade takes place upon incubation with human umbilical vein endothelial cells. The mechanism by which initiation occurs is uncertain. Zinc-dependent binding of plasma proteins to gC1qR, cytokeratin 1, and perhaps u-PAR is requisite for activation to take place. We demonstrate here that during a 2 hour incubation time plasma deficient in either factor XII or high molecular weight kininogen (HK) fails to activate, as compared to normal plasma, but with more prolonged incubation, factor XII-deficient plasma gradually activates while HK-deficient plasma does not. Our data support both factor XII-dependent (rapid) and factor XII-independent (slow) mechanisms; the latter may require a cell-derived protease to activate prekallikrein and the presence of zinc ions and HK.     

Zinc ions promote the binding of factor XII/factor XIIA to acidic phospholipids but have no effect on the binding of high-Mr kininogen

Binding of high-Mr kininogen and factor XII/factor XIIa to phospholipids coated on to polystyrene microtiter plates was investigated by ELISA. Both high-Mr kininogen and factor XII/factor XIIa bound specifically to the phospholipid surface. Binding was observed to negatively charged phospholipids only. The binding of high-Mr kininogen was not affected by the presence of zinc ions. At a surface concentration of 20% phosphatidylinositol phosphate in phosphatidylcholine a dissociation constant (kD) of 10 nM for the binding of high-Mr kininogen was calculated. The amount of bound purified alpha-factor XIIa could be increased 4-5-fold in the presence of zinc ions. The lowest zinc ion concentration giving maximal binding was 0.1 mM. The binding of alpha-factor XIIa was inhibited by high-Mr kininogen. Independent of the presence of zinc ions or high-Mr kininogen, a kD of 7.9 nM was calculated for alpha-factor XIIa binding. The binding of prekallikrein was dependent upon the presence and the concentration of high-Mr kininogen. In plasma containing aprotinin, the binding of high-Mr kininogen was apparently inhibited in the presence of zinc ions, which was a prerequisite for the binding of factor XII. This apparently inhibitory effect of zinc ions on the binding of high-Mr kininogen was probably due to the increased binding of factor XII, which displaced high-Mr kininogen.     

Canine Plasma Kininogen: Evidence for the Presence of Two Kininogens and Purification of High Molecular Weight Kininogen and Characterization as Multi-Functional Molecule

The ratio of kininogen that is substrate of plasma kallikrein to kininogen, which is not substrate of plasma kallikrein in canine plasma, was about 1:3.6 by differential assay of kininogens. When the plasma was gel-filtered through a column of Sephacryl S-300 superfine, two fractions, which released kinin by trypsin, were obtained. These results indicate that two kininogens with different molecular weights are present in the plasma and they show different susceptibility to plasma kallikrein. One kininogen was purified by ion-exchange and zinc-chelating affinity chromatographies. Purified kininogen showed a single band in sodium dodecyl sulfate-polyacrylamide gel electrophoresis under reducing condition and its molecular weight was 125 kDa. Released kinin from the kininogen by trypsin was bradykinin. The kininogen inhibited papain and ficin but did not inhibit bromelain at the concentration used. The kininogen bound to carboxymethylated-papain and this binding was dissociated by 3M NaSCN. Canine plasma shortened the abnormal clotting time of human high molecular weight kininogen-deficint plasma. The kininogen also shortened the abnormal clotting time of the plasma. From these results, the purified kininogen was high molecular weight kininogen and it was multi-functional protein.     

Activated platelets but not endothelial cells participate in the initiation of the consolidation phase of blood coagulation

To address the question of whether initiation of the consolidation phase of coagulation occurs on platelets or on endothelium, we have examined the interaction of coagulation factor XI with human umbilical vein endothelial cells (HUVEC) and with platelets. In microtiter wells factor XI binds to more sites in the absence of HUVEC (1.8 x 10(10) sites/well, K(D) = 2.6 nm) than in their presence (1.3 x 10(10) sites/well, K(D) = 12 nm) when high molecular weight kininogen (HK) and zinc are present. Binding was volume-dependent and abrogated by HUVEC or Chinese hamster ovary cells and was a function of nonspecific binding of HK to the artificial plastic surface. Factor XI did not bind to HUVEC or to HEK293 cell monolayers anchored to microcarrier beads. Activation of HUVEC resulted in von Willebrand's factor secretion, but factor XI binding was not observed. Only activated platelets supported factor XI binding in the presence of HK and zinc (K(D) = 8 nm, B(max) = 1319 sites/cell). Activation of factor XI was observed in plasma in the presence of platelets activated by the thrombin receptor activation peptide but not with activated HUVEC. These results support the concept that activated platelets, but not endothelial cells, expose a procoagulant surface for binding and activating factor XI, thereby initiating the consolidation phase of coagulation.     

The role of high molecular weight kininogen and prothrombin as cofactors in the binding of factor XI A3 domain to the platelet surface

We have reported that prothrombin (1 microm) is able to replace high molecular weight kininogen (45 nm) as a cofactor for the specific binding of factor XI to the platelet (Baglia, F. A., and Walsh, P. N. (1998) Biochemistry 37, 2271-2281). We have also determined that prothrombin fragment 2 binds to the Apple 1 domain of factor XI at or near the site where high molecular weight kininogen binds. A region of 31 amino acids derived from high molecular weight kininogen (HK31-mer) can also bind to factor XI (Tait, J. F., and Fujikawa, K. (1987) J. Biol. Chem. 262, 11651-11656). We therefore investigated the role of prothrombin fragment 2 and HK31-mer as cofactors in the binding of factor XI to activated platelets. Our experiments demonstrated that prothrombin fragment 2 (1 microm) or the HK31-mer (8 microm) are able to replace high molecular weight kininogen (45 nm) or prothrombin (1 microm) as cofactors for the binding of factor XI to the platelet. To localize the platelet binding site on factor XI, we used mutant full-length recombinant factor XI molecules in which the platelet binding site in the Apple 3 domain was altered by alanine scanning mutagenesis. The recombinant factor XI with alanine substitutions at positions Ser(248), Arg(250), Lys(255), Leu(257), Phe(260), or Gln(263) were defective in their ability to bind to activated platelets. Thus, the interaction of factor XI with platelets is mediated by the amino acid residues Ser(248), Arg(250), Lys(255), Leu(257), Phe(260), and Gln(263) within the Apple 3 domain.     

Effects of chemical modifications on the surface- and protein-binding properties of the light chain of human high molecular weight kininogen

The light chain of kallikrein-cleaved human high molecular weight kininogen is solely responsible for its cofactor activity in blood clotting. Sequencing of the NH2-terminal region of the light chain reported herein identified the third kallikrein cleavage site of high molecular weight kininogen as Arg-437. The co-factor activity of high molecular weight kininogen consists of the capacity to bind to negatively charged surfaces and to factor XI or prekallikrein. Chemical modification of the histidines by either photooxidation or ethoxyformic anhydride affected the equivalent of 14-16 of 23 histidines available and resulted in over 90% loss in procoagulant activity. The modified protein had drastically reduced surface- and zinc-binding capacity, but it bound successfully to either factor XI or prekallikrein. In contrast, modification of two carboxyl groups, which led to approximately 80-90% loss of procoagulant activity, seriously compromised protein binding but left surface binding unaffected. All 3 tryptophans were modified at pH 4.0 with N-bromosuccinimide with a 70% reduction in procoagulant activity, but only 1 tryptophan was available for reaction at pH 7.35, resulting in a 50% loss in activity. Tryptophan modification at acidic pH affected protein binding but did not modify surface or zinc binding. Modification of both available tyrosine and 9 of 18 available lysine residues did not have a significant effect on the procoagulant activity of the light chain. These studies indicate that histidines participate in surface binding and that free carboxyl groups and tryptophan side chains are involved in binding of high molecular weight kininogen to other clotting factors.     

Identification and characterization of plasma kallikrein-kinin system inhibitors from salivary glands of the blood-sucking insect Triatoma infestans

Two plasma kallikrein-kinin system inhibitors in the salivary glands of the kissing bug Triatoma infestans, designated triafestin-1 and triafestin-2, have been identified and characterized. Reconstitution experiments showed that triafestin-1 and triafestin-2 inhibit the activation of the kallikrein-kinin system by inhibiting the reciprocal activation of factor XII and prekallikrein, and subsequent release of bradykinin. Binding analyses showed that triafestin-1 and triafestin-2 specifically interact with factor XII and high molecular weight kininogen in a Zn2+-dependent manner, suggesting that they specifically recognize Zn2+-induced conformational changes in factor XII and high molecular weight kininogen. Triafestin-1 and triafestin-2 also inhibit factor XII and high molecular weight kininogen binding to negatively charged surfaces. Furthermore, they interact with both the N-terminus of factor XII and domain D5 of high molecular weight kininogen, which are the binding domains for biological activating surfaces. These results suggest that triafestin-1 and triafestin-2 inhibit activation of the kallikrein-kinin system by interfering with the association of factor XII and high molecular weight kininogen with biological activating surfaces, resulting in the inhibition of bradykinin release in an animal host during insect blood-feeding.     

Determination of the bifunctional properties of high molecular weight kininogen by studies with monoclonal antibodies directed to each of its chains

In normal human plasma two forms of kininogen exist, low molecular weight kininogen (LMWK) and high molecular weight kininogen (HMWK). When these proteins are cleaved they are found to have a common heavy chain and bradykinin, but each has a unique light chain. Monoclonal antibodies to the heavy and light chains of HMWK have been developed, and the effects of each on the function of this protein are defined. Initial studies showed that an antibody, C11C1, completely neutralized the coagulant activity of plasma HMWK whereas another antibody, 2B5, did not. On a competitive enzyme-linked immunosorbent assay (CELISA) the C11C1 antibody was consumed by kininogen antigen in normal plasma but not by kininogen antigen in HMWK-deficient plasma. On immunoblot, the C11C1 antibody recognized one kininogen protein in normal plasma and did not recognize any kininogen antigen in HMWK-deficient plasma. These combined studies indicated that the C11C1 antibody was directed to an epitope on the unique 46-kDa light chain of HMWK. In contrast, the 2B5 antibody on a CELISA was consumed by kininogen antigen in both normal plasma and HMWK-deficient plasma but not by total kininogen-deficient plasma. On immunoblot, the 2B5 antibody recognized both kininogens in normal plasma but only LMWK in HMWK-deficient plasma. These combined studies indicated that the 2B5 antibody was directed to the common 64-kDa heavy chain of the plasma kininogens. Utilizing direct binding studies or competition kinetic experiments, the 2B5 and C11C1 antibodies bound with high affinity (1.71 and 0.77 nM, respectively) to their antigenic determinants on the HMWK molecule. The 2B5 antibody did neutralize the ability of HMWK to inhibit platelet calpain. These studies with monoclonal antibodies directed to each of the HMWK chains indicate that HMWK is a bifunctional molecule that can serve as a cofactor for serine zymogen activation and an inhibitor of cysteine proteases.     

Binding and activation of plasminogen on the platelet surface

A mechanism by which platelets might participate in fibrinolysis by binding plasminogen and influencing its activation has been examined. Binding of radioiodinated human Glu-plasminogen to washed human platelets was time-dependent and was enhanced 3-9-fold by stimulation of platelets with thrombin but not with ADP. The interaction with both stimulated and unstimulated cells was specific, saturable, divalent ion-independent, and reversible. The platelet-bound ligand had the molecular weight of plasminogen, and no conversion to plasmin was detected. Scatchard analyses provided evidence for a single class of plasminogen-binding sites on both stimulated and unstimulated cells. The Kd for thrombin-stimulated platelets was 2.6 +/- 1.3 microM, and 190,000 +/- 45,000 molecules were bound per cell, whereas unstimulated platelets bound 37,000 +/- 10,500 molecules/cell with a Kd of 1.9 +/- 0.15 microM. Plasminogen binding was inhibited in a dose-dependent manner by omega-aminocarboxylic acids at concentrations consistent with a requirement for an unoccupied high affinity lysine-binding site for plasminogen binding to the cells. When platelet-bound plasminogen was incubated with tissue plasminogen activator, urokinase, or streptokinase, gel analysis established that plasmin was preferentially associated with the platelet relative to the supernatant. Plasminogen and plasmin interacted with thrombin-stimulated platelets with similar binding characteristics, and there was no evidence for a binding site for plasmin which did not also bind plasminogen. Therefore, the results suggest that plasminogen activation is enhanced on the cell surface. In sum, these results indicate that platelets bind plasminogen at physiologic zymogen concentrations and this interaction may serve to localize and promote plasminogen activation.     

Identification of the binding site for plasma prekallikrein in human high molecular weight kininogen. A region from residues 185 to 224 of the kininogen light chain retains full binding activity

We studied the ability of fragments of the light chain of human high molecular weight kininogen to bind to plasma prekallikrein. In a competitive fluorescence polarization assay, kallikrein-cleaved light chain (light chain-2; residues 49-255), a cyanogen bromide fragment (residues 185-242), and a tryptic peptide (T-7; residues 185-224) had binding affinities of approximately 20 nM, equivalent to the value for the intact light chain (residues 1-255) of high-molecular-weight kininogen. In contrast, fragments consisting of residues 49-184 and 243-255 showed no binding activity (Kd much greater than 1,000 nM). Direct titrations of fluorescein-labeled derivatives of light chain-2 and peptide T-7 with prekallikrein confirmed that T-7 retained full binding activity for prekallikrein (Kd = 12 +/- 2 nM for labeled light chain-2; Kd = 7 +/- 1 nM for labeled T-7). These results localize the binding site of high molecular weight kininogen for prekallikrein within a region of 40 amino acids (residues 185-224) that resides in the near carboxyl terminus of the light chain of kininogen.     

Identification of a binding site for glycoprotein Ibalpha in the Apple 3 domain of factor XI

Factor XI (FXI) is a homodimeric plasma zymogen that is cleaved at two internal Arg(369)-Ile(370) bonds by thrombin, factor XIIa, or factor XIa. FXI circulates as a complex with the glycoprotein high molecular weight kininogen (HK). FXI binds to specific sites (K(d) = approximately 10 nM, B(max) = approximately 1,500/platelet) on the surface of stimulated platelets, where it is efficiently activated by thrombin. The FXI Apple 3 (A3) domain mediates binding to platelets in the presence of HK and zinc ions (Zn(2+)) or prothrombin and calcium ions. The platelet glycoprotein (GP) Ib-IX-V complex is the receptor for FXI. Using surface plasmon resonance, we determined that FXI binds specifically to glycocalicin, the extracellular domain of GPIbalpha, in a Zn(2+)-dependent fashion (K(d) = approximately 52 nM). We now show that recombinant FXI A3 domain inhibits FXI inbinding to glycocalicin in the presence of Zn(2+), whereas the recombinant FXI A1, A2, or A4 domains have no effect. Experiments with full-length recombinant FXI mutants show that, in the presence of Zn(2+), glycocalicin binds FXI at a heparin-binding site in A3 (Lys(252) and Lys(253)) and not by amino acids previously shown to be required for platelet binding (Ser(248), Arg(250), Lys(255), Phe(260), and Gln(263)). However, binding in the presence of HK and Zn(2+) requires Ser(248), Arg(250), Lys(255), Phe(260), and GLn(263) and not Lys(252) and Lys(253). Thus, binding of FXI to GPIbalpha is mediated by amino acids in the A3 domain in the presence or absence of HK. This interaction is important for the initiation of the consolidation phase of blood coagulation and the generation of thrombin at sites of platelet thrombus formation.     

Studies on human high molecular weight (HMW) kininogen. II. Structural change of HMW kininogen by the action of human plasma kallikrein

We have investigated in detail the cleavage of human high molecular weight (HMW) kininogen by human plasma kallikrein and revealed the formation of a nicked kininogen and a novel kinin-free protein (KFP) as intermediate cleavage products. The cleavage of a single chain HMW kininogen (Mr=120,000) by plasma kallikrein was a three-step reaction. The first cleavage yielded a nicked kininogen composed of two disulfide-linked 62,000 and 56,000 daltons chains. The second cleavage yielded kinin and an intermediate kinin-free protein, KFP-I, which was apparently of equal size to the nicked kininogen. The third cleavage yielded a stable kinin-free protein, KFP-II, composed of two disulfide-linked 62,000 and 45,000 daltons chains. The liberation of an 8,000 daltons fragment was identified when the 56,000 daltons chain isolated by SP-Sephadex C-50 chromatography of reduced and alkylated KFP-I was cleaved by plasma kallikrein into the 45,000 daltons chain. Although the antiserum against HMW kininogen cross-reacted with low molecular weight (LMW) kininogen, the antiserum against the 45,000 daltons chain was specific for HMW kininogen. These results suggest that the antigenic determinant groups common to HMW and LMW kininogens are located in the 62,000 daltons heavy chain, while those specific for HMW kininogen are located in the 45,000 daltons light chain, which is known to retain blood coagulation activity.     

Inhibition of cell adhesion by high molecular weight kininogen

An anti-cell adhesion globulin was purified from human plasma by heparin-affinity chromatography. The purified globulin inhibited spreading of osteosarcoma and melanoma cells on vitronectin, and of endothelial cells, platelets, and mononuclear blood cells on vitronectin or fibrinogen. It did not inhibit cell spreading on fibronectin. The protein had the strongest antiadhesive effect when preadsorbed onto the otherwise adhesive surfaces. Amino acid sequence analysis revealed that the globulin is cleaved (kinin-free) high molecular weight kininogen (HKa). Globulin fractions from normal plasma immunodepleted of high molecular weight kininogen (HK) or from an individual deficient of HK lacked adhesive activity. Uncleaved single-chain HK preadsorbed at neutral pH, HKa preadsorbed at pH greater than 8.0, and HKa degraded further to release its histidine-rich domain had little anti-adhesive activity. These results indicate that the cationic histidine-rich domain is critical for anti-adhesive activity and is somehow mobilized upon cleavage. Vitronectin was not displaced from the surface by HKa. Thus, cleavage of HK by kallikrein results in both release of bradykinin, a potent vasoactive and growth-promoting peptide, and formation of a potent anti-adhesive protein.     

Interaction of thrombospondin with resting and stimulated human platelets

The interaction of isolated and radioiodinated thrombospondin with washed human platelets has been characterized. The ligand bound to nonstimulated and thrombin-stimulated platelets in a time-dependent manner, and apparent steady state was reached within 25 min. Binding was not due to iodination of the ligand and was inhibited by nonlabeled thrombospondin but not by unrelated proteins, and bound ligand was identical with thrombospondin in terms of subunit structure. Nonlinear curve-fitting analyses of binding to resting platelets suggested the presence of a single class of sites which bound 3,100 +/- 1,000 molecules/platelet with an apparent Kd of 50 +/- 20 nM. This interaction was not attributable to contaminating cells or inadvertant platelet activation. Binding to thrombin-stimulated platelets had a lower apparent affinity (Kd = 250 +/- 100 nM) and higher apparent capacity (35,600 +/- 9,600 molecules/platelet). Thrombin-enhanced binding was dependent upon agonist dose and platelet stimulation. Fibrinogen, a monoclonal antibody to GPIIb-IIIa, temperature, and divalent ions had differential effects upon thrombospondin binding to resting and stimulated platelets, suggesting the presence of two distinct mechanisms of thrombospondin binding to platelets. While thrombospondin binding to thrombin-stimulated platelets occurs with characteristics similar to those observed for fibrinogen, fibronectin, and von Willebrand Factor, its high affinity interaction with resting platelets is unique to this adhesive glycoprotein.     

Hypothesis. The molecular 'double-pivot' mechanism for water oxidation

High-molecular-weight (HMW) kininogen was purified from guinea-pig plasma by measuring its ability to correct the prolonged clotting time in human HMW kininogen deficient plasma (Fitzgerald trait). The purified HMW kininogen demonstrated a homogeneous band in disc gel electrophoresis in the presence of sodium dodecyl sulfate under reducing or non-reducing conditions with an apparent molecular weight of 100,000. Kinin released from HMW kininogen by treatment with guinea-pig plasma kallikrein was identified as bradykinin by reverse-phase HPLC and amino-acid analysis. The capacity of HMW kininogen as a thiol-proteinase inhibitor was realized by its dose-dependent inhibitory activity to papain. The Ki value for papain was estimated to be 42 pM. The kinin-free HMW kininogen maintained the inhibitor and clotting-factor activities with similar capacities to those of the HMW kininogen molecule. Heavy chain (H-chain) and light chain (L-chain) of HMW kininogen were prepared from reduced and alkylated kinin-free HMW kininogen by HPLC. The S-alkylated H-chain, but not L-chain, demonstrated the inhibitor activity with the Ki value 6.9 nM for papain, whereas the S-alkylated L-chain, but not H-chain, maintained the clotting activity one-third of the capacity of HMW kininogen. Specific antibodies recognized HMW kininogen, but also a probable low-molecular-weight kininogen(s) with an apparent molecular weight of 60,000 in the guinea-pig plasma. All of these properties are consistent with the reports on human, bovine and rat HMW kininogen.     

Interaction of human plasma kallikrein and its light chain with alpha 2-macroglobulin

Human plasma kallikrein participates in the contact activation system of plasma. The light chain of kallikrein contains the enzymatic active site; the heavy chain is required for binding to high molecular weight kininogen and for surface-dependent activation of coagulation. This study has examined the functional contributions of the heavy chain of kallikrein and of high molecular weight kininogen in the inactivation of kallikrein and of its isolated light chain by alpha 2-macroglobulin (alpha 2M). Irreversible inhibition was observed for both kallikrein and its light chain, with the initial formation of a reversible enzyme-inhibitor complex. The second-order rate constants for these reactions were 3.5 X 10(5) and 4.8 X 10(5) M-1 min-1 for kallikrein and its light chain, respectively. When present in excess, high molecular weight kininogen decreased the rate of kallikrein inactivation by alpha 2M, whereas the rate of inactivation of the light chain was unaffected by high molecular weight kininogen. Although at a drastically reduced rate, high molecular weight kininogen was cleaved by alpha 2M-bound kallikrein. Sodium dodecyl sulfate gradient polyacrylamide gel electrophoresis was used to study complex formation between alpha 2M and kallikrein or its light chain. Under reducing conditions, four kallikrein-alpha 2M complexes were observed. Three of these complexes consisted of alpha 2M and the light chain of kallikrein (Mr 123 000, 235 000, and 330 000). Two alpha 2M-kallikrein light chain complexes incorporated [3H]diisopropyl fluorophosphate ( [3H]DFP) whereas the Mr 330 000 complex did not react with [3H]DFP.(ABSTRACT TRUNCATED AT 250 WORDS)