Characterization of the H-kininogen-binding site on factor XI: a comparison of factor XI and plasma prekallikrein.

Factor XI (FXI), the zymogen of the blood coagulation protease FXIa, and the structurally homologous protein plasma prekallikrein circulate in plasma in noncovalent complexes with H-kininogen (HK). HK binds to the heavy chains of FXI and of prekallikrein. Each chain contains four apple domains (F1-F4 for FXI and P1-P4 for prekallikrein). Previous studies indicated that the HK-binding site on FXI is located in F1, whereas the major HK-binding site on prekallikrein is in P2. To determine the contribution of each FXI apple domain to HK-FXI complex formation, we examined binding of recombinant single apple domain-tissue plasminogen activator fusion proteins to HK. The order of affinity from highest to lowest is F2 F4 > F1 F3. Monoclonal antibodies against F2 are superior to F4 or F1 antibodies as inhibitors of HK binding to FXI. Antibody alphaP2, raised against prekallikrein, cross-reacts with FXI F2 and inhibits FXI-HK binding with an IC(50) of 8 nm. HK binding to a platelet-specific FXI variant lacking the N-terminal half of F2 is reduced > 5-fold compared with full-length FXI. A chimeric FXI molecule in which F2 is replaced by P2 is cleaved within P2 during activation by factor XIIa, resulting in greatly reduced HK binding capacity. In contrast, wild-type FXI is not cleaved within F2, and its binding capacity for HK is unaffected by factor XIIa. Our data show that HK binding to FXI involves multiple apple domains, with F2 being most important. The findings demonstrate a similarity in mechanism for FXI and prekallikrein binding to HK.     

High molecular weight kininogen-binding site of prekallikrein probed by monoclonal antibodies.

A panel of monoclonal antibodies against human prekallikrein was raised in mice and characterized with respect to the major antigenic epitopes. Of 18 antibodies, nine were directed against the light chain portion performing the proteolytic function of activated kallikrein, and nine recognized the heavy chain mediating the binding of prekallikrein to high molecular weight (H-)kininogen. Among the anti-heavy chain antibodies, one (PK6) interfered with the procoagulant activity of prekallikrein, and prolonged in a concentration-dependent manner the activated partial thromboplastin time of reconstituted prekallikrein-deficient plasma (Fletcher type). Antibody PK6 was subtyped IgG1,k and had an apparent Kass of 6.8 +/- 0.44.10(8) M-1 for prekallikrein. Functional analyses revealed that PK6 does not interfere with prekallikrein activation by activated Hageman factor (beta-F XIIa), and has no effect on the kininogenase function of activated kallikrein. Monoclonal antibody PK6 but none of the other anti-heavy chain antibodies completely prevented complex formation of prekallikrein with H-kininogen, and readily dissociated preformed complexes of prekallikrein and H-kininogen. Likewise, Fab' and F(ab')2 fragments of PK6 blocked H-kininogen binding to prekallikrein. A synthetic peptide of 31 amino acid residues encompassing the entire prekallikrein binding region of H-kininogen effectively competed with PK6 for prekallikrein binding indicating that the target epitope of PK6 is juxtaposed to, if not incorporated in the H-kininogen-binding site of prekallikrein. Extensive cross-reactivity of PK6 with another H-kininogen-binding protein of human plasma, i.e. factor XI, suggested that the structure of the target epitope of PK6 is well conserved among prekallikrein and factor XI, as would be expected for the kininogen-binding site shared by the two proteins. It is anticipated that monoclonal antibody PK6 will be an important tool for the precise mapping of the hitherto unknown kininogen-binding site of prekallikrein.     

Mapping of the prekallikrein-binding site of human H-kininogen by ligand screening of lambda gt11 expression libraries. Mimicking of the predicted binding site by anti-idiotypic antibodies.

High molecular weight (H-)kininogen, a non-enzymatic cofactor of the contact activation system, has on the COOH-terminal part of its light chain a unique binding site which complexes prekallikrein or factor XI with high affinity and specificity. In a conventional protein fragmentation approach, the prekallikrein-binding site was mapped to positions 556-595 of the human H-kininogen sequence (Tait, J. F., and Fujikawa, K. (1986) J. Biol. Chem. 261, 15396-15401). To gain more insight into the minimum structural requirements of the prekallikrein-binding site, we have developed an alternative strategy employing the lambda gt11 expression cloning system. A ligand assay was established which probes for the binding site in H-kininogen or recombinant fusion proteins thereof by complexation with prekallikrein, followed by a specific antibody against prekallikrein and a secondary labeled antibody. A cDNA library constructed in lambda gt11 from random fragments of a cDNA clone encoding the COOH-terminal part of the kininogen light chain was screened by the ligand assay, and 17 positive clones were identified. Analysis of their inserted cDNA sequences revealed a consensus sequence of 119 nucleotides which maps to the extreme 3' end (positions 1759-1877) of the coding part of the prekininogen mRNA. The consensus sequence encodes positions 569-607 of the kininogen light chain and overlaps by 27 residues (positions 569-595) with the binding segment identified previously by the fragment approach. Analysis of successively shortened peptides revealed that the common segment of 27 residues but not truncated versions thereof contains the essential structural elements for prekallikrein binding. This conclusion was corroborated by the finding that anti-idiotypic antibodies toward a monoclonal antibody directed to the binding segment of 27 residues bear internal image(s) of the binding site of H-kininogen. It is pointed out that the methodology described in this study may prove generally useful in the cloning and mapping of high affinity binding sites of proteins.     

Immunological characterization of rat kininogens with monoclonal antibodies to T-kininogen. Distinction between the different domains of T-kininogen and the multiple rat kininogens.

A panel of 16 monoclonal antibodies (mAb) were produced against rat T-kininogen to characterize this family of proteins. These mAbs bound 125I-T-kininogen by radioimmunoassay as well as reacting strongly with immobilized T-kininogen in an enzyme-linked immunosorbent assay (ELISA). The reactivity of these antibodies with proteolytic fragments of T-kininogen demonstrated the recognition of several different epitopes. One antibody was specific for the domain 1 of the heavy chain and/or the light chain, twelve antibodies were specific for domain 2 and three antibodies were specific for domain 3. All monoclonal antibodies recognized the two forms of T-kininogen encoded by the two different T-kininogen genes, TI and TII kininogen, except antibody TK 16-3.1 which uniquely reacted with TII kininogen. Two antibodies recognizing domain 2 cross-reacted with the high-molecular-mass kininogen (H-kininogen), whereas all the other monoclonal antibodies were specific to T-kininogen and did not recognize the heavy chain of H-kininogen. None of the antibodies tested altered the thiol protease inhibitory activity of T-kininogen, its partial proteolysis by rat mast cell chymase or the hydrolysis of H-kininogen by rat urinary kallikrein. The use of these antibodies in the development of sensitive ELISA to measure T-kininogen levels in plasma, urine, liver microsomes and hepatocytes is described. Two different forms of T-kininogen were distinguished by these monoclonal antibodies in Western blotting using rat plasma. The localization of T-kininogen was defined using these monoclonal antibodies by immunohistochemistry in rat liver hepatocytes and rat kidney.     

Localization of the high molecular weight kininogen binding site in the heavy chain of human factor XI to amino acids phenylalanine 56 through serine 86

We have previously demonstrated that a monoclonal antibody (5F7) directed against the heavy chain region of factor XI inhibits the binding of factor XI to high molecular weight kininogen (high Mr kininogen) and the surface-mediated proteolytic activation of factor XI by factor XIIa in the presence of high Mr kininogen. In order to identify the structural domain of factor XI that binds high Mr kininogen, CNBr-digested factor XI was passed over a 5F7 antibody affinity column. One of two CNBr peptides that bound to this 5F7 affinity column inhibited binding of 125I-factor XI to high Mr kininogen, as did intact factor XI. Polyacrylamide gel electrophoresis in sodium dodecyl sulfate of an inhibitory peptide purified by high performance liquid chromatography revealed an Mr of 10,000-15,000. Gas-phase sequencing of this peptide revealed the following amino-terminal sequence: X-X-Val-Thr-Gln-Leu-Leu-Lys-Asp-Thr. These data together with the amino acid composition of the isolated peptide indicate that both the epitope recognized by antibody 5F7 and at least a portion of the high Mr kininogen binding site are contained within the amino-terminal portion of factor XI comprising residues Glu-1 through Met-102. Further cleavage of this peptide with o-iodosobenzoic acid at a tryptophanyl peptide bond revealed that an Mr 5,000 peptide (with the amino-terminal sequence Trp-Phe-Thr-Cys-Val-Leu) bound to a high Mr kininogen affinity column and inhibited binding of 125I-factor XI to high Mr kininogen. Finally, a synthetic peptide comprising residues Phe-56 through Ser-86 inhibited 125I-factor XI binding to high Mr kininogen. These experiments strongly suggest that the high Mr kininogen binding site is contained within the domain in the heavy chain region of factor XI comprising residues Phe-56 through Ser-86.     

Protein-protein interactions in contact activation of blood coagulation. Binding of high molecular weight kininogen and the 5-(iodoacetamido) fluorescein-labeled kininogen light chain to prekallikrein, kallikrein, and the separated kallikrein heavy and light chains

Binding of the 5-(iodoacetamido)fluorescein (IAF)-labeled high molecular weight (HMW) kininogen light chain to prekallikrein and D-Phe-Phe-Arg-CH2Cl-inactivated kallikrein was monitored by a 0.040 +/- 0.002 increase in fluorescence anisotropy. Indistinguishable average dissociation constants and stoichiometries of 14 +/- 3 nM and 1.1 +/- 0.1 mol of prekallikrein/mol of IAF-light chain and 17 +/- 3 nM and 0.9 +/- 0.1 mol of kallikrein/mol of IAF-light chain were determined for these interactions at pH 7.4, mu 0.14 and 22 degrees C. Prekallikrein which had been reduced and alkylated in 6 M guanidine HCl lost the ability to increase the fluorescence anisotropy of the IAF-kininogen light chain, suggesting that the native tertiary structure was required for tight binding. The kallikrein heavy and light chains were separated on the basis of the affinity of the heavy chain for HMW-kininogen-Sepharose, after mild reduction and alkylation of kallikrein under nondenaturing conditions. Under these conditions, alkylation with iodo [14C]acetamide demonstrated that only limited chemical modification had occurred. Binding of the IAF-kininogen light chain to the isolated alkylated kallikrein heavy chain, when compared to prekallikrein and kallikrein, was characterized by an indistinguishable increase in fluorescence anisotropy, average dissociation constant of 14 +/- 3 nM, and stoichiometry of 1.2 +/- 0.1 mol of kallikrein heavy chain/mol of IAF-light chain. In contrast, no binding of the D-Phe-Phe-Arg-CH2Cl-inactivated kallikrein light chain was detected at concentrations up to 500 nM. Furthermore, 300 nM kallikrein light chain did not affect IAF-kininogen light chain binding to prekallikrein, kallikrein, or the kallikrein heavy chain. The binding of monomeric single chain HMW-kininogen to prekallikrein, kallikrein, and the kallikrein heavy and light chains was studied using the IAF-kininogen light chain as a probe. Analysis of the competitive binding of HMW-kininogen gave average dissociation constants and stoichiometries of 12 +/- 2 nM and 1.2 +/- 0.1 mol of prekallikrein/mol of HMW-kininogen, 15 +/- 2 nM and 1.3 +/- 0.1 mol of kallikrein/mol of HMW-kininogen, 14 +/- 3 nM and 1.4 +/- 0.2 mol of kallikrein heavy chain/mol of HMW-kininogen, and no detectable effect of 300 nM kallikrein light chain on these interactions. We conclude that a specific, nonenzymatic interaction between sites located exclusively on the light chain of HMW-kininogen and the heavy chain of kallikrein or prekallikrein is responsible for the formation of 1:1 noncovalent complexes between these proteins.     

Mapping the interaction between high molecular mass kininogen and the urokinase plasminogen activator receptor

The urokinase plasminogen activator receptor (uPAR) is a multifunctional, GPI-linked receptor that modulates cell adhesion/migration and fibrinolysis. We mapped the interaction sites between soluble uPAR (suPAR) and high molecular mass kininogen (HK). Binding of biotin-HK to suPAR was inhibited by HK, 56HKa, and 46HKa with an IC50 of 60, 110, and 8 nm, respectively. We identified two suPAR-binding sites, a higher affinity site in the light chain of HK and 46HKa (His477-Gly496) and a lower affinity site within the heavy chain (Cys333-Lys345). HK predominantly bound to suPAR fragments containing domains 2 and 3 (S-D2D3). Binding of HK to domain 1 (S-D1) was also detected, and the addition of S-D1 to S-D2D3 completely inhibited biotin-HK or -46HKa binding to suPAR. Using sequential and overlapping 20-amino acid peptides prepared from suPAR, two regions for HK binding were identified. One on the carboxyl-terminal end of D2 (Leu166-Thr195) blocked HK binding to suPAR and to human umbilical vein endothelial cells (HUVEC). This site overlapped with the urokinase-binding region, and urokinase inhibited the binding of HK to suPAR. A second region on the amino-terminal portion of D3 (Gln215-Asn255) also blocked HK binding to HUVEC. Peptides that blocked HK binding to uPAR also inhibited prekallikrein activation on HUVEC. Therefore, HK interacts with suPAR at several sites. HK binds to uPAR as part of its interaction with its multiprotein receptor complex on HUVEC, and the biological functions that depend upon this binding are modulated by urokinase.     

Histidine-rich glycoprotein is evolutionarily related to the cystatin superfamily. Presence of two cystatin domains in the N-terminal region

A new member of the cystatin superfamily is introduced. Human plasma histidine-rich glycoprotein (HRG) was found to contain 2 cystatin-like sequences in tandem in the N-terminal region. Domain 1 (residues 1-112) was most homologous to domain 1 of the heavy chain of human kininogen and domain 2 (residues 113-225) was most homologous to human cystatin S as well as other cystatins and domain 3 of the heavy chain of kininogen, suggesting that the cystatin domains of HRG may represent a hitherto unknown binary form (or intermediate molecule) composed of 2 cystatin domains, and evolutionarily intermediate between the cystatin and the kininogen families.     

Human high molecular weight kininogen. Studies of structure-function relationships and of proteolysis of the molecule occurring during contact activation of plasma.

Human high Mr kininogen was purified from normal plasma in 35% yield. The purified high Mr kininogen appeared homogeneous on polyacrylamide gels in the presence of sodium dodecyl sulfate and mercaptoethanol and gave a single protein band with an apparent Mr = 110,000. Using sedimentation equilibrium techniques, the observed Mr was 108,000 +/- 2,000. Human plasma kallikrein cleaves high Mr kininogen to liberate kinin and give a kinin-free, two-chain, disulfide-linked molecule containing a heavy chain of apparent Mr = 65,000 and a light chain of apparent Mr = 44,000. The light chain is histidine-rich and exhibits a high affinity for negatively charged materials. The isolated alkylated light chain quantitatively retains the procoagulant activity of the single-chain parent molecule. 125I-Human high Mr kininogen undergoes cleavage in plasma during contact activation initiated by addition of kaolin. This cleavage, which liberates kinin and gives a two-chain, disulfide-linked molecule, is dependent upon the presence of prekallikrein and Factor XII (Hageman factor) in plasma. Addition of purified plasma kallikrein to normal plasma or to plasmas deficient in prekallikrein or Factor XII in the presence or absence of kaolin results in cleavage of high Mr kininogen and kinin formation.     

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.     

Localization of distinct functional domains on prekallikrein for interaction with both high molecular weight kininogen and activated factor XII in a 28-kDa fragment (amino acids 141-371).

The predominant autolytic form of human kallikrein, beta-kallikrein, was used to localize the high molecular weight kininogen (HK) binding site on kallikrein as well as the substrate recognition site for activated factor XII on prekallikrein. beta-Kallikrein is formed by autolysis of the kallikrein heavy chain to give two fragments of approximately 18 and 28 kDa by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. A ligand binding technique established that the HK binding site on kallikrein residues on the 28-kDa fragment of the heavy chain. Limited NH2-terminal sequencing of this portion of beta-kallikrein showed that this fragment of the heavy chain consists of the COOH-terminal 231 amino acids of the heavy chain. A panel of five murine monoclonal antibodies to human prekallikrein (PK) were found to have epitopes on this same fragment of the heavy chain. None of the monoclonal antibodies were able to block binding of HK to PK. Three of the monoclonal antibodies (13G11, 13H11, and 6A6) were able to inhibit the activation of PK to kallikrein in both a plasma system and a purified system. The 28-kDa fragment of the PK heavy chain was purified and was able to compete with HK for binding to PK. The HK binding site and the site of recognition of factor XII are separate and distinct on PK, and both are contained in the COOH-terminal 231 amino acids of the PK heavy chain.     

Protein-protein interactions in contact activation of blood coagulation. Characterization of fluorescein-labeled human high molecular weight kininogen-light chain as a probe

Limited proteolysis of high molecular weight kininogen by kallikrein resulted in the generation of an inactive heavy chain of Mr = 64,000 and active light chains of Mr = 64,000 and 51,000 when analyzed by sodium dodecyl sulfate (SDS)-gel electrophoresis under reducing conditions. Starting with kininogen from outdated plasma, a light chain with an apparent molecular weight of 51,000 on 7.5% SDS gels was purified and characterized. Molecular weights of 28,900 +/- 1,100 and 30,500 +/- 1,600 were obtained by gel filtration of the reduced and alkylated protein in 6 M guanidine HCl and equilibrium sedimentation under nondenaturing conditions in the air-driven ultracentrifuge, respectively. The light chain stained positively with periodic acid-Schiff reagent on SDS gels indicating that covalently attached carbohydrate may be responsible for the anomalously high molecular weight estimated by SDS-gel electrophoresis. A single light chain thiol group reacted with 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) in the presence and absence of 6 M guanidine HCl. Specific fluorescent labeling of the thiol group with 5-(iodoacetamido)fluorescein (IAF) occurred without loss of clotting activity. Addition of purified human plasma prekallikrein to the IAF-light chain resulted in a maximum increase in fluorescence anisotropy of 0.041 +/- 0.001 and no change in the fluorescence intensity. Fluorescence anisotropy measurements of the equilibrium binding of prekallikrein to the IAF-light chain yielded an average Kd of 17.3 +/- 2.5 nM and stoichiometry of 1.07 +/- 0.07 mol of prekallikrein/mol of IAF-light chain. Measurements of the interaction of prekallikrein with iodoacetamide-alkylated light chain using the IAF-light chain as a probe gave an average Kd of 16 +/- 4 nM and stoichiometry of 1.0 +/- 0.2 indicating indistinguishable affinities for prekallikrein.     

Interaction of factor XII, high-molecular-weight (HMW) kininogen and prekallikrein with sulfatide: analysis by fluorescence polarization

The interaction of high-molecular-weight (HMW) kininogen, Factor XII and prekallikrein with sulfatide was studied by fluorescence polarization. Fluorescein-conjugated derivatives of HMW kininogen, Factor XII and prekallikrein were prepared by reacting the purified bovine factors with fluorescein isothiocyanate (FITC). The apparent dissociation constant (Kd) for the binding of FITC-labeled HMW kininogen (F-HMW kininogen) with sulfatide was calculated to be 3.2 (+/- 0.3) X 10(-8) M. This binding was partially inhibited by three kininogen derivatives, fragment 1 X 2, kinin-free protein and fragment 1 X 2-light chain, but not by kinin and fragment 1 X 2-free protein. In the presence of Factor XII, the binding of F-HMW kininogen with sulfatide was strongly inhibited, suggesting that the zymogen and the protein cofactor compete for the same or a closely related binding site on the sulfatide surface. In contrast, the binding of FITC-labeled Factor XII (F-Factor XII) with sulfatide was weakly inhibited by HMW kininogen but not by prekallikrein. The Kd value for binding of F-Factor XII with sulfatide was calculated to be 2.0 (+/- 0.3) X 10(-8) M. F-Prekallikrein did not interact with sulfatide. Moreover, the fluorescence polarization value of F-HMW kininogen decreased in the presence of prekallikrein, leveling off at a one-to-one molar ratio of prekallikrein to F-HMW kininogen. The Kd value for binding of F-HMW kininogen-light chain (F-light chain) with prekallikrein was calculated to be 3.8 (+/- 0.6) X 10(-8) M and the stoichiometry was estimated as 1 to 1.2 on a molar basis from the Scatchard plot.     

Binding of heparin to human high molecular weight kininogen

The binding of heparin to high molecular weight kininogen (H-kininogen) was analyzed by the effect of kininogen in decreasing the heparin-induced enhancement of the rate of inactivation of thrombin by antithrombin. The conditions were arranged so that the heparin-catalyzed antithrombin-thrombin reaction, monitored in the presence of the reversible thrombin inhibitor p-aminobenzamidine, followed pseudo-first-order kinetics and the observed rate constant (kappa obsd) varied linearly with the heparin concentration. In the absence of metal ions, H-kininogen minimally affected kappa obsd, measured at a constant concentration of heparin with high affinity for antithrombin (30 nM), at I = 0.15, pH 7.4 and 25 degrees C. However, at a saturating concentration of Zn2+ (10 microM), kappa obsd was reduced to 50% at approximately 20 nM H-kininogen and to that of the uncatalyzed reaction at greater than or equal to approximately 0.2 microM H-kininogen. Conversely, at a saturating concentration of H-kininogen (0.5 microM), kappa obsd was decreased to 50% at approximately 0.6 microM Zn2+ and to the kappa obsd of the uncatalyzed reaction at greater than or equal to 10 microM Zn2+. Other metal ions were effective in the order Zn2+ approximately Ni2+ greater than Cu2+ approximately Co2+ approximately Cd2+. The single-chain and two-chain forms of H-kininogen and the H-kininogen light chain reduced the heparin enhancement in the presence of Zn2+ to the same extent, whereas low molecular weight kininogen had no influence.(ABSTRACT TRUNCATED AT 250 WORDS)     

Proteinase-sensitive regions in the heavy chain of low molecular weight kininogen map to the inter-domain junctions

Low molecular weight kininogen from human plasma was subjected to limited proteolysis with trypsin, chymotrypsin, elastase, and bromelain, and the resulting fragments of 20,000 or 40,000 Da were isolated. Amino-terminal sequence analysis of the fragments disclosed for the various proteinases eight independent cleavage sites distinct from the typical kallikrein cleavage sites flanking the kinin region. All the identified cleavage sites cluster in two stretches of 11-12 residues of the kininogen heavy chain. These short segments represent the primary attack sites for proteinases ("proteinase-sensitive regions") in the heavy chain portion of human low molecular weight kininogen. The amino acid sequences of the two proteinase-sensitive regions are mutually homologous; they are further characterized by the presence of a single copy each of the consensus tetrapeptide Cys-X-Gly-Cys known to form a narrow disulfide loop (Kellermann, J., Thelen, C., Lottspeich, F., Henschen, A., Vogel, R., and Müller-Esterl, W. (1987) Biochem. J. 247, 15-21). The proteinase-sensitive regions are located at the junctions of the three cystatin-like domains constituting the kininogen heavy chain. Proteolytic cleavage at the sensitive regions dissects the kininogen heavy chain and releases single domains of 20,000 Da and combined domains of 40,000 Da which can function as cysteine proteinase inhibitors. The presence of kininogen heavy chain domains in plasma samples under pathologic conditions suggests that cleavage of the proteinase-sensitive regions might also occur in vivo.     

Fine mapping of the high molecular weight kininogen binding site on blood coagulation factor XI through the use of rationally designed synthetic analogs.

Using immunological and chemical cleavage techniques, we have previously identified a domain contained within residues Phe56-Ser86 in the first tandem repeat (A1) of the heavy chain of factor XI which binds high Mr kininogen (Baglia, F. A., Jameson, B. A., and Walsh, P. N. (1990) J. Biol. Chem. 265, 4149-4154). We have now chemically synthesized peptides from corresponding homologous regions in the second (A2), third (A3), and fourth (A4) tandem repeats of the heavy chain (A2: Asn145-Ala176; A3: Asn235-Arg266; and A4: Gly326-Lys357). These peptides had no effect on the binding of factor XI to high Mr kininogen. Because of a lack of detailed structural information for the A1 domain, a molecular model of this region was constructed. This hypothetical model made distinct and testable predictions regarding potential surfaces and concomitant secondary structure. Specifically, the resulting structure depicted two juxtaposed beta-stranded stem-loops that, in conjunction with biological information, constitute a candidate surface for contact with high Mr kininogen. The hypothetical A1 model was, consequently, used as a predictive template in the rational design of two synthetic peptides (Val59-Arg70 and Asn72-Lys83). When both these peptides were added together and the binding of factor XI to high Mr kininogen was examined, a synergistic inhibitory effect was observed compared with each peptide added individually. Our data are consistent with the notion that the sequence of amino acids from Val59-Lys83 of the heavy chain of factor XI contains two antiparallel beta-strands connected by beta-turns that together comprise a continuous surface utilized for the binding of high Mr kininogen.     

Mapping of functional domains of human high molecular weight and low molecular weight kininogens using murine monoclonal antibodies

Thirty-four monoclonal antibodies directed against human high molecular weight (HMW) and low molecular weight (LMW) kininogens and their derivatives were obtained, and the specificities of the antibodies were assayed by enzyme-linked immunosorbent assay (ELISA). By use of HMW kininogen, kinin-free HMW kininogen, kinin-free and fragment 1.2 (fr 1.2) free HMW kininogen, fr 1.2-light chain of HMW kininogen, LMW kininogen, kinin-free LMW kininogen, heavy chain of LMW kininogen, and light chain of LMW kininogen, the monoclonal antibodies were characterized and classified into four groups: (A) 20 monoclonal antibodies reacting with only the heavy chain, a common region of HMW and LMW kininogens; each of these monoclonal antibodies possessed the specificity to domain 1 (2 monoclonal antibodies), domain 2 (2 monoclonal antibodies), domain 3 (7 monoclonal antibodies), and both domains 2 and 3 (7 monoclonal antibodies) of the heavy chain; (B) 7 monoclonal antibodies reacting with fr 1.2, a unique histidine-rich region; (C) 5 monoclonal antibodies reacting with the light chain of HMW kininogen; (D) 2 monoclonal antibodies reacting with the light chain of LMW kininogen. Two monoclonal antibodies in the first group (group A), designated HKG H7 and H12, effectively suppressed the thiol proteinase inhibitor activity of HMW kininogen to papain and calpains and of LMW kininogen to papain, but the others did not affect it. Further, all the monoclonal antibodies which recognized the fr 1.2 or light chain of HMW kininogen (groups B and C) suppressed the clotting activity.(ABSTRACT TRUNCATED AT 250 WORDS)     

High molecular weight kininogen utilizes heparan sulfate proteoglycans for accumulation on endothelial cells

Kininogens, the high molecular weight precursor of vasoactive kinins, bind to a wide variety of cells in a specific, reversible, and saturable manner. The cell docking sites have been mapped to domains D3 and D5(H) of kininogens; however, the corresponding cellular acceptor sites are not fully established. To characterize the major cell binding sites for kininogens exposed by the endothelial cell line EA.hy926, we digested intact cells with trypsin and other proteases and found a time- and concentration-dependent loss of (125)I-labeled high molecular weight kininogen (H-kininogen) binding capacity (up to 82%), indicating that proteins are crucially involved in kininogen cell attachment. Cell surface digestion with heparinases similarly reduced kininogen binding capacity (up to 78%), and the combined action of heparinases and trypsin almost eliminated kininogen binding (up to 85%), suggesting that proteoglycans of the heparan sulfate type are intimately involved. Consistently, inhibitors such as p-nitrophenyl-beta-d-xylopyranoside and chlorate interfering with heparan sulfate proteoglycan biosynthesis reduced the total number of kininogen binding sites in a time- and concentration-dependent manner (up to 67%). In vitro binding studies demonstrated that biotinylated H-kininogen binds to heparan sulfate glycosaminoglycans via domains D3 and D5(H) and that the presence of Zn(2+) promotes this association. Cloning and over-expression of the major endothelial heparan sulfate-type proteoglycans syndecan-1, syndecan-2, syndecan-4, and glypican in HEK293t cells significantly increased total heparan sulfate at the cell surface and thus the number of kininogen binding sites (up to 3. 3-fold). This gain in kininogen binding capacity was completely abolished by treating transfected cells with heparinases. We conclude that heparan sulfate proteoglycans on the surface of endothelial cells provide a platform for the local accumulation of kininogens on the vascular lining. This accumulation may allow the circumscribed release of short-lived kinins from their precursor molecules in close proximity to their sites of action.     

Antibody variable region binding by Staphylococcal protein A: thermodynamic analysis and location of the Fv binding site on E-domain.

Immunoglobulins of human heavy chain subgroup III have a binding site for Staphylococcal protein A on the heavy chain variable domain (V(H)), in addition to the well-known binding site on the Fc portion of the antibody. Thermodynamic characterization of this binding event and localization of the Fv-binding site on a domain of protein A is described. Isothermal titration calorimetry (ITC) was used to characterize the interaction between protein A or fragments of protein A and variants of the hu4D5 antibody Fab fragment. Analysis of binding isotherms obtained for titration of hu4D5 Fab with intact protein A suggests that 3-4 of the five immunoglobulin binding domains of full length protein A can bind simultaneously to Fab with a Ka of 5.5+/-0.5 x 10(5) M(-1). A synthetic single immunoglobulin binding domain, Z-domain, does not bind appreciably to hu4D5 Fab, but both the E and D domains are functional for hu4D5 Fab binding. Thermodynamic parameters for titration of the E-domain with hu4D5 Fab are n = 1.0+/-0.1, Ka = 2.0+/-0.3 x 10(5) M(-1), and deltaH = -7.1+/-0.4 kcal mol(-1). Similar binding thermodynamics are obtained for titration of the isolated V(H) domain with E-domain indicating that the E-domain binding site on Fab resides within V(H). E-domain binding to an IgG1 Fc yields a higher affinity interaction with thermodynamic parameters n = 2.2+/-0.1, Ka > 1.0 x 10(7) M(-1), and deltaH = -24.6+/-0.6 kcal mol(-1). Fc does not compete with Fab for binding to E-domain indicating that the two antibody fragments bind to different sites. Amide 1H and 15N resonances that undergo large changes in NMR chemical shift upon Fv binding map to a surface defined by helix-2 and helix-3 of E-domain, distinct from the Fc-binding site observed in the crystal structure of the B-domain/Fc complex. The Fv-binding region contains negatively charged residues and a small hydrophobic patch which complements the basic surface of the region of the V(H) domain implicated previously in protein A binding.     

High-affinity binding of two molecules of cysteine proteinases to low-molecular-weight kininogen.

Human low-molecular-weight kininogen (LK) was shown by fluorescence titration to bind two molecules of cathepsins L and S and papain with high affinity. By contrast, binding of a second molecule of cathepsin H was much weaker. The 2:1 binding stoichiometry was confirmed by titration monitored by loss of enzyme activity and by sedimentation velocity experiments. The kinetics of binding of cathepsins L and S and papain showed the two proteinase binding sites to have association rate constants kass,1 = 10.7-24.5 x 10(6) M-1 s-1 and kass,2 = 0.83-1.4 x 10(6) M-1 s-1. Comparison of these kinetic constants with previous data for intact LK and its separated domains indicate that the faster-binding site is also the tighter-binding site and is present on domain 3, whereas the slower-binding, lower-affinity site is on domain 2. These results also indicate that there is no appreciable steric hindrance for the binding of proteinases between the two binding sites or from the kininogen light chain.