Amino acid makeup, structural characteristics and substrate specificity of rabbit plasma kininogen]

Highly purified kininogen preparation with the activity of 16-18 int. units per mg was isolated from rabbit blood serum. Its molecular weight was estimated to be 54 000 by gel filtration through Sephadex G-200. Leucine was identified as N-terminal amino acid by the dansylation method. Rabbit kininogen consists of 394 amino acid residues (except tryptophane). Amino acid composition of kininogen is characterized by a high content of dicarbonic amino acids, proline and by a low content of methionine. Kininogen molecule does not contain SH-groups. 13.1-13.5 SH-groups were found in kininogen after the reduction of S-S bonds with beta-mercaptoethanol in the presence of 8 M urea, thus indicating the presence of 6-7 S-S bonds in kininogen molecule. Kininogen group does not occupy C-terminal position in the molecule, because the treatment of the protein with carboxypeptidase B does not change the content of bradykinine in it. Purified kininogen preparation is a substrate for kallikrein from rabbit blood plasma, human saliva and trypsin. Unlike trypsin, kallikreines from human blood plasma and saliva release kinines from kininogen with reduced S-S bonds. Under spontaneous reoxidation of reduced S-S bonds up to 90%, substate properties of kininogen for tripsin recover only by 50%. Rabbit kininogen is similar to beef kininogen II in its molecular weight, amino acid composition and the number of S-S bonds.     

Purification and Characterization of Kininogens from Sheep Plasma

High molecular weight kininogen (HMWK) and low molecular weight kininogen (LMWK) have been purified from sheep ( Avis Arias) plasma in three steps involving ammonium sulphate precipitation, column chromatography on Sephacryl-300HR and ion exchange chromatography on DEAE cellulose. HMWK gave a single band on native and SDS-PAGE with a molecular weight corresponding to 280 kDa. Under reducing conditions purified HMWK was again resolved to a single band with molecular weight corresponding to 140 kDa indicative of its dimeric nature. LMWK was resolved into two isoforms named as LMWK1 and LMWK2, with an apparent molecular weight of 68 kDa. The yield of HMWK, LMWK1 and 2 was about 8.1, 5.63 and 10.65 respectively. HMWK, LMWK1 and 2 strongly inhibited activities of ficin and papain but not of trypsin, chymotrypsin and bromelain. K_i values estimated for HMWK with papain and ficin was 0.8 and 0.6 nM respectively. K_i values estimated for LMWK1 and 2 with papain were 2.40 and 2.00 nM respectively. Binding of HMWK, LMWK1 and 2 to activated papain were accompanied by pronounced changes in secondary and tertiary structure that are compatible with perturbations of environment of aromatic residues.     

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.     

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.     

Cysteine proteinase inhibitor in the ascitic fluid of sarcoma 180 tumor-bearing mice is a low molecular weight kininogen. Partial NH2- and COOH-terminal sequences and susceptibility to various glandular kallikreins

It has been proposed that a cysteine proteinase inhibitor (CPI) found in the ascitic fluid of Sarcoma 180 tumor-bearing mice is a kind of kininogen (Itoh, N., Yokota, S., Takagishi, U., Hatta, A., and Okamaoto, H. (1987) Cancer Res. 47, 5560-5565). The first 40 NH2-terminal residues and 54 residues of the COOH-terminal sequence, including the bradykinin moiety of highly purified ascites CPI, were determined and compared with those of mammalian low molecular weight kininogens (LMWK). The significant identity between these amino acid sequences with those of other mammalian LMWKs suggests that ascites CPI corresponds precisely to mouse LMWK. This kininogen has a light chain composed of 43 amino acid residues, which contains a unique Met-Ala-Arg-bradykinin sequence. Hydroxyproline, which was recently identified in the bradykinin sequence of kininogen from the ascitic fluid of a cancer patient, was not found in the kinin moiety of this mouse kininogen. Among purified glandular kallikreins from human, hog, rat, and mouse, only mouse submaxillary gland kallikrein was able to release bradykinin from this kininogen. Kinetic studies using a newly synthesized fluorogenic substrate, N-t-butoxycarbonyl-Met-Ala-Arg-MCA, revealed that mouse kallikrein hydrolyzes this substrate approximately 80-fold faster than does hog kallikrein, suggesting that the unique Met-Ala-Arg-bradykinin sequence is responsible for the varied susceptibility of mouse kininogen to different kallikreins.     

Bradykinin and kininogens in bovine milk

Two peptides exhibiting kinin activity in an isolated rat uterus assay were purified from pasteurized skim bovine milk. The amino acid sequence of the more prominent peptide was found to be that of bradykinin. Partially purified kinin preparations were also obtained from N-tosyl-L-phenylalanyl chloromethyl ketone-treated trypsin digests of non-fat dry milk and insoluble lactalbumin. The application of fast atom bombardment/mass spectrometry permitted detection of the bradykinin protonated molecular ion in each of these samples. Collision-activated decomposition of the ion of m/z 1061 confirmed it to be the protonated molecular ion of bradykinin. Fast atom bombardment/mass spectrometry analysis further confirmed the occurrence of bradykinin in a pancreatic kallikrein digest of a partially purified bovine milk kininogen preparation. In apparent contrast with bovine plasma kininogens, the forms of kininogen which occur in milk include a high Mr kininogen (Mr greater than 68,000) and a low Mr kininogen (Mr 16,000-17,000). Kinin formation from the high Mr kininogen is catalyzed by porcine pancreatic kallikrein or trypsin.     

T-kininogen--the major plasma kininogen in rat adjuvant arthritis

Total kininogen in plasma of Freund's adjuvant treated rats increased 20-fold 7 days following the injection. Analysis of the kininogens demonstrated that increases in T-kininogen was the major reason for the rise in kininogen. High molecular weight and low molecular weight kininogens showed little or no change. The increase in T-kininogen paralleled the inflammatory condition. Anti-inflammatory agents which reduced paw swelling also reduced plasma T-kininogen levels. Unidentified peaks on HPLC of kinin following plasma treatment by trypsin were shown to be oligopeptides containing T-kinin (Ile-serbradykinin). The relationship of T-kininogen to the inflammatory response is discussed.     

Release of a new vascular permeability enhancing peptide from kininogens by human neutrophil elastase

Stimulated neutrophils produced vascular permeability enhancing (VPE) activity in the presence of high molecular weight kininogen (HMWK), which was inhibited mainly by a neutrophil elastase (NE) inhibitor or a bradykinin (BK) B(2)-receptor antagonist. NE (>3 nM) generated VPE activity from kininogens at normal plasma concentrations with the smaller protein being several fold more responsive than the larger protein, through releasing a new VPE peptide (E-kinin), SLMKRPPGFSPFRSSRI. Synthetic E-kinin, SLMKRPPGFSPFRSS and SLMKRPPGFSPFR had VPE and blood pressure lowering activities, which were comparable to the activities of BK and completely inhibited by B(2)-receptor antagonists. Interestingly, E-kinin and SLMKRPPGFSPFRSS did not induce smooth muscle contraction. These results suggest that E-kinin formed in vivo may be processed at the carboxy-terminus to give a peptide that can bind to the B(2)-receptor. The molecular mechanism for neutrophil-associated VPE may be explained by excision of E-kinin from kininogens by NE, followed by further processing of the peptide.     

Purification and characterization of rat low molecular weight kininogen

Low molecular weight (LMW) kininogen was isolated from pooled rat plasma by chromatography on DEAE-Sephadex A-50, CM-Sephadex C-50, Blue-Sepharose CL-6B, and Sephadex G-100. It was shown to be homogeneous by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) and immunoelectrophoresis. The molecular weight of rat LMW kininogen was determined to be 72,000 by SDS-PAGE. The LMW kininogen contained 83.5% protein, 4.0% hexose, 5.5% hexosamine, and 2.7% sialic acid. Kinin liberated from LMW kininogen by trypsin treatment was identified as an Ile-Ser-bradykinin(T-kinin) by analysis involving ion exchange column chromatography on CM-Sephadex C-25 and high performance liquid chromatography on a reverse-phase column (ODS-120T). LMW kininogen formed kinin with rat submaxillary gland kallikrein, but the kinin liberated was only 14% of the total kinin content, that is, that released by trypsin. In order to determine the immunochemical properties of LMW kininogen, specific antiserum was prepared in rabbits. The antiserum cross-reacted with high molecular weight (HMW) kininogen, but spur formation was observed between the LMW and HMW kininogens. The kininogen level in rat plasma was estimated to be 433 microgram/ml by a quantitative single radial immunodiffusion test.     

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.     

Human high molecular weight kininogen as a thiol proteinase inhibitor: presence of the entire inhibition capacity in the native form of heavy chain

High molecular weight (HMW) kininogen was purified from fresh human plasma by two successive column chromatographies on DEAE-Sephadex A-50 and Zn-chelate Sepharose 4B. The purified HMW kininogen appeared to be a single band on sodium dodecyl sulfate (SDS)-polyacrylamide disc gel electrophoresis in both the presence and absence of beta-mercaptoethanol. However, it gave two bands on nonreduced SDS-polyacrylamide slab gel electrophoresis, a major band of dimeric form (Mr 200 000, ca. 95%) and a minor band of monomeric form (Mr 105 000, ca. 5%). Under reduced conditions, the dimeric form was converted stoichiometrically to a monomeric form (Mr 110 000), and the monomeric form observed under nonreduced conditions (Mr 105 000) was converted to a heavy chain (Mr 60 000) and a light chain (Mr 50 000). The formation of a dimer of HMW kininogen was also confirmed by an immunoblotting experiment. This unique property of intact HMW kininogen to form a dimer was further utilized in studies on the kininogens and their derivatives as thiol proteinase inhibitors. The purified HMW kininogen strongly inhibited the caseinolytic activities of calpain I, calpain II, and papain but not those of trypsin, chymotrypsin, and thermolysin, indicating that it was a group-specific inhibitor for thiol proteinases. When HMW kininogen was reduced with 0.14 or 1.4 M beta-mercaptoethanol, its inhibitory activity was partially or mostly inactivated, but on subsequent air oxidation its activity was almost completely recovered. In addition, kinin-free and fragment 1,2 free HMW kininogen showed higher inhibitory activity than the intact HMW kininogen.(ABSTRACT TRUNCATED AT 250 WORDS)     

Stoichiometry of binding of high molecular weight kininogen to factor XI/XIa

Factor XI is a dimeric protein and circulates in plasma complexed with high molecular weight kininogen (HMWK). We investigated the binding of HMWK to factor XIa utilizing two active site directed fluorescent probes: nitrobenzoxadiazole aminopentyl methylphosphonofluoridate for serine and dansyl-glu-gly-arg-chloromethyl ketone for histidine. In the presence of saturating amounts of HMWK, the fluorescence of factor XIa-fluorophore was quenched by approximately 28% for each probe. Titrations of the fluorescent factor XIa with HMWK revealed that each subunit of factor XIa binds one molecule of HMWK with a Kd approximately 3.4 X 10(-8)M.     

Purification of single-chain human low-molecular-weight kininogen and demonstration of its cleavage by human urinary kallikrein

Human low-molecular-weight kininogen (LMWK) was purified to apparent physical and functional homogeneity by a six-step procedure consisting of ion-exchange chromatography, reverse ammonium sulfate gradient solubilization, hydrophobic chromatography on phenyl-Sepharose, gel filtration, and removal of contaminating proteins by their affinity for Affi-Gel blue and zinc. The recovery averaged 15.6% (n = 4). Purified LMWK presented as a single stained band on alkaline polyacrylamide gel electrophoresis which corresponded to the region of function in eluates from a duplicate gel. The apparent homogeneity was also observed in sodium dodecyl sulfate (SDS)-gel electrophoresis, where the protein presented as a single band of Mr = 65,000 without reduction and 68,000 with reduction. A mole of substrate released 0.8 mol of kinin in 5 min when cleaved by human urinary kallikrein (HUK), and 0.9 mol after 30 min. Cleavage of the single-chain LMWK released kinin from within a disulfide loop as indicated by the SDS-gel electrophoresis of reduced and unreduced kinin-free LMWK. The heavy chain exhibited an Mr = 62,000, which is similar to the Mr of the amino-terminal chain of human HMWK and is consistent with their antigenic relatedness. In contrast to the Mr = 64,000 procoagulant chain of human HMWK, the small (less than 10,000) carboxy-terminal chain of LMWK has no procoagulant activity and may serve only to protect the kinin moiety in the intact substrate.     

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.     

Purification and characterization of novel kininogens from spotted wolffish and Atlantic cod.

Kininogens are multifunctional proteins found so far mainly in mammals. They carry vasoactive kinins as well as participate in defense, blood coagulation and the acute phase response. In this study, novel kininogens were isolated from Atlantic cod (Gadus morhua L.) and spotted wolffish(Anarhichas minor) by papain-affinity chromatography. The molecular mass of cod kininogen determined by MALDI-TOF mass spectrometry to be 51.0 kDa and it had pI values of 3.6, 3.9 and 4.4. The molecular mass of wolffish kininogen was 45.8 kDa and it had pI values of 4.1, 4.3, 4.35 and 4.4. Partial amino-acid sequences determined from both kininogens showed clear homology with previously determined kininogen sequences. Both kininogens were found to inhibit cysteine proteinases like papain and ficin but they had no effect on trypsin, a serine proteinase. Wolffish kininogen carried alpha2,3-sialylated biantennary and triantennary N-glycans with extensive sialic acid O-acetylation. Cod kininogen carried similar glycan structures but about 1/3 of its glycans carried sulfate at their N-acetylglucosamine units.     

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 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.     

Properties of chemically oxidized kininogens

Kininogens are multifunctional proteins involved in a variety of regulatory processes including the kinin-formation cascade, blood coagulation, fibrynolysis, inhibition of cysteine proteinases etc. A working hypothesis of this work was that the properties of kininogens may be altered by oxidation of their methionine residues by reactive oxygen species that are released at the inflammatory foci during phagocytosis of pathogen particles by recruited neutrophil cells. Two methionine-specific oxidizing reagents, N-chlorosuccinimide (NCS) and chloramine-T (CT), were used to oxidize the high molecular mass (HK) and low molecular mass (LK) forms of human kininogen. A nearly complete conversion of methionine residues to methionine sulfoxide residues in the modified proteins was determined by amino acid analysis. Production of kinins from oxidized kininogens by plasma and tissue kallikreins was significantly lower (by at least 70%) than that from native kininogens. This quenching effect on kinin release could primarily be assigned to the modification of the critical Met-361 residue adjacent to the internal kinin sequence in kininogen. However, virtually no kinin could be formed by human plasma kallikrein from NCS-modified HK. This observation suggests involvement of other structural effects detrimental for kinin production. Indeed, NCS-oxidized HK was unable to bind (pre)kallikrein, probably due to the modification of methionine and/or tryptophan residues at the region on the kininogen molecule responsible for the (pro)enzyme binding. Tests on papain inhibition by native and oxidized kininogens indicated that the inhibitory activity of kininogens against cysteine proteinases is essentially insensitive to oxidation.     

Purification and characterization of two kinds of low molecular weight kininogens from rat (non-inflamed) plasma. One resistant and the second sensitive to rat glandular kallikreins

Two kinds of low molecular weight kininogens (identified as A and B) were isolated from pooled plasma of Sprague-Dawley rats. They show a single band on sodium dodecyl sulfate-polyacrylamide gel electrophoresis in the presence and absence of 2-mercaptoethanol, and the molecular weights are 68,000 for low Mr kininogen A and 73,000 for low Mr kininogen B. Although the molecular weights and amino acid compositions of the low Mr kininogens are similar, rat submaxillary and urinary kallikreins released bradykinin from low Mr kininogen B, whereas low Mr kininogen A was resistant to these enzymes. The COOH-terminal portion of low Mr kininogen A was isolated after cyanogen bromide treatment, and the amino acid sequence of the COOH-terminal 55 residues including the T-kinin (Ile-Ser-bradykinin) was determined. The COOH-terminal portion consists of two sequences with substitution of 4 residues. One peptide corresponds to alpha 1-major acute phase protein (Cole, T., Inglis, A. S., Roxburgh, C. M., Howlett, G. J., and Schreiber, G. (1985) FEBS Lett. 182, 57-61) and the other to the TI-kininogen predicted from a cDNA study (Furuto-Kato, S., Matsumoto, A., Kitamura, N., and Nakanishi, S. (1985) J. Biol. Chem. 260, 12054-12059). The results demonstrate that there exist at least two kinds of low Mr kininogens with clearly different function in rat plasma: one of them, low Mr kininogen A, is a precursor of T-kinin and is resistant to kallikreins, and the second, low Mr kininogen B, is sensitive to tissue kallikreins and shares properties with bovine and human low Mr kininogens. The results also demonstrate that T-kininogen is a mixture of two isoproteins which correspond to alpha 1-major acute phase protein or TI-kininogen, respectively. We could not detect the low Mr kininogen corresponding to the TII-kininogen predicted from the cDNA study of Furuto-Kato et al.     

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.     

Kinin release from kininogens by calpains

During the investigation of inhibitory activity of kininogens toward calpains [EC 3.4.22.17], we found that lysyl-bradykinin was liberated from both high molecular weight (HMW) and low molecular weight (LMW) kininogens by the action of the calpains. The kinin liberation occurred in a limited range of calpain to kininogen molar ratios of 0.5:1 to 8:1, and in that condition calpains were simultaneously inhibited 20 to 80% by kininogens. The maximum level of kinin release from HMW and LMW kininogens by calpain I was about 25% and that by calpain II was 20%. These results suggest that in case of inflammation the kininogens play two physiologically distinct roles by interaction with calpains: to release lysyl-bradykinin and to inhibit proteinase activity of calpains derived from the damaged tissues.