Heavy chain of human high molecular weight and low molecular weight kininogens binds calcium ion

An antibody subpopulation, anti high molecular weight (anti-HMW) kininogen-Ca2+ antibody able to bind specifically to the HMW kininogen-Ca2+ complex, was isolated from anti-HMW kininogen antiserum. Partially purified anti-HMW kininogen antibody was applied to a HMW kininogen-Sepharose column equilibrated with 40 mM tris(hydroxymethyl)aminomethane hydrochloride buffer, pH 7.5, containing 1.0 M NaCl and 1 mM CaCl2, and anti-HMW kininogen-Ca2+ antibody was eluted with 5 mM ethylenediaminetetraacetic acid. As a result of characterization by enzyme-linked immunosorbent assay, this antibody specifically recognized the cyanogen bromide cleaved fragment 1 (CB-1) region (1-160 amino acid sequence) of the heavy chain of kininogen molecules in the presence of Ca2+ or Mg2+. Furthermore, circular dichroism (CD) experiments showed that the conformational changes of HMW kininogen and heavy chain were induced by metal ions such as Ca2+ and Mg2+ and that these changes were due to the conformational change of the CB-1 region of the heavy chain. The dissociation constant (Kd) for the heavy chain-Ca2+ measured by CD analysis at 214 nm was found to be 0.33 +/- 0.09 mM (mean +/- SD). The number of Ca2+-binding sites of heavy chain calculated from the Hill plot was 1.15 +/- 0.04 (mean +/- SD). Then, a possible Ca2+-binding site was found in the amino-terminal portion of the heavy chain of kininogen molecules.     

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)     

Studies on human kininogens. I. Isolation, characterization, and cleavage by plasma kallikrein of high molecular weight (HMW)-kininogen.

1. Human high molecular weight (HMW)-kininogen was highly purified from human plasma by chromatographies on QAE-Sephadex A-50 and CM-Sephadex C-50. Human HMW-kininogen thus purified was a mixture of a single chain and a disulfide-linked pair of chains. Human HMW-kininogen is an acidic glycoprotein having a molecular weight of 120,000. The amino acid composition of human HMW-kininogen is quite similar to that of bovine HMW-kininogen. 2. We investigated whether the liberation of kinin from human HMW-kininogen by human plasma kallikrein was accompanied by liberation of histidine-rich fragments, as observed with bovine HMW-kininogen (Han et al. (1975) J. Biochem. 77, 55--68). After prolonged incubation of human HMW-kininogen and human plasma kallikrein followed by gel-filtration on Sephadex G-50, a fragment of molecular weight 8,000 was isolated together with bradykinin. However, the histidine content of the fragment was not as high as that in the bovine fragments. Most of the histidine in human HMW-kininogen was recovered in the kinin-free protein, and the light chain of kinin-free protein was found to be rich in histidine compared with the heavy chain. These results suggest that the histidine-rich sequence in human HMW-kininogen is not released by the action of human plasma kallikrein, but remains bound to the light chain of kinin-free protein.     

Various properties and kinetics of interaction of high and low molecular weight human kininogens with human plasma kallikrein

A relatively simple procedure for isolation and purification of human blood plasma kallikrein (HPK) by QAE-Sephadex A-50 SP-Sephadex C-50 and affinity chromatography on Sepharose 4B with immobilized soybean trypsin inhibitor with the activity yield of about 40% has been developed. The method allows for simultaneous isolation of low (LMW) and high molecular weight (HMW) kininogens from the same HPK sample. HPK preparations are homogeneous upon 7.5% polyacrylamide gel electrophoresis in the presence of 0.1% SDS; its Mr is 90,000. After treatment with beta-mercaptoethanol, HPK dissociates into two fragments with Mr of 43,000 and 37,000. HPK preparations have high specific activities of esterase (31 microM/min), amidase (78 microM/min), and kininogenase (420 micrograms equiv. bradikinin/min). The high degree of protein purification was demonstrated by titration of active centers with 4-methylumbelliferylguanidine benzoate. The values of equilibrium dissociation constants for the HPK complex with aprotinin (Ki) equal to 1 X 10(-8) M (ethyl ester of N-alpha-benzoyl-L-arginine) and 1,5 X 10(-9) M (HMW) were determined. The kinetics of HPK-induced liberation of bradikinin from purified preparations of HMW and LMW was studied. The kinetic parameters (Km, kcat and kcat/Km) of this reaction suggest a high affinity of HPK for HMW, but not for LMW. LMW does not compete with HMW for the enzyme active center. It is assumed that LMW is not a physiological substrate for HPK.     

Interaction of human calpains I and II with high molecular weight and low molecular weight kininogens and their heavy chain: mechanism of interaction and the role of divalent cations

Calpain I prepared from human erythrocytes was half-maximally and maximally activated at 23 and 35 microM calcium ion, and two preparations of calpain II from human liver and kidney were half-maximally activated at 340 and 220 microM calcium ion and maximally activated at 900 microM calcium ion, respectively. High molecular weight (HMW) and low molecular weight (LMW) kininogens isolated from human plasma and the heavy chain prepared from these proteins inhibited calpain I as well as calpain II. The molar ratios of calpains to HMW kininogen to give complete inhibition of calpains were 1.4 for calpain I and 2.0 for calpain II, and those of calpains to heavy chain were 0.40-0.66 for calpain I and 0.85 for calpain II. LMW kininogen did not completely inhibit the calpains even with an excess amount of kininogen. The apparent binding ratio of calpain to HMW kininogen estimated from the disc gel electrophoretic analysis, however, was found to be 2:1, whereas those of calpain to LMW kininogen and of calpain to heavy chain were found to be 1:1. Calpains and kininogens failed to form complexes in the absence of calcium ion. In the presence of calcium ion, however, they formed the complexes, which were dissociable by the addition of ethylene glycol bis(beta-aminoethyl ether)-N,N,N',N'-tetraacetic acid. The minimum concentrations of calcium ion required to induce complex formation between calpain I and kininogens and calpain II and kininogens were 70 and 100 microM, respectively. Some other divalent cations such as Mn2+, Sr2+, and Ba2+ were also able to induce the complex formation between calpains and kininogens.(ABSTRACT TRUNCATED AT 250 WORDS)     

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.     

The molecular weight of bovine lactoferrin.

The molecular weight of bovine lactoferrin in a neutral solvent (e.g. 0.2 M NaC1, pH 7.8 20 degrees C) has been determined using high-speed sedimentation equilibrium at various concentrations and speeds. Under these conditions the protein behaved as a single thermodynamic component with a weight-average molecular weight [MW]C=0 = 93000 plus or minus 2000 and a second virial coefficient B = 4.3-10(-5) mol-ml(-1)-g(-2). This value of the molecular weight is in good agreement with values previously reported by Groves (J. Am. Chem. Soc. 82, 3345-3350, 1960) and Szuchet and Johnson (Eur. Polym. J. 2, 115-128, 1966); it is, however, in disagreement with the more recent value given by Castellino et al. (J. Biol. Chem. 245, 4269-4275, 1970). The possible reasons for this discrepancy are discussed.     

Role of calpains and kininogens in inflammation.

Neutrophil chemotactic activity was found in the autodigest of calcium dependent cysteine proteinase (calpain) I purified from human erythrocytes, an active peptide was isolated, and its structure was determined. It was an N-acetyl nonapeptide with the sequence: N-acetyl Ser-Glu-Glu-Ile-Ile-Thr-Pro-Val-Tyr. This peptide was identical with the N-terminal amino acid sequence of the large subunit of calpain I deduced from cDNA sequence, except that the peptide was lacking a methionine residue and was acetylated at the N-terminus. A number of N-acetyl peptides with N-terminal amino acid sequences of large and small subunits of calpains I and II were synthesized and their chemotactic activity was estimated. In addition to the N-acetyl nonapeptide from calpain I large subunit, several peptides of different lengths from the small subunit showed dose-dependent migrations of neutrophils. They include N-acetyl tetra, hepta, octa, nona and larger size peptides. Further, it was also revealed that when calpain was incubated with high molecular weight (HMW) or low molecular weight (LMW) kininogen, kinin liberation occurred with simultaneous inhibition of calpains by kininogens. These data suggest that chemical mediators generated from the calpain-kininogen system may participate in migration and accumulation of neutrophils to the inflammatory locus.     

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.     

Low molecular weight RNA species from chromatin.

Several methods of preparing low molecular weight RNA from chick embryo chromatin have been examined. Traditional methods for dissociating chromatin utilizing high concentrations of salt (greater than 2 M) followed by high-speed centrifugation resulted in very low yields of RNA. Increased yields of RNA were obtained by treating chromatin at lower salt concentration (0.2-0.5 M). By using low salt extraction and sodium dodecyl sulfate-phenol deproteinization, six to eight low molecular weight homogeneous RNA species were isolated from chick embryo chromatin and mouse myeloma chromatin. In the myeloma system, all these RNAs are metabolically stable. Each component is homogeneous as examined by gel electrophoresis and hybridizes with mouse DNA at a rate consistent with a single species. There are multiple gene copies for these RNA species in the mouse genome, varying from 100 to 2000 copies for the different species. One of these RNAs is identical with 5S rRNA. In addition, the redundancy of genes for 18S, 28S, and 5S rRNA and tRNA was determined. Approximately 300 copies for 18 and 28S rTRNA and 500 copies for 5S rRNA were found. tRNAs were on an average 110-fold redundant with about 55 different species measured.     

On the molecular weight of thiosulfate sulfurtransferase.

Bovine liver thiosulfate sulfurtransferase (rhodanese) (EC 2.8.1.1) HAS BEEN REPORTED TO EXIST IN SOLUTION IN A RAPID, PH-dependent equilibrium between monomeric and dimeric forms of molecular weights 18 500 and 37 000 (Volini, M., DeToma, F. and Westley, J. (1967), J. Biol. Chem. 242, 5220). We have reinvestigated the proposed dissociation using sodium dodecylsulfate-polyacrylamide gel electrophoresis. The smallest rhodanese species observed has a molecular weight around 35 000, which is not reduced by severe denaturing conditions, including alkylation in 8 M guanidine-HCl or dialysis against 2% sodium dodecylsulfate and 5% mercaptoethanol. After limited CNBr cleavage, intermediate products of greater than 18 500 molecular weight are formed. The apparent molecular weight of these intermediate fragments is not changed by addition of mercaptoethanol. The total apparent molecular weights of the CNBr fragments after exhaustive cleavage is approx. 45 000 plus or minus 15 000. These results are not consistent with a monomer molecular weight of approx. 18 500 for thiosulfate sulfurtransferase.     

Viscosity and molecular weight of hyaluronic acids.

The intrinsic viscosity ([eta]) and the molecular weight (M) by sedimentation equilibrium were determined for hyaluronic acids of low (M=104--7.2X10(4)) and high (M=3.1X10(5)--1.5X10(6)) molecular weights. Double logarithmic plot of [eta] against M gave different lines for the two groups. The relationship between [eta] and M was [eta]=3.0X10(6)XM1,20 for the former and [eta]=5.7X10(-4)XM0.46 for the latter group. The molecular weight at the point of intersection of the two lines was about 1.5X10(5). The rheological behavior of the hyaluronic acids below M=2.1X10(4), for which the value of reduced viscosity was independent of concentration, was different from that of the hyaluronic acids above M=5.1X10(4), for which the value of reduced viscosity increased with concentration.     

Determination of molecular weight and molecular structure of rat-liver pyruvate carboxylase.

The molecular weight of pyruvate carboxylase isolated from pigeon and rat liver mitochondria was examined using analytical ultracentrifugation and electron microscopy. The enzyme molecule appeared as a tetramer with the four subunits arranged at the corners of a square. Sedimentation studies in the analytical ultracentrifuge, extrapolated to infinite dilution, showed the tetramer to have a molecular weight Mc=0r of 280 000 and an So20,w of 12.7 S. The tetramer could be dissociated into trimers and dimers of lower specific enzymic activity by storage at 4 degrees C or incubation at -- 20 degrees C at low protein concentrations. The isolated trimers and dimers had a molecular weight Mc=0r of 210 000 and 140 000, respectively, and an So20,w of 10.85 S and 7.55 S, respectively. Incubation with 2 M urea at 20 degrees C yielded enzymically inactive subunits (Mc=0r = 70 000; So20,w = 4.95 S). The molecular weights (for pyruvate carboxylase and its subunits), as calculated from the subunit diameter observed in the electron microscope, were consistent with the values obtained from sedimentation studies.