HK Binding Research Articles

Cell surface-associated chondroitin sulfate proteoglycans bind contact phase factor H-kininogen

The kinin system has been recognized as a locally operating hormone system of cardiovascular cells, however, the molecular mechanisms regulating circumscribed kinin release on cell surfaces are not fully understood. In particular, the principal cell docking sites for the kinin precursor, high molecular weight kininogen (HK), are not fully explored. Here we demonstrate by enzymatic digestion, recombinant overexpression, and affinity cross-linking studies that cell surface chondroitin sulfate (CS) chains of proteoglycans (PGs) serve as major HK binding sites on platelet, fibroblast, liver, and endothelial kidney cells. In this way, CS-type PGs may contribute to a local accumulation of kinin precursors on cell surfaces and modulate circumscribed release of short-lived kinin hormones at or next to their site of action.

Assembly of High Molecular Weight Kininogen and Activation of Prekallikrein on Cell Matrix

Investigations determined if extracellular matrix of endothelial cells (EC) is a platform for HK assembly and PK activation. In buffers containing bovine serum albumin, biotin-HK binding to ECV304 cells or their matrix requires > or = 50 microM added Zn2+. Ortho-phenanthroline or a HK domain 5 peptide blocks HK binding. Binding to umbilical vein EC or matrix, but not ECV304 cells or matrix, is mediated by cytokeratin 1. Biotin-HK binds to ECV304 cells or matrix with a Kd of 15.8 or 9.0 nM and a Bmax of 2.6 x 10(7) or 2.4 x 10(7) sites/cell, respectively. PK activation on ECV304 cells or matrix is blocked by antipain or SBTI and corn trypsin inhibitor partially inhibits kallikrein formation. PK activation occurs on ECV304 cells or matrix prepared without serum or in human factor XII deficient serum, indicating that the PK activator is not factor XIIa. EC matrix promotes plasminogen activation after the assembly of HK, PK and pro-urokinase. These studies indicate that matrix of various EC has the ability to assemble HK allowing for PK activation and subsequent activities.

Human Factor XII Binding to the Glycoprotein Ib-IX-V Complex Inhibits Thrombin-induced Platelet Aggregation

Factor XII deficiency has been postulated to be a risk factor for thrombosis suggesting that factor XII is an antithrombotic protein. The biochemical mechanism leading to this clinical observation is unknown. We have previously reported high molecular weight kininogen (HK) inhibition of thrombin-induced platelet aggregation by binding to the platelet glycoprotein (GP) Ib-IX-V complex. Although factor XII will bind to the intact platelet through GP Ibalpha (glycocalicin) without activation, we now report that factor XIIa (0. 37 microm), but not factor XII zymogen, is required for the inhibition of thrombin-induced platelet aggregation. Factor XIIa had no significant effect on SFLLRN-induced platelet aggregation. Moreover, an antibody to the thrombin site on protease-activated receptor-1 failed to block factor XII binding to platelets. Inhibition of thrombin-induced platelet aggregation was demonstrated with factor XIIa but not with factor XII zymogen or factor XIIf, indicating that the conformational exposure of the heavy chain following proteolytic activation is required for inhibition. However, inactivation of the catalytic activity of factor XIIa did not affect the inhibition of thrombin-induced platelet aggregation. Factor XII showed displacement of biotin-labeled HK (30 nm) binding to gel-filtered platelets and, at concentrations of 50 nm, was able to block 50% of the HK binding, suggesting involvement of the GP Ib complex. Antibodies to GP Ib and GP IX, which inhibited HK binding to platelets, did not block factor XII binding. However, using a biosensor, which monitors protein-protein interactions, both HK and factor XII bind to GP Ibalpha. Factor XII may serve to regulate thrombin binding to the GP Ib receptor by co-localizing with HK, to control the extent of platelet aggregation in vivo.

Hexokinase 'binding sites' of normal and tumoral human brain mitochondria.

Interaction of type I hexokinase (HK-I) with the mitochondria obtained from the biopsy specimens of normal and tumoral human brain tissues was studied in the present investigation. This effort was undertaken with the aim of exploring possible differences in the mode of association of the enzyme with the outer mitochondrial membrane in the described sources. Results indicate that the two 'sites' for binding of HK-I suggested in the literature, based on extensive studies carried out on rat brain mitochondria, are similarly present in the human brain mitochondria. Differences in the microenvironments of HK binding, as reflected by the presented data, are suggested to be of importance in regulation of the catalytic potential of the bound enzyme. The real metabolic significance of this association in relation to cancer and its practical importance would need further investigation.

Cytokeratin 1 and gC1qR mediate high molecular weight kininogen binding to endothelial cells.

High molecular weight kininogen (HK) attaches to endothelial cells by separate sites on the heavy and light chains and requires 15-50 microM zinc. Previously identified binding proteins include gC1qR, cytokeratin 1, and the urokinase plasminogen activator receptor; however, their relative contributions to binding are not yet clarified. We have prepared affinity columns to which were coupled either cleaved HK or peptide LDCNAEVYVVPWEKKIYPTVNCQPLGM derived from heavy-chain domain 3. Endothelial cell membranes were solubilized and chromatographed in the presence or absence of zinc ion, the bound proteins were eluted, and active fractions were identified by dot blot using biotinylated HK, SDS/PAGE, and Western blot analysis. The peptide containing column eluate revealed but one band at 68 kDa if zinc ion was present which was identified as cytokeratin 1 by amino acid sequencing of an internal peptide. The HK affinity column revealed bands at 68 kDa (cytokeratin 1), 33 kDa (gC1qR), and 66 kDa (unidentified). HK or domain 3-derived peptide bound to the 68 kDa band; prekallikrein and Factor XII did not. HK or Factor XII bound to the 33-kDa band if zinc was present while no binding to the 66 kDa band was observed. Antibody to cytokeratin 1 inhibited HK binding to endothelial cells by 30%, antibody to gC1qR inhibited HK binding to endothelial cells by 72%, and a mixture of both inhibited binding by 86%. Our data suggest HK binding by interaction of the heavy-chain domain 3 with cytokeratin 1 and the light chain with gC1qR.

Interaction of Factor XII and high molecular weight kininogen with cytokeratin 1 and gC1qR of vascular endothelial cells and with aggregated Aβ protein of Alzheimer's disease

High molecular weight kininogen (HK) attaches to endothelial cells at separate sites on the heavy and light chains by a process which requires 15–50 μM zinc. Previously identified binding proteins include gC1qR, cytokeratin 1, and the urokinase plasminogen activator receptor (U-par), however, their relative contribution to binding are not yet clarified. We have purified the binding proteins by affinity chromatography, in the presence of zinc ion, and identified cytokeratin 1 and gC1qR by amino acid sequencing of an internal peptide and by immunoblot as heavy chain and light chain binding proteins, respectively. Antibody to cytokeratin 1 inhibited HK binding to endothelial cells by 30%, antibody to gC1qR inhibited HK binding to endothelial cells by 72%, and a mixture of both inhibited binding by 86%. The binding and activation of the proteins of the kinin-forming cascade along the cell surface is zinc-dependent. Similarly, proteins of the plasma kinin-forming cascade can be activated by binding to aggregated Aβ protein of Alzheimer's disease. Activation of the cascade using purified proteins or upon addition of Aβ to plasma requires aggregation of Aβ and the reactions are zinc-dependent. In plasma, HK is cleaved and bradykinin is liberated. The data demonstrate that aggregated Aβ can bind and activate proenzymes of the plasma kinin-forming cascade to release bradykinin and these reactions are dependent on zinc ion.

Mapping Binding Domains of Kininogens on Endothelial Cell Cytokeratin 1

Human cytokeratin 1 (CK1) in human umbilical vein endothelial cells (HUVEC) is expressed on their membranes and is able to bind high molecular weight kininogen (HK) (Hasan, A. A. K., Zisman, T., and Schmaier, A. H. (1998) Proc. Natl. Acad. Sci. U. S. A. 95, 3615-3620). New investigations have been performed to demonstrate the HK binding domain on CK1. Four overlapping recombinant (r) CK1 proteins were produced in Escherichia coli by a glutathione S-transferase gene fusion system. Biotin-HK specifically bound to rCK128 and rCK131 in the presence of Zn2+ but not to Deleted1-6rCK131. Recombinant CK128 and rCK131 also inhibited biotin-HK binding to HUVEC with IC50 of 0.4 and 0.5 microM, respectively. Alternatively, rCK114 and Deleted1-6rCK131 did not inhibit binding at concentrations >/=1 microM. Seven sequential 20 amino acid peptides of CK1 were prepared to cover the protein coded by exons 1-3. Only the first peptide (GYG20) coded by exon 1 significantly inhibited HK binding to HUVEC with an IC50 of 35 microM. Fine mapping studies isolated two overlapping peptides also coded by exon 1 (GPV15 and PGG15) that inhibited binding to HUVEC with IC50 of 18 and 9 microM, respectively. A sequence scrambled peptide of PGG15 did not block binding to HUVEC and biotin-GPV20 specifically bound to HK. Peptides GPV15 and PGG15 also blocked prekallikrein activation on endothelial cells. However, inhibition of PK activation by peptide PGG15 occurred at 10-fold lower concentration (IC50 = 1 microM) than inhibition of biotin-HK binding to HUVEC (IC50 = 10 microM). These studies indicate that HK binds to a region of 20 amino acids coded by exon 1 on CK1 which is carboxyl-terminal to its glycine-rich amino-terminal globular domain. Furthermore, HK binding to CK1 modulates PK activation on HUVEC.

Fourier Transform Infrared (FT-IR) Spectroscopic Studies of Peptide Models for Interaction of the Binding Regions of High Molecular Weight Kininogen and Prekallikrein

The binding sites for high molecular weight kininogen (HK) on prekallikrein (PK) are composed of two discontinuous segments in the primary sequence, one in Apple 1 domain (PK56=F56-G86) and the other in Apple 4 (PK266=K266-G295). The site on HK, HK31, is subsumed in a 31-amino-acid sequence (S565-K595) near the C-terminus which has the same affinity for prekallikrein as the entire HK molecule. The binding among them is likely due to conformational changes which serve to juxtapose the PK binding domain within HK with the HK binding site. Resolution-enhanced Fourier transform infrared spectroscopy (FT-IR) has been employed to analyze the contents of secondary structural elements of PK56 and HK31 and to reveal the possible specific binding portion and structural changes in HK31 and PK56 upon binding. From the amide I bands of their deconvoluted FT-IR spectra, it is known that PK56 contains no helix component, while HK31 has two different helical conformations. A quantitative comparison of the spectra of HK31, PK56 and their binding complex suggests that the conformation of 3 10-helix in HK31 has been changed to an α-helix, and one disordered segment of PK56 may have been changed to extended conformation. The other structural components in PK56 and HK31 remain unchanged. Since previous studies have shown that these peptides mimic the natural protein in their bioactivity, their interaction may reflect similar changes in the natural molecules.

Identification of cytokeratin 1 as a binding protein and presentation receptor for kininogens on endothelial cells.

A kininogen binding protein(s), a putative receptor, was identified on endothelial cells. A 54-kDa protein was isolated by a biotin-high molecular mass kininogen (HK) affinity column that, on aminoterminal sequencing of tryptic digests, was identified as cytokeratin 1. Multiple antibodies directed to cytokeratin 1 reacted with a 54-kDa band on immunoblot of lysates of endothelial cells. On laser scanning confocal microscopy, cytokeratin 1 antigen was found on the surface of endothelial cells. Cytokeratin 1 antigen also was detected on endothelial cell membranes by flow cytometry. Moreover, an antipeptide antibody to a sequence unique to cytokeratin 1 also specifically bound to nonpermeabilized endothelial cells. Biotin-HK specifically bound to cytokeratin only in the presence of Zn2+, and cytokeratin blocked biotin-HK binding to endothelial cells. Further, HK and low molecular mass kininogen, but not factor XII, blocked biotin-HK binding to cytokeratin, and peptides of each cell binding region of HK on domains 3,4, and 5 blocked biotin-HK binding to cytokeratin. gC1qR and soluble urokinase-like plasminogen activator receptor also inhibited biotin-HK binding to cytokeratin. These investigations identify a new function for cytokeratin 1 as a kininogen binding protein. Cytokeratins, members of the family of intermediate filament proteins, may represent a new class of receptors.

Identification of the zinc-dependent endothelial cell binding protein for high molecular weight kininogen and factor XII: identity with the receptor that binds to the globular "heads" of C1q (gC1q-R).

High molecular weight kininogen (HK) and factor XII are known to bind to human umbilical vein endothelial cells (HUVEC) in a zinc-dependent and saturable manner indicating that HUVEC express specific binding site(s) for those proteins. However, identification and immunochemical characterization of the putative receptor site(s) has not been previously accomplished. In this report, we have identified a cell surface glycoprotein that is a likely candidate for the HK binding site on HUVECs. When solubilized HUVEC membranes were subjected to an HK-affinity column in the presence or absence of 50 microM ZnCl2 and the bound membrane proteins eluted, a single major protein peak was obtained only in the presence of zinc. SDS/PAGE analysis and silver staining of the protein peak revealed this protein to be 33 kDa and partial sequence analysis matched the NH2 terminus of gC1q-R, a membrane glycoprotein that binds to the globular "heads" of C1q. Two other minor proteins of approximately 70 kDa and 45 kDa were also obtained. Upon analysis by Western blotting, the 33-kDa band was found to react with several monoclonal antibodies (mAbs) recognizing different epitopes on gC1q-R. Ligand and dot blot analyses revealed zinc-dependent binding of biotinylated HK as well as biotinylated factor XII to the isolated 33-kDa HUVEC molecule as well as recombinant gC1q-R. In addition, binding of 125I-HK to HUVEC cells was inhibited by selected monoclonal anti-gC1q-R antibodies. C1q, however, did not inhibit 125I-HK binding to HUVEC nor did those monoclonals known to inhibit C1q binding to gC1q-R. Taken together, the data suggest that HK (and factor XII) bind to HUVECs via a 33-kDa cell surface glycoprotein that appears to be identical to gC1q-R but interact with a site on gC1q-R distinct from that which binds C1q.

A Binding Site for Thrombin in the Apple 1 Domain of Factor XI

Previously we defined a binding site for high molecular weight kininogen (HK) in the A1 domain of factor XI (FXI). Since thrombin can activate FXI and HK inhibits the activation of FXI by thrombin, we have identified a thrombin binding site in FXI. Both the recombinant A1 domain (Glu1-Ser90) and a synthetic peptide (Phe56-Ser86) containing the HK binding site inhibited FXI activation by thrombin. Both a monoclonal antibody, 5F7, recognizing the A1 domain, and the rA1 domain were shown to be competitive inhibitors of thrombin-catalyzed FXI activation. The peptides Ala45-Arg54 and Val59-Arg70 acted synergistically to inhibit FXI activation by thrombin. Mutant rA1 domain constructs (Val64 --> Ala and Ile77 --> Ala), which do not inhibit FXI binding to HK, retain full capacity to inhibit FXI activation by thrombin. The peptide Ala45-Arg54 inhibited thrombin-catalyzed FXI activation, whereas it had no effect on FXI binding to HK. In contrast, the peptide Asn72-Leu83 (which inhibited FXI binding to HK) did not inhibit FXI activation by thrombin. Thus, a thrombin binding site exists in the A1 domain of FXI spanning residues Ala45-Arg70 that is contiguous with but separate and distinct from the HK binding site. These sites may regulate which ligand is bound to FXI and through which pathway FXI is activated.

Direct evidence for multifacial contacts between high molecular weight kininogen and plasma prekallikrein.

HK31 (S565-K595) has previously been shown to encompass the binding domain for plasma prekallikrein (PK) within domain 6 of high molecular weight kininogen (HK). The complementary binding domain for HK within PK is mapped to PK56 (F56-G86), in the apple 1 domain, and to PK266 (K266-C295), in the apple 4 domain. Isothermal titration calorimetry was used to directly monitor binding among HK31, PK56, and PK266. Either PK peptide binds to HK31 in 1:1 stoichiometry, regardless of whether a binary complex is first formed between PK266 and HK31 or between PK56 and HK31. Binding of the alternate PK peptide into a ternary complex is facilitated nearly 2-fold. The ternary complex consists of 1:1:1 HK31:PK56:PK266. Furthermore, binary and ternary complex formation is entropically driven and thermodynamically favored, suggesting that the conformational changes accompany binding. Fluorescence emission spectroscopy revealed that binding of PK56 caused a limited decrease in intrinsic tryptophan fluorescence emission intensity of HK31 while binding of PK266 to HK31 or the complex of HK31/PK56 had no such effect. We conclude that the two PK peptides bind to the HK peptide at different sites. The binding between HK and PK is likely due to conformational changes which serve to juxtapose the PK binding domain within HK with the HK binding site involving two spatial proximity segments.

High molecular weight kininogen binds to Mac-1 on neutrophils by its heavy chain (domain 3) and its light chain (domain 5).

High molecular weight kininogen (HK) binds specifically, saturably, and reversibly to neutrophils and also reciprocally inhibits the binding of fibrinogen to neutrophils. Since fibrinogen binds to the leukocyte integrin CD11b/18 (Mac-1, alpha M beta 2), we investigated whether HK bound to Mac-1 and whether the binding site was similar to that for factor X. We also examined whether one or both chains of cleaved HK (HKa) were involved. Two monoclonal antibodies, 2B5 (0.29 microM) to HK heavy chain domains 2 (D2) and 3 (D3), and C11C1 (0.26 microM) to HK light chain domain 5 (D5), inhibited by 99 and 93% the binding, respectively, of 125I-HK (8.3 nM) to neutrophils. To minimize steric hindrance, we further demonstrated that the Fab' fragments of 2B5 and C11C1 were able to inhibit the binding of this ligand to virtually the same extent as the intact antibody, indicating that, as in binding of HK to platelets and endothelial cells, both chains are involved. To directly demonstrate the involvement of each chain, we showed that the reduced alkylated light chain derived from HK and low molecular weight kininogen, which contains the same heavy chain as HK, each markedly inhibited the binding of HK to neutrophils. We localized the domain responsible for the binding in each chain by showing that recombinant D3 and D5 decreased the binding of HK to neutrophils. To define the receptor for HK, we employed three monoclonal antibodies to Mac-1: OKM1 and OKM10 to epitopes on the alpha M subunit and IB4 to an epitope on the beta 2 chain. OKM1, which can inhibit fibrinogen binding to neutrophils, inhibited HK binding by 79%, whereas the other antibodies inhibited HK binding less than 25%. Coagulation factor X also binds to Mac-1 on monocytes at a similar site to C3bi. Synthetic peptides which define noncontiguous surface loops in factor X that interact with Mac-1, failed to inhibit 125I-HK binding to neutrophils. We conclude that HK binds, via domains on its heavy chain, D3, and light chain, D5, to Mac-1 on the neutrophil surface, and HK occupies a site overlapping with fibrinogen and different from factor X.

Interaction of high molecular weight kininogen with plasminogen inhibits binding of plasminogen to cell surfaces

Recent studies have shown that high molecular weight kininogen (HK) inhibits the binding of plasmin to platelets and thereby inhibits platelet activation by plasmin. We hypothesized that these results might be explained by HK binding to plasmin(ogen) in solution. Using ligand blotting, we showed that 125I-plasminogen (Pg) binds to immobilized HK and that 125I-HK binds to immobilized Pg. HK partially inhibited 125I-Pg binding to lysine-Sepharose. Non-covalent binding of HK to Pg in solution was demonstrated using the cross-linking agent, bis(sulfosuccinimidyl)suberate (BS 3) . The cross-linking agent stabilized a 180kDa complex as determined by SDS-PAGE. The 180kDa complex was not observed in the absence of BS 3 or when ϵ-amino caproic acid was added. In addition, excess unlabelled Pg or HK inhibited the binding of each radiolabelled protein to the other. The equilibrium dissociation constant (K D) for the binding of Pg to HK in solution was 0.8 μmol/L, as determined by BS 3 cross-linking. Binding of Pg to C6 glioma cells in culture was inhibited by HK in a concentration-dependent manner with an IC 50 of approximately 0.4 μmol/L. Similar inhibition was observed using human umbilical vein endothelial cells (IC 50≈0.5 μmol/L). Binding of 125I-HK to C6 glioma cells was apparently saturable, zinc-dependent and inhibited by Pg (IC 50≈0.9 μmol/L). The results presented here suggest that HK inhibits Pg binding to cell surfaces primarily by forming a complex with Pg in solution. Pg binding to HK may affect the localization of these proteins in the vascular compartment.

Bradykinin regulates the expression of kininogen binding sites on endothelial cells

The vasoactive compound bradykinin (BK) is liberated by proteolytic cleavage from high molecular weight kininogen (HK) and low molecular weight kininogen (LK). Expression of kininogens on cell surface receptors may affect the delivery of BK at sites of inflammation. Therefore, we investigated whether BK itself alters the expression of binding sites for its parent molecules, HK and LK, on the surface of cultured human umbilical vein endothelial cells (HUVEC). 125I-LK and 125I-HK each bind to a single class of sites on HUVEC in reactions that are saturable, reversible, and zinc-dependent (Bmax = 9.7 +/- 0.2 x 10(5) sites/cell; kd = 43.3 +/- 8 nmol/L; n = 5 and Bmax = 10.3 +/- 0.4 x 10(5) sites/cell; kd = 40.3 +/- 0.9 nmol/L; n = 3 for LK and HK, respectively). HK and LK compete for the same binding site (Ki = 19.4 +/- 5 nmol/L HK v 125I-LK; Ki = 24.5 +/- 4 nmol/L LK v 125I-HK, n = 3). Moreover, 50-fold molar excess light chain of HK inhibits 125I-LK binding 51% and 50-fold molar excess LK and the heavy chain of HK inhibit 125I-light chain of HK binding 92% and 76%, respectively. Preincubation of HUVEC with BK produces a transient, concentration- dependent increase in the binding of HK and LK, reaching a maximum 3 to 4 hours after addition of BK (46% increase over control for HK; 57% increase over control for LK; P < .005 for each ligand). Des-Arg9- bradykinin, a B1 receptor agonist, increases kininogen binding to the same extent as BK; the upregulation of kininogen binding sites by BK is partially blocked by a B1 but not by a B2 receptor antagonist. The protein kinase C inhibitors (PKC), sphingosine and H7, completely block the induction of HK receptors by BK. Phorbol 12-myristate 13-acetate (PMA), which also activates PKC, stimulates the binding of HK and the purified light chain of HK to HUVEC as well. However, unlike HK and its light chain, binding of LK and the heavy chain of HK are increased by PMA only in the presence of added calcium ion. These studies show that BK upregulates a common binding site for HK, LK, and each chain of HK on HUVEC. Induction of kininogen receptors on endothelial cells by BK may modulate the generation of this vasoactive compound at sites of vascular injury.

Bradykinin Regulates the Expression of Kininogen Binding Sites on Endothelial Cells

The vasoactive compound bradykinin (BK) is liberated by proteolytic cleavage from high molecular weight kininogen (HK) and low molecular weight kininogen (LK). Expression of kininogens on cell surface receptors may affect the delivery of BK at sites of inflammation. Therefore, we investigated whether BK itself alters the expression of binding sites for its parent molecules, HK and LK, on the surface of cultured human umbilical vein endothelial cells (HUVEC). 125I-LK and 125I-HK each bind to a single class of sites on HUVEC in reactions that are saturable, reversible, and zinc-dependent (Bmax = 9.7 +/- 0.2 x 10(5) sites/cell; kd = 43.3 +/- 8 nmol/L; n = 5 and Bmax = 10.3 +/- 0.4 x 10(5) sites/cell; kd = 40.3 +/- 0.9 nmol/L; n = 3 for LK and HK, respectively). HK and LK compete for the same binding site (Ki = 19.4 +/- 5 nmol/L HK v 125I-LK; Ki = 24.5 +/- 4 nmol/L LK v 125I-HK, n = 3). Moreover, 50-fold molar excess light chain of HK inhibits 125I-LK binding 51% and 50-fold molar excess LK and the heavy chain of HK inhibit 125I-light chain of HK binding 92% and 76%, respectively. Preincubation of HUVEC with BK produces a transient, concentration-dependent increase in the binding of HK and LK, reaching a maximum 3 to 4 hours after addition of BK (46% increase over control for HK; 57% increase over control for LK; P < .005 for each ligand). Des-Arg9-bradykinin, a B1 receptor agonist, increases kininogen binding to the same extent as BK; the upregulation of kininogen binding sites by BK is partially blocked by a B1 but not by a B2 receptor antagonist. The protein kinase C inhibitors (PKC), sphingosine and H7, completely block the induction of HK receptors by BK. Phorbol 12-myristate 13-acetate (PMA), which also activates PKC, stimulates the binding of HK and the purified light chain of HK to HUVEC as well. However, unlike HK and its light chain, binding of LK and the heavy chain of HK are increased by PMA only in the presence of added calcium ion. These studies show that BK upregulates a common binding site for HK, LK, and each chain of HK on HUVEC. Induction of kininogen receptors on endothelial cells by BK may modulate the generation of this vasoactive compound at sites of vascular injury.

Insulin, growth factors, and cancer cell energy metabolism: an hypothesis on oncogene action.

The hexokinase-mitochondrial acceptor theory provides a model of insulin action which unifies the metabolic effects of this hormone and suggests that these result from insulin's stimulatory effect on mitochondrial ATP synthesis. There are similarities between these changes in cells exposed to insulin and in mitochondria of transformed cell lines and cancer cells, where an increased binding of hexokinase to mitochondria is observed. This phenomenon may play a key role in the high rates of glycolysis sustained by cancer cells under aerobic conditions. Structural and functional evidence support the hypothesis that certain growth factors and oncogenes act through stimulation of oxidative phosphorylation via promoting HK binding to mitochondria.

Domain 3 of kininogens contains a cell-binding site and a site that modifies thrombin activation of platelets.

High and low molecular weight kininogens (HK and LK) are able to bind to platelets to inhibit thrombin binding to and activation of platelets. The heavy chain domain on the kininogens that contains these functions has been determined. Domain 3 (D3) but not domains 1 or 2, completely inhibited 125I-HK binding to platelets (Ki = 24 +/- 7 nM, n = 4). 125I-D3 specifically bound to unstimulated platelets and human umbilical vein endothelial cells. On platelets, it was blocked by unlabeled D3 and HK but not prekallikrein, factor XII, C1s, or C1 inhibitor. Further, one monoclonal antibody (HKH13) directed to kininogens' D3 blocked 125I-HK and 125I-D3 binding to platelets. The binding of 125I-D3 to platelets was fully reversible by addition of 35 molar excess of unlabeled D3. D3 binding to platelets was saturable with an apparent Kd of 39 +/- 8 nM (n = 4) and 1227 +/- 404 binding sites/platelet. D3, like HK and LK, inhibited thrombin-induced platelet activation by preventing thrombin binding to platelets. Another monoclonal antibody (HKH12), directed to D3, which did not block HK binding to platelets, reduced HK's ability to inhibit 125I-alpha-thrombin binding. This result suggests that the region on D3 that inhibits 125I-alpha-thrombin binding to platelets is different from that which directly binds to platelets. These studies indicate that D3 of the kininogens contains both a binding region for platelets and endothelial cells and another region that inhibits thrombin-induced platelet activation.

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.