A monoclonal antibody that triggers deacylation of an intermediate thrombin-antithrombin III complex

Upon incubation of antithrombin III with thrombin in the presence of a monoclonal antibody recognizing an epitope exposed on the heavy chain part of thrombin-cleaved two-chain antithrombin III, antithrombin III was preferentially cleaved by the enzyme as a substrate, rather than covalently complexed with the enzyme to form an equimolar, stable acyl complex. Once the stable acyl complex was formed between the enzyme and antithrombin III, however, no further liberation of two-chain antithrombin III was observed. Kinetic studies showed that heparin does not affect this reaction, although generation of thrombin-cleaved two-chain antithrombin III is apparently accelerated in accordance with the rate constant for heparin-enhanced thrombin-antithrombin III complex formation. Here we propose the term "switching antibody" for an antibody that triggers deacylation of an intermediate enzyme-inhibitor complex by switching the enzyme-inhibitor reaction from the major pathway of stable acyl complex formation to an alternative pathway of cleavage of the inhibitor as a substrate.     

Association of thrombin-antithrombin III complex with vitronectin in serum

Purification of vitronectin by identical procedures from serum instead of plasma results in the coisolation of an additional protein component with mobility on sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) of 82 kDa. We show that this component is the thrombin-antithrombin III complex based on the following evidence. Similar to a complex constructed using purified thrombin and antithrombin III, the 82-kDa component has a reduced molecular size of 69 kDa if it is not boiled prior to SDS-PAGE. Upon prolonged boiling in SDS it dissociates into 56- and 32-kDa components which co-migrate in SDS-PAGE with purified antithrombin III and thrombin, respectively. The 82- and 56-kDa components react with an antiserum against antithrombin III, and an antiserum prepared against the 82-kDa complex reacts with purified antithrombin III. Thrombin-antithrombin III complex, from either serum or recalcified clotted plasma, bound to vitronectin immobilized on Sepharose or plastic. However, purified antithrombin III which had not reacted with thrombin lacked affinity for vitronectin as did antithrombin III from citrated plasma. Purified antithrombin III acquired affinity for immobilized vitronectin if it was complexed with thrombin or was modified by radioiodination. Binding of vitronectin to antithrombin III coated on plastic was demonstrated using enzyme-linked immunosorbent assay. These results demonstrate that vitronectin binds thrombin-antithrombin III complexes through a cryptic site in antithrombin III which can be exposed when antithrombin III is radioiodinated, bound to plastic, or complexed with thrombin. Since vitronectin can interact with cells, the binding of vitronectin to the thrombin-antithrombin III complex may serve to facilitate the interaction of this complex with cell surfaces.     

Association of thrombin, plasmin, thrombin-antithrombin III complex and plasmin-antithrombin III complex with isolated hepatocytes

The interaction of thrombin, plasmin or their antithrombin III complexes with isolated mouse hepatocytes was studied. Plasmin bound to hepatocytes in a concentration-dependent manner with an apparent Kd of 6.4.10(-8) M, attaining equilibrium within 10 min, and the interaction was inhibited by 6-amino-n-hexanoic acid. Plasmin treated with diisopropylfluorophosphate (DFP) bound to the cells in similar way as the untreated form of the enzyme. Thrombin bound also to hepatocytes, in a concentration-dependent manner, with a Kd of 5.4.10(-8) M reaching a steady state after 180 min. Thrombin inactivated with DFP, however, was inhibited in its binding to these cells. These data suggest that, whereas the kringle domains of plasmin are responsible for the enzyme-cell interaction, the active center of thrombin may be involved in the binding of this enzyme to hepatocytes. Plasmin-antithrombin III and thrombin-antithrombin III complexes were also associated with hepatocytes in a time-dependent manner, reaching a plateau after 180 min, and the two complexes competed in the interaction. While the interaction of active proteinases plasmin or thrombin with hepatocytes did not result in their internalization, the antithrombin III complexes were taken up by the cells, and thrombin-antithrombin III complex was degraded. These results indicate that hepatocytes may participate in the elimination of proteinase-antithrombin III complexes from the plasma, while the association of plasmin and thrombin with hepatocytes could imply distinct biological importance.     

Preparation and characterization of monolconal antibodies against the human thrombin-antithrombin III complex

Monoclonal antibodies were raised against human thrombin-antithrombin III complex by a hybridoma technique. Among them, five monoclonal antibodies, designated as JITAT-4, -14, -16, -17 and -19, were found to react with thrombin-antithrombin III, but not with its nascent components, α-thrombin or antithrombin III. Their respective immunoglobulin classes are IgG₁ for JITAT-16 and -19, and IgG_2a for JITAT-4, -14 and -17. Besides the thrombin-antithrombin III complex, they all bound to the Factor Xa-antithrombin III complex and the active-site-cleaved two-chain antithrombin III as well. Moreover, the reactivity of these two antibodies to the neoantigens was not affected by heparin, suggesting that their epitopes are independent of heparin-induced conformational changes of antithrombin III. Two of them, JITAT-16 and -17, were categorized as high-affinity antibodies to thrombin-antithrombin III complex, the dissociation constants being 6.7 nM and 4.8 nM, respectively. However, they do not share antigenic determinants. These monoclonal antibodies may allow us to explore more precisely the reaction between antithrombin III and thrombin or its related enzymes.     

Effect of rabbit thrombomodulin on the inhibition of thrombin by the antithrombin-heparin complex: role of the acid domain of thrombomodulin

Acidic and non-acidic forms of rabbit thrombomodulin were studied with regard to their effects on the inhibition of thrombin by antithrombin in the presence of exogenous heparin. The non acidic form was obtained by proteolytic cleavage of a polyanionic component (presumably a sulfated polysaccharide) from the parent acidic form of thrombomodulin, and purified by ion-exchange chromatography. It was previously found that the acidic form of thrombomodulin increases the rate of thrombin inactivation by antithrombin. The present study showed that thrombin bound to acidic thrombomodulin was inactivated at a lower rate by antithrombin in the presence of exogenous heparin than was free thrombin or thrombin bound to the non-acidic form of thrombomodulin. The data suggest that the acidic component of thrombomodulin is primarily responsible for the retardation of thrombin-antithrombin complex formation in the presence of exogenous heparin. It is proposed that the polyanionic component of thrombomodulin blocks a site on thrombin required for heparin binding, thus rendering the antithrombin-heparin complex ineffective.     

Probing the heparin-binding domain of human antithrombin III with V8 protease

From structural analysis on genetically abnormal and chemically modified human antithrombin III [Koide, T., Odani, S., Takahashi, K., Ono, T. and Sakuragawa, N. (1984) Proc. Natl Acad. Sci. USA 81, 289-293; Chang, J.-Y. and Tran, T. H., (1986) J. Biol. Chem. 261, 1174-1176; Blackburn, M. N., Smith, R. L., Carson, J. and Sibley, C. C. (1984) J. Biol. Chem. 259, 939-941], the heparin-binding site of antithrombin III has been suggested to be in the region of Pro-41, Arg-47 and Trp-49. In this study the heparin-binding site was probed by preferential cleavage of V8 protease on heparin-treated and non-treated native antithrombin III. The study has been based on the presumption that the heparin-binding site of antithrombin III is situated at exposed surface domain and may be preferentially attacked during limited proteolytic digestion. Partially digested antithrombin III samples were monitored by quantitative amino-terminal analysis and amino acid sequencing to identify the preferential cleavage sites. 1-h-digested antithrombin III was separated on HPLC and peptide fragments were isolated and characterized both qualitatively and quantitatively. The results reveal that Glu-Gly (residues 34-35), Glu-Ala (residues 42-43) and Glu-Leu (residues 50-51) are three preferential cleavage sites for V8 protease and their cleavage, especially the Glu-Ala and the Glu-Leu sites, was drastically inhibited when antithrombin III was preincubated with heparin. Both high-affinity and low-affinity antithrombin-III-binding heparins were shown to inhibit the V8 protease digestion of native antithrombin III, but the high-affinity sample exhibited a higher inhibition activity than the low-affinity heparin. These findings (a) imply that the segment containing residues 34-51 is among the most exposed region of native antithrombin III and (b) support the previous conclusions that this region may play a pivotal role in the heparin binding.     

The N-terminal segment of antithrombin acts as a steric gate for the binding of heparin.

The binding of heparin causes a conformational change in antithrombin to give an increased heparin binding affinity and activate the inhibition of thrombin and factor Xa. The areas of antithrombin involved in binding heparin and stabilizing the interaction in the high-affinity form have been partially resolved through the study of both recombinant and natural variants. The role of a section of the N-terminal segment of antithrombin, residues 22-46 (segment 22-46), in heparin binding was investigated using rapid kinetic analysis of the protein cleaved at residues 29-30 by limited proteolysis with thermolysin. The cleaved antithrombin had 5.5-fold lowered affinity for heparin pentasaccharide and 1.8-fold for full-length, high-affinity heparin. It was shown that, although the initial binding of heparin is slightly enhanced by the cleavage, it dissociates much faster from the cleaved form, giving rise to the overall decrease in heparin affinity. This implies that the segment constituting residues 22-46 in the N terminus of antithrombin hinders access to the binding site for heparin, hence the increased initial binding for the cleaved form, whereas, when heparin is bound, segment 22-46 is involved in the stabilization of the binding interaction, as indicated by the increased dissociation constant. When the heparin pentasaccharide is bound to antithrombin prior to incubation with thermolysin, it protects the N-terminal cleavage site, implying that segment 22-46 moves to interact with heparin in the conformational change and thus stabilizes the complex.     

Role of heparin and heparinlike molecules in thrombosis and atherosclerosis

Antithrombin is a protease inhibitor that neutralizes the activity of the serine proteases of the coagulation cascade, such as factors IXa, Xa, XIa, XIIa, and thrombin by forming a 1:1 stoichiometric complex between enzyme and inhibitor via a reactive site (arginine)-active center (serine interaction). Heparin binds to lysyl residues on antithrombin and accelerates the rate of complex formation. Studies of the binding parameters and kinetic characteristics of the heparin-antithrombin-hemostatic enzyme interactions have revealed that binding of heparin to antithrombin is responsible for a approximately 1000-fold acceleration of the thrombin-antithrombin or factor IXa-antithrombin and factor Xa-antithrombin interactions (allosteric effect). The reactions between free thrombin or free factor IXa and heparin provide an additional 4- to 15-fold enhancement in the rate of these processes (approximation effect) and account for 1-2% of the total rate of enhancement. It has been shown that commercial heparin is composed of anticoagulantly active and anticoagulantly inactive species. The anticoagulantly active mucopolysaccharide contains a unique antithrombin-binding site. Anticoagulantly inactive heparin does not possess this structure and does not bind to the protease inhibitor. Anticoagulantly active heparin also contains a critical region required for the acceleration of the various enzyme-inhibitor interactions. The two different domains of the heparin molecule interact with separate areas of antithrombin and induce distinct conformational transitions within the protease inhibitor. Anticoagulantly active heparinlike molecules (most likely a heparan sulfate with an appropriate sequence for anticoagulant activity) are found on the luminal surface of the endothelium. This heparinlike substance appears to alter the conformation of antithrombin in a manner virtually identical to that of commercial heparin. Both anticoagulantly active heparin and inactive heparin are able to suppress smooth muscle cell proliferation in vitro and in vivo and can reverse the effects of mitogenic factors such as platelet-derived growth factor. Furthermore, it has been shown that bovine aortic endothelial cells produce heparinlike molecules with growth inhibitory potency.     

Anticoagulant activities of a monoclonal antibody that binds to exosite II of thrombin.

A monoclonal IgG isolated from a patient with multiple myeloma has been shown to bind to exosite II of thrombin, prolong both the thrombin time and the activated partial thromboplastin time (aPTT) when added to normal plasma, and alter the kinetics of hydrolysis of synthetic peptide substrates. Although the IgG does not affect cleavage of fibrinogen by thrombin, it increases the rate of inhibition of thrombin by purified antithrombin approximately 3-fold. Experiments with plasma immunodepleted of antithrombin or heparin cofactor II confirm that prolongation of the thrombin time requires antithrombin. By contrast, prolongation of the aPTT requires neither antithrombin nor heparin cofactor II. The IgG delays clotting of plasma initiated by purified factor IXa but has much less of an effect on clotting initiated by factor Xa. In a purified system, the IgG decreases the rate of activation of factor VIII by thrombin. These studies indicate that binding of a monoclonal IgG to exosite II prolongs the thrombin time indirectly by accelerating the thrombin-antithrombin reaction and may prolong the aPTT by interfering with activation of factor VIII, thereby diminishing the catalytic activity of the factor IXa/VIIIa complex.     

Mechanism of action of heparin through thrombin on blood coagulation.

It has been suggested that heparin can affect blood coagulation through thrombin, i.e. the binding of heparin to thrombin induces a conformational change in the enzyme, facilitating a complex formation between thrombin and antithrombin (Machovich, T., Blaskó, Gy. and Pálos, L. (1975) Biochim. Biophys. Acta 379, 193-200). This hypothesis seems to have been proved. Modification of arginine residues in thrombin did not result in decreased thrombin activity and decreased sensitivity to antithrombin, whereas the heparin sensitivity of the enzyme and the thrombin-antithrombin reaction were diminished.     

Reconstitution of enzymatic activity by the association of the cap and catalytic domains of human topoisomerase I

When human topoisomerase I binds DNA, two opposing lobes in the enzyme, the cap region (amino acid, residues 175-433) and the catalytic domain (Deltacap, residues 433 to the COOH terminus) clamp tightly around the DNA helix to form the precleavage complex. Although Deltacap contains all of the residues known to be important for catalysis and binds DNA with an affinity similar to that of the intact enzyme, this fragment lacks catalytic activity. However, a mixture of Deltacap and topo31 (residues 175-433) reconstitutes enzymatic activity as measured by plasmid DNA relaxation and suicide cleavage assays. Although the formation of an active complex between topo31 and Deltacap is too unstable to be detected by pull-down experiments even in the presence of DNA, the association of topo31 with Deltacap persists and is detectable after the complex catalyzes the covalent attachment of the DNA to Deltacap by suicide cleavage. Removal of topo31 from Deltacap-DNA after suicide cleavage reveals that, unlike the cleavage reaction, religation does not require the cap region of the protein. These results suggest that activation of the catalytic domain of the enzyme for cleavage requires both DNA binding and the presence of the cap region of the protein.     

Effect of Thermus thermophilus elongation factor Ts on the conformation of elongation factor Tu

Affinity labeling in situ of the Thermus thermophilus elongation factor Tu (EF-Tu) nucleotide binding site was achieved with periodate-oxidized GDP (GDPoxi) or GTP (GTPoxi) in the absence and presence of elongation factor Ts (EF-Ts). Lys52 and Lys137, both reacting with GDPoxi and GTPoxi, are located in the nucleotide binding region. In the absence of EF-Ts Lys137 and to a lesser extent Lys52 were accessible to the reaction with GTPoxi. GDPoxi reacted much more efficiently with Lys52 than with Lys137 under these conditions [Peter, M. E., Wittman-Liebold, B. & Sprinzl, M. (1988) Biochemistry 27, 9132-9138]. In the presence of EF-Ts, GDPoxi reacted more efficiently with Lys137 than with Lys52, indicating that the interaction of EF-Ts with EF-Tu.GDPoxi induces a conformation resembling that of the EF-Tu.GDPoxi complex in the absence of EF-Ts. Binding of EF-Ts to EF-Tu.GDP enhances the accessibility of the Arg59-Gly60 peptide bond of EF-Tu to trypsin cleavage. Hydrolysis of this peptide bond does not interfere with the ability of EF-Ts to bind to EF-Tu. EF-Ts is protected against trypsin cleavage by interaction with EF-Tu.GDP. High concentrations of EF-Ts did not interfere significantly with aminoacyl-tRNA.EF-Tu.GTP complex formation.     

Hydrophobic residues 382-386 of antithrombin III, Ala-Ala-Ala-Ser-Thr, serve as the epitope for an antibody which facilitates hydrolysis of the inhibitor by thrombin.

In the presence of a monoclonal antibody raised against the human thrombin-antithrombin III complex, the reaction between thrombin and antithrombin III proceeded to form preferentially a two-chain form of the inhibitor rather than to follow the major pathway of stable acyl complex formation. We thus propose the term "switching antibody" for an antibody that switches the enzyme-inhibitor reaction (Asakura, S., Matsuda, M., Yoshida, N., Terukina, S., and Kihara, H. (1989) J. Biol. Chem. 264, 13736-13739). By analyzing a CNBr fragment of the thrombin-antithrombin III complex that reacts with the antibody we localized the epitope for the antibody to a strongly hydrophobic residue 382-386 peptide segment, Ala-Ala-Ala-Ser-Thr, of the inhibitor, which is also contiguous with a hydrophobic amino acid Ala at its carboxyl terminus. This particular region should be cryptic in nascent antithrombin III, but could have been exposed to provide the reactive site for the antibody at an early stage of the reaction. Thereby a conformational change may have been induced at or near the reactive site of the complex, facilitating hydrolysis of the inhibitor by the enzyme. Interestingly, this hydrophobic region is highly conserved among members of the serpin family.     

Monoclonal antibodies against antithrombin III. Identification of their epitopes and effects on antithrombin III activities

Four monoclonal antibodies with distinct epitopes were prepared against antithrombin III. None of them is directed against the heparin-binding region nor the active site, yet two mAb namely A36 and B108, interfere with antithrombin III inhibition of thrombin. The epitope of monoclonal antibody A36 is located within amino acid residues 1-393, at a site different from the active site since it recognizes antithrombin III and antithrombin-III-thrombin complexes with the same affinity. A36 partially prevents the intrinsic antithrombin III activity and has no effect on the heparin-enhanced antithrombin III activity when added to the antithrombin-III--heparin complex. If A36 is first reacted with antithrombin III and then heparin is added to the reaction mixture, A36 fixes the conformation of antithrombin III so that heparin binds to antithrombin III, but is not able to induce the conformational change in the antithrombin III molecule required for the enhanced activity. The epitope for monoclonal antibody B108 is located within residues 282-393, close to the active site. It does not recognize antithrombin-III-thrombin complexes by solid-phase radioimmunoassay. Its binding to antithrombin III induces a conformational change that enhances antithrombin III activity in a manner that resembles the heparin effect, but its effect is additive to the heparin effect, since when it was added to a reaction mixture which contained a saturating amount of heparin, inhibition of thrombin was enhanced. The epitope for monoclonal antibody A5 is located within residues 1-393, and its recognition of antithrombin III or antithrombin-III-thrombin is strongly dependent on the integrity of the disulfide bonds. A5 has no effect on antithrombin III activities. The epitope for monoclonal antibody A10 is well defined within a narrow range of 55 amino acid residues, 339-393, on the antithrombin III molecule, close to the active site, yet it has no effect on antithrombin III inhibitory activity. These monoclonal antibodies may be developed for various diagnostic or clinical purposes and offer a powerful tool for studying the conformational changes and structure/activity relationships in the antithrombin III molecule.     

Conformational changes accompanying the binding of antithrombin III to thrombin.

The conformational aspects of the binding of antithrombin III to thrombin were investigated by difference spectroscopy, circular dichroism, and optical rotatory dispersion. The CD and ORD studies indicate an increase of 6--8% in alpha-helix content at the expense of the beta structure, while the results from difference spectroscopy showed an increased exposure of approximately seven tyrosine residues. In the presence of heparin there is a slightly greater increase in helicity which is accompanied by exposure of an average of two tryptophan and one tyrosine residues. These spectral results indicate that the thrombin-antithrombin III complex formed in the presence of heparin differs in its conformation from that produced in its absence.     

Mutagenesis studies toward understanding the mechanism of the cofactor function of thrombomodulin

Thrombomodulin (TM) is as essential cofactor in protein C activation by thrombin. To investigate the cofactor effect of TM on the P3-P3' binding specificity of thrombin, we prepared a Gla-domainless protein C (GDPC) and an antithrombin (AT) mutant in which the P3-P3' residues of both molecules were replaced with the corresponding residues of the factor Xa cleavage site in prethrombin-2. TM is known to interact with GDPC, but not AT in the complex. Thrombin did not react with either mutant in the absence of a cofactor. While the thrombin-TM complex also did not react with the AT mutant, it activated the GDPC mutant with a normal k(cat), but an approximately 4-fold impaired K(m) value. Further studies revealed that the active-site directed inhibitor p-aminobenzamidine acts as a competitive inhibitor of both wild-type and GDPC mutant in reaction with the thrombin-TM complex. These results suggest that the interaction of the P3-P3' residues of GDPC with the active-site pocket of the thrombin-TM complex makes a dominant contribution to the binding specificity of the reaction. Moreover, the observation that the GDPC mutant, but not the AT mutant, functions as an effective substrate for the thrombin-TM complex suggests that GDPC interaction with the thrombin-TM complex may be associated with the alteration of the conformation of the P3-P3' residues of the substrate.     

Mitochondrial protein import: recognition of internal import signals of BCS1 by the TOM complex

BCS1, a component of the inner membrane of mitochondria, belongs to the group of proteins with internal, noncleavable import signals. Import and intramitochondrial sorting of BCS1 are encoded in the N-terminal 126 amino acid residues. Three sequence elements were identified in this region, namely, the transmembrane domain (amino acid residues 51 to 68), a presequence type helix (residues 69 to 83), and an import auxiliary region (residues 84 to 126). The transmembrane domain is not required for stable binding to the TOM complex. The Tom receptors (Tom70, Tom22 and Tom20), as determined by peptide scan analysis, interact with the presequence-like helix, yet the highest binding was to the third sequence element. We propose that the initial recognition of BCS1 precursor at the surface of the organelle mainly depends on the auxiliary region and does not require the transmembrane domain. This essential region represents a novel type of signal with targeting and sorting functions. It is recognized by all three known mitochondrial import receptors, demonstrating their capacity to decode various targeting signals. We suggest that the BCS1 precursor crosses the TOM complex as a loop structure and that once the precursor emerges from the TOM complex, all three structural elements are essential for the intramitochondrial sorting to the inner membrane.     

Sequences of the vesicular stomatitis virus matrix protein involved in binding to nucleocapsids.

The purpose of these experiments was to study the physical structure of the nucleocapsid-M protein complex of vesicular stomatitis virus by analysis of nucleocapsid binding by wild-type and mutant M proteins and by limited proteolysis. We used the temperature-sensitive M protein mutant tsO23 and six temperature-stable revertants of tsO23 to test the effect of sequence changes on M protein binding to the nucleocapsid as a function of NaCl concentration. The results showed that M proteins from wild-type, mutant, and three of the revertant viruses had similar NaCl titration curves, while the curve for M proteins from the other three revertants differed significantly. The altered NaCl dependence of M protein was correlated with a single amino acid substitution from Phe to Leu at position 111 compared with the original temperature-sensitive mutant and was not correlated with a substitution of Gly to Glu at position 21 in tsO23 and the revertants. To determine whether protease cleavage sites in the M protein were protected by interaction with the nucleocapsid, nucleocapsid-M protein complexes were subjected to limited proteolysis with trypsin, chymotrypsin, or Staphylococcus aureus V8 protease. The initial trypsin and chymotrypsin cleavage sites, located after amino acids 19 and 20, respectively, were as accessible to proteases when M protein was bound to the nucleocapsid as when it was purified, indicating that this region of the protein does not interact directly with the nucleocapsid. Furthermore, trypsin or chymotrypsin treatment released the M protein fragments from the nucleocapsid, presumably due to conformational changes following proteolysis. V8 protease cleaved the M protein at position 34 or 50, producing two distinct fragments. The M protein fragment produced by V8 protease cleavage at position 34 remained associated with the nucleocapsid, while the fragment produced by cleavage at position 50 was released from the nucleocapsid. These results suggest that the amino-terminal region of the M protein around amino acid 20 does not interact directly with the nucleocapsid and that conformational changes resulting from single-amino-acid substitutions at other sites in the M protein are important for this interaction.     

Periodic cleavage of poly(dA) by oligothymidylates covalently linked to the 1,10-phenanthroline-copper complex

1,10-Phenanthroline (OP) was covalently attached to the 3'-terminus of two oligothymidylates via different linkers [abbreviated as T8-(OP) and T6-(OP)]. In the presence of Cu2+ and 3-mercaptopropionic acid (MPA), these reagents induce a hybridization-dependent cleavage of poly(dA) and of a 27 nucleotide long oligodeoxynucleotide containing an A8 sequence. The principal cleavage sites on the 27-mer span four residues located near the 3'-terminal phosphate group of T8-(OP). When poly(dA) was degraded by T6-(OP) and T8-(OP), a series of bands were obtained corresponding to a repeat unit of six and eight nucleotides, respectively. This periodicity reflects the cooperative binding of oligothymidylate-OP to the polynucleotide matrix and the localized nicking sites.