Amino-terminal alanine functions in a calcium-specific process essential for membrane binding by prothrombin fragment 1

Two acetylation sites on prothrombin fragment 1 (amino-terminal 156 amino acid residues of bovine prothrombin) are essential for the tight calcium and membrane binding functions of the protein; calcium protects both of these sites from acetylation [Welsch, D. J., Pletcher, C. H., & Nelsestuen, G. L. (1988) Biochemistry (first of three papers in this issue)]. The epsilon-amino groups of the lysine residues (positions 3, 11, 44, 57, and 97) were not critical to protein function and were acetylated in the calcium-protected protein. The most reactive of the two essential acetylation sites was identified as amino-terminal alanine. To identify this site, fragment 1 was first acetylated in the presence of calcium to derivatize the nonessential sites. Removal of calcium and partial acetylation with radioactive reagent produced a single major radioactive peptide. Isolation and characterization of this peptide showed that the radioactivity was associated with amino-terminal alanine. In addition, sequence analysis of calcium-protected protein showed the presence of underivatized amino-terminal alanine. Surprisingly, covalent modification with a trinitrophenyl group did not alter membrane binding activity. Thus, the positive charge on the amino terminus did not appear critical to its function. Acetylation of amino-terminal alanine without acetylation of the second essential site produced a fragment 1 derivative which had a high requirement for calcium and which had lost most membrane binding function. However, this protein had only slightly altered affinity for magnesium ion. In agreement with this metal ion selectivity, protection of amino-terminal alanine was calcium specific, and magnesium ion did not protect this site from acetylation.(ABSTRACT TRUNCATED AT 250 WORDS)     

A metal ion-binding site in the kringle region of bovine prothrombin fragment 1.

45Ca(II) binding studies (equilibrium dialysis) on the kringle domain of bovine prothrombin fragment 1 were conducted using a mixture of peptides (residues 43-156 and 46-156) resulting from limited alpha-chymotryptic hydrolysis of fragment 1. Analysis of the Scatchard plot of these data indicates a single, low affinity Ca(II)-binding site to be present. Similar results were obtained from studies on the decarboxylated fragment 1 derivative, 10-gamma-MGlu-fragment 1. Acetylation of bovine fragment 1 in the absence of Ca(II) or Mg(II) ions results in the loss of the metal ion-promoted quenching of the intrinsic Trp fluorescence of the protein and the Ca(II)-mediated binding to phosphatidylserine/phosphatidylcholine (PS/PC) vesicles. The acetylation of the NH2 alpha-group of Ala-1 has been shown (Welsch, D. J., and Nelsestuen, G. L. (1988) Biochemistry 27, 4946-4952) to abolish the PS/PC binding property of fragment 1. The present study demonstrates that acetylation of a second site possibly Ser-79 or Thr-81 using the conditions described in the preceding paper results in loss of both the fluorescence transition and the Ca(II)-mediated PS/PC binding of the resulting protein derivative. Removal of the O-acetyl group at the Ser-79/Thr-81 site is accomplished by aminolysis with 0.2 M hydroxylamine, pH 10, 50 degrees C; the fluorescence transition is partially restored. PS/PC binding is partially restored if the NH2 alpha-group of Ala-1 is trinitrophenylated but is not restored if the NH2 alpha-group of Ala-1 is acetylated. We conclude that the Ser-79/Thr-81 site may represent a portion of the metal ion-binding site within the kringle domain of fragment 1. Occupancy of this site by a Ca(II) ion appears to be important in the binding of the protein to PS/PC vesicles.     

Protein structural requirements and properties of membrane binding by gamma-carboxyglutamic acid-containing plasma proteins and peptides

The membrane-binding characteristics of a number of modified vitamin K-dependent proteins and peptides showed a general pattern of structural requirements. The amino-terminal peptides from human prothrombin (residues 1-41 and 1-44, 60:40) bovine factor X (residues 1-44), and bovine factor IX (residues 1-42), showed a general requirement for a free amino-terminal group, an intact disulfide, and the tyrosine homologous to Tyr44 of factor X for membrane binding. Consequently, the peptide from factor IX did not bind to membranes. Any of several modifications of the amino terminus, except reaction with trinitrobenzenesulfonic acid, abolished membrane binding by the factor X and prothrombin peptides. Calcium, but not magnesium, protected the amino terminus from chemical modification. The requirement for a free amino terminus was also shown to be true for intact prothrombin fragment 1, factor X, and factor IX. Although aggregation of the peptide-vesicle complexes greatly complicated accurate estimation of equilibrium binding constants, results with the factor X peptide indicated an affinity that was not greatly different from that of the parent protein. The most striking difference shown by the peptides was a requirement for about 10 times as much calcium as the parent proteins. In a manner similar to the parent proteins, the prothrombin and factor X peptides showed a large calcium-dependent quenching of tryptophan fluorescence. This fluorescence quenching in the peptides also required about 10 times the calcium needed by the parent proteins. Thus, the 1-45 region of the vitamin K-dependent proteins contained most of the membrane-binding structure but lacked component(s) needed for high affinity calcium binding. Protein S that was modified by thrombin cleavage at Arg52 and Arg70 showed approximately the same behavior as the amino-terminal 45-residue peptides. That is, it bound to membranes with overall affinity that was similar to native protein S but required high calcium concentrations. These results suggested that the second disulfide loop of protein S (Cys47-Cys72) and prothrombin (Cys48-Cys61) were involved in high affinity calcium binding. Since factor X lacks a homologous disulfide loop, an alternative structure must serve a similar function. A striking property of protein S was dissociation from membranes by high calcium. While this property was shared by all the vitamin K-dependent proteins, protein S showed this most dramatically and supported protein-membrane binding by calcium bridging.     

Metal and phospholipid binding properties of partially carboxylated human prothrombin variants

To study the specific role of gamma-carboxyglutamic acid (Gla) residues in prothrombin, we have isolated a series of partially carboxylated prothrombin variants from a patient with a hereditary defect in vitamin K-dependent carboxylation (Goldsmith, G. H., Pence, R. E., Ratnoff, O. D., Adelstein, D. A., and Furie, B. (1982) J. Clin. Invest. 69, 1253-1260). The three variant prothrombins, purified by DEAE-Sephacel, immunoaffinity chromatography, and preparative gel electrophoresis, were indistinguishable from prothrombin in molecular weight, amino acid composition, and NH2-terminal amino acid sequence, with the exception of Gla residues. Variant prothrombin 1, with 8 Gla residues, had 66% of the coagulant activity of prothrombin, one high affinity metal-binding site (Kd = 15 nM), and three lower affinity sites (Kd = 2.7 microM); prothrombin contained two high affinity (36 nM) and four lower affinity sites (Kd = 1 microM). Ca(II) induced a 23% decrease in the intrinsic fluorescence of variant prothrombin 1 fragment 1, compared to a 35% decrease in that of prothrombin fragment 1. The phospholipid binding activity of variant prothrombin 1 was 44% that of prothrombin. Variant prothrombin 2 and variant prothrombin 3, with 4 and 6 Gla residues, respectively, had about 5% of prothrombin coagulant activity and a single high affinity and two lower affinity metal-binding sites and exhibited no phospholipid binding activity. Variant prothrombin 3 fragment 1 and variant prothrombin 2 fragment 1 demonstrated 18 and 13% of Ca(II)-induced fluorescence quenching, respectively. Abnormal prothrombin, with 1 Gla residue, had 8% of prothrombin coagulant activity, a single lower affinity (1 microM) metal-binding site, and 13% Ca(II)-induced fluorescence quenching of the fragment 1 species and did not bind to phospholipid. These results indicate that Gla residues define the metal binding properties of prothrombin. Most, if not all, of the Gla residues are required for complete prothrombin function, and the prothrombin coagulant activity correlates to the phospholipid binding activity of the prothrombin species.     

Deglycosylated prothrombin fragment 1. Calcium binding, phospholipid interaction, and self-assocation

The carbohydrate portion of prothrombin fragment 1 has been removed by fluorolysis in anhydrous HF. The deglycosylated protein retains its calcium- and membrane-binding properties. The slow, calcium-dependent protein transition monitored by changes in intrinsic protein fluorescence remains intact for the aglycoprotein. Calcium-dependent protein-membrane binding is also observed and can be quantitatively reversed with EDTA. The major alteration resulting from carbohydrate removal is the degree of protein self-association. Both the normal and deglycosylated proteins undergo a rapid self-association which approaches a dimer in the presence of calcium. This self-association is independent of the slow change in intrinsic fluorescence. The deglycosylated protein then undergoes a secondary self-association with kinetics identical with the fluorescence change. This secondary self-association also occurs on the membrane surface. This suggests that the calcium-dependent conformational change exposes a site on the protein which functions in secondary self-association. The carbohydrate apparently masks this site in the native molecule.     

Evidence for a common metal ion-dependent transition in the 4-carboxyglutamic acid domains of several vitamin K-dependent proteins

The murine monoclonal antibody H-11 binds a conserved epitope found at the amino terminal of the vitamin K-dependent blood proteins prothrombin, factors VII and X, and protein C. The sequence of polypeptide recognized by antibody H-11 contains 2 residues of gamma-carboxyglutamic acid, and binding of the antibody is inhibited by divalent metal ions. By using a solid-phase immunoassay with 125I-labeled antibody and immobilized vitamin K-dependent protein, binding of the antibody to the vitamin K-dependent proteins was inhibited by increasing concentrations of calcium, manganese, and magnesium ion. The transition midpoints for antibody binding were in the millimolar concentration range and were different for each metal ion. In general, the transition midpoints were lowest for manganese ion, intermediate for calcium ion, and highest for magnesium ion. Antibody H-11 bound specifically to a synthetic peptide corresponding to residues 1-12 of human prothrombin that was synthesized as the gamma-carboxyglutamic acid-containing derivative. Binding of the antibody to the peptide was not inhibited by calcium ion. These data suggest that inhibition of antibody H-11 binding by divalent metal ions is not due simply to neutralization of negative charge by Ca2+. This transition which is conserved in vitamin K-dependent proteins containing the H-11 antigenic site is likely due to a structural transition of the amino-terminal polypeptide possibly from a random (accessible) to ordered (inaccessible) structure.     

Metal ion binding to alpha-lactalbumin species

A strong cation (calcium) binding site has been demonstrated to exist in several alpha-lactalbumin species; bovine, goat, human, and guinea pig. A metal ion induced conformational change occurs, resulting in a unique (10-14-nm) blue shift and relative quenching of Trp fluorescence for all species. Calcium ion binding to the alpha-lactalbumins yielded dissociation constants (Kdiss consistently in the 10(-10)--10(-12) M range, while Mn(II) binding was in the 20-30 microM range. Independent determinations of these cation binding equilibria were made by ESR measurements of free unliganded Mn(II) in titrations with the bovine species. One strong site (Kdiss = 30.5 microM) was found, which correlated directly with the fluorescence-associated cation binding, plus three weaker sites (Kdiss = 1.1, 5.0, and 5.0 mM, respectively). Several lanthanides as well as Mg(II) were found to displace Mn(II) from the strong site on bovine alpha-lactalbumin (as monitored by ESR) and to cause the identical fluorescence changes as found for Ca(II) and Mn(II) above. The importance of measuring these equilibria by both fluorescence and ESR was borne out by demonstrating the potential errors in estimating dissociation equilibria by the fluorescence method alone. Also, the errors in estimating Kdiss for samples containing partially metal bound apo-alpha-lactalbumin are described as well as rapid, sensitive methods for estimating the extent of metal-free protein and correctly accounting for residual bound metal in equilibrium calculations.     

Extensive segregation of acidic phospholipids in membranes induced by protein kinase C and related proteins

Protein kinase C and two other proteins with molecular masses of 64 and 32 kDa, purified from bovine brain, constitute a type of protein that binds a large number of calcium ions in a phospholipid-dependent manner. This study suggested that these proteins also induced extensive clustering of acidic phospholipids in the membranes. Clustering of acidic phospholipids was detected by the self-quenching of a fluorescence probe that was attached to acidic phospholipids (phosphatidic acid or phosphatidylglycerol). Addition of these proteins to phospholipid vesicles containing 15% fluorescently labeled phosphatidic acid dispersed in neutral phosphatidylcholine resulted in extensive, rapid, and calcium-dependent quenching of the fluorescence signal. Fluorescence-quenching requirements coincided with protein-membrane binding characteristics. As expected, the addition of these proteins to phospholipid vesicles containing fluorescent phospholipids dispersed with large excess of acidic phospholipids produced only small fluorescence changes. In addition, association of these proteins with vesicles composed of 100% fluorescent phospholipids resulted in no fluorescence quenching. Protein binding to vesicles containing 5-50% fluorescent phospholipid showed different levels of fluorescence quenching that closely resemble the behavior expected for extensive segregation of the acidic phospholipids in the outer layer of the vesicles. Thus, the fluorescence quenching appeared to result from self-quenching of the fluorophores that become clustered upon protein-membrane binding. These results were consistent with protein-membrane binding that was maintained by calcium bridges between the proteins and acidic phospholipids in the membrane. Since each protein bound eight or more calcium ions in the presence of phospholipid, they may each induce clustering of a related number of acidic phospholipids.(ABSTRACT TRUNCATED AT 250 WORDS)     

Metal binding sites of a gamma-carboxyglutamic acid-rich fragment of bovine prothrombin.

The metal binding sites of a gamma-carboxyglutamic acid-rich fragment derived from bovine prothrombin were examined using paramagnetic lanthanide ions to evaluate the role of gamma-carboxyglutamic acid resideus in metal binding. A gamma-carboxyglutamic acid-rich peptide, fragment 12-44, was isolated from a tryptic digest of prothrombin. Using 153Gd(III), fragment 12-44 was found to contain one high affinity metal binding site (KD = 0.55 microM) and four to six lower affinity metal binding sites (KD approximately 4 to 8 microM). The S-carboxymethyl derivative of fragment 12-44, in which the disulfide bond in fragment 12-44 was reduced and alkylated, contained no high affinity metal binding site and four or five lower affinity sites (KD = 8 microM). The effects of paramagnetic lanthanide ions on fragment 12-44 and its S-carboxymethyl derivative were studied by natural abundance 13C NMR spectroscopy. The 13C NMR spectrum of fragment 12-44 was recorded at 67.88 MHz and the resonances were assigned by comparison to the chemical shift of carbon resonances of amino acids and peptides previously studied. The proximity between bound metal ions and carbon atoms in fragment 12-44 was estimated using Gd(III), based upon the strategy that the magnitude of the change in the transverse relaxation rate of resonances of carbon nuclei induced by bound metal ions is related in part to the interatomic distances between bound metal and carbon nuclei. Titration of fragment 12-44 with Gd(III) resulted in the selective broadening of the gamma-carboxyl carbon, C gamma, C beta, and C alpha resonances of gamma-carboxyglutamic acid, and the C epsilon of the arginines. S-Carboxymethyl fragment 12-44, which lacked the high affinity metal binding site, showed markedly decreased perturbation of the C epsilon of the arginine residues upon titration with Gd(III). These studies indicate that gamma-carboxyglutamic acid residues in prothrombin fragment 12-44 participate in metal liganding. A high affinity metal binding site in fragment 12-44 is in close proximity of Arg 16 and Arg 25 and is stabilized by the disulfide bond. On the basis of these data, a model of the metal binding sites is proposed in which the high affinity site is composed of two gamma-carboxyglutamic acid residues which participate in intramolecular metal-dependent bridging of two regions of the polypeptide chain. The lower affinity metal binding sites, formed by single or paired adjacent gamma-carboxyglutamic acid residues, then may participate in intermolecular metal-dependent protein . protein or protein . membrane complex formation.     

Interaction of vitamin K dependent proteins with membranes

The membrane-binding characteristics of six vitamin K dependent plasma proteins, which have homologous amino acid sequences, were compared. All of these proteins display calcium-dependent membrane binding and the identified equilibria for protein-membrane binding are qualitatively the same for all proteins. Quantitative characteristics of these protein-membrane interactions allow organization into distinct subgroups. Protein C and factor VII form a subgroup which has extemely low affinity for bilayer membranes; prothrombin, factor X, and protein S form the tightest complexes with membranes and factor IX displays intermediate affinity. In the presence of manganese (which substitutes for calcium in a cation-dependent protein transition), calcium titration of protein-membrane binding shows the same calcium dependence for all proteins except prothrombin which requires lower calcium. These protein-membrane binding characteristics agree very well with the relatedness of these proteins based on their partial amino-terminal sequences.     

X-ray structure of an unusual Ca2+ site and the roles of Zn2+ and Ca2+ in the assembly, stability, and storage of the insulin hexamer.

Metal ion binding to the insulin hexamer has been investigated by crystallographic analysis. Cadmium, lead, and metal-free hexamers have been refined to R values of 0.181, 0.172, and 0.172, against data of 1.9-, 2.5-, and 2.5-A resolution, respectively. These structures have been compared with each other and with the isomorphous two-zinc insulin. The structure of the metal-free hexamer shows that the His(B10) imidazole rings are arranged in a preformed site that binds a water molecule and is poised for Zn2+ coordination. The structure of the cadmium derivative shows that the binding of Cd2+ at the center of the hexamer is unusual. There are three symmetry-related sites located within 2.7 A of each other, and this position is evidently one-third occupied. It is also shown that the coordinating B13 glutamate side chains of this derivative have two partially occupied conformations. One of these conformations is two-thirds occupied and is very similar to that seen in two-zinc insulin. The other, one-third-occupied conformation, is seen to coordinate the one-third-occupied metal ion. The binding of Ca2+ to insulin is assumed to be essentially identical with that of Cd2+. Thus, we conclude that the Ca2+ binding site in the insulin hexamer is unlike that of any other known calcium binding protein. The crystal structures reported herein explain how binding of metal ions stabilizes the insulin hexamer. The role of metal ions in hexamer assembly and dissociation is discussed.     

The active site of membrane-bound meizothrombin. A fluorescence determination of its distance from the phospholipid surface and its conformational sensitivity to calcium and factor Va

The distance between the phospholipid surface and the active site of membrane-bound meizothrombin, a derivative of prothrombin, was determined directly using fluorescence energy transfer. The active site of prothrombin was exposed after a single cleavage by Echis carinatus protease in the presence of [5-(dimethylamino)-1-naphthalenesulfonyl]glutamylglycylarginyl+ ++ (DEGR) chloromethyl ketone to yield DEGR-meizothrombin and thereby minimize secondary proteolysis. When DEGR-meizothrombin was titrated with 80% phosphatidylcholine, 20% phosphatidylserine vesicles containing octadecylrhodamine, singlet-singlet energy transfer was observed between the donor dyes in the active sites of the membrane-bound proteins and the acceptor dyes at the outer surface of the phospholipid bilayer. This energy transfer required both Ca2+ and phosphatidylserine. Assuming k2 = 2/3, the dependence of the efficiency of energy transfer upon the acceptor density showed that the distance of closest approach between the active site probe and the bilayer surface was 71 +/- 2 A. In the presence of factor Va, the distance was 67 +/- 3 A. These direct measurements show that the active site of meizothrombin is located far above the membrane surface. Also, association of factor Va with meizothrombin on the phospholipid surface appears to cause a slight movement of the meizothrombin protease domain toward the membrane surface. The environment of the dansyl dye covalently attached to the active site of meizothrombin was particularly sensitive to the presence of calcium: addition of Ca2+ ions to metal-free DEGR-meizothrombin reduced the dansyl fluorescence lifetime from 11.7 to 9.0 ns and the dansyl emission intensity by 24%. Hence, the conformation of the active site changed when Ca2+ ions bound to meizothrombin. Since the intensity change was half-maximal at 0.2 mM and was also elicited by the binding of Mg2+ ions, this spectral change correlates with the calcium-dependent conformational change previously observed in fragment 1. We conclude, therefore, that the binding of Ca2+ ions to meizothrombin and, by extension, perhaps to prothrombin, elicits a conformational change that extends beyond the fragment 1 domains into the distant (cf. above) active site or protease domain. The association of factor Va with membrane-bound DEGR-meizothrombin increased both the dansyl emission intensity (by 7%) and polarization. This intensity change and the factor-Va dependent change in energy transfer indicate that the cofactor of the prothrombinase complex functions to modulate the conformation and orientation of both the substrate and the enzyme of the complex.     

Decarboxylation of bovine prothrombin fragment 1 and prothrombin

Bovine prothrombin fragment 1 and prothrombin undergo decarboxylation of their gamma-carboxyglutamic acid residues when the lyophilized proteins are heated in vacuo at 110 degrees C for several hours. The fully decarboxylated fragment 1 product has lost its barium-binding ability as well as the calcium-binding function which causes fluorescence quenching in the presence of 2 mM Ca2+. There is no sign of secondary structure alteration in solution upon analysis by fluorescence emission and circular dichroic spectroscopy. A family of partially decarboxylated fragment 1 species generated by heating for shorter periods shows that the initial decrease in calcium-binding ability occurs almost twice as rapidly as the loss of gamma-carboxyglutamic acid. This is consistent with the idea that differential functions can be ascribed to the 10 gamma-carboxyglutamic acid residues in fragment 1, including both high- and low-affinity metal ion binding sites. Prothrombin itself also undergoes total decarboxylation without any apparent alteration in secondary structure. However, in this case the latent thrombin activity is progressively diminished during the heating process in terms of both clotting activity and hydrolysis of the amide substrate H-D-Phe-Pip-Arg-pNA. The present results indicate that in vitro decarboxylation of gamma-carboxyglutamic acid in dried proteins is useful for analyzing the detailed calcium-binding proteins of vitamin K dependent coagulation factors.     

The activation of concanavalin A by lanthanide ions.

Divalent cadmium and lead and the trivalent lanthanides bind in the trasition metal site (S1) of concamavanlin A and induce saccharide binding to the protein in the presence of calcium. Partial activation of the protein in the presence of lanthanides alone indicates these ions bind into both transition metal (S1) and calcium sites (S2). The activity of a lanthanide-protein derivative may be increased by the addition of either calcium or a transition metal ion. The saccharide binding activity decreases in the order Zn2+ is greater than Ni2+ is greater than Co2+ is greater than Mn2+ is greater than Cd2+ reflecting the order of binding constants for these ions in the transition metal site. Like the lanthanides, divalent cadmium substitutes for both the transition metal ion and calcium ion to partially activate the protein. Divalent lead substitutes only for the transition metal ion and partially activates the protein upon addingcalcium. The data are consistent with a model in which saccharide binding activity is independent of the metal size in S1 but critically dependent upon metal size in S2.     

Gamma-carboxyglutamic acid

Summary Gamma-carboxyglutamic acid is an amino acid with a dicarboxylic acid side chain. This amino acid, with unique metal binding properties, confers metal binding character to the proteins into which it is incorporated. This amino acid has been discovered in blood coagulation proteins (prothrombin, Factor X, Factor IX, and Factor VII), plasma proteins of unknown function (Protein C, Protein S, and Protein Z), and proteins from calcified tissue (osteocalcin and bone-Gla protein). It has also been observed in renal calculi, atherosclerotic plaque, and the egg chorioallantoic membrane, among other tissues. Gamma-carboxyglutamic acid is synthesized by the post-translational modification of glutamic acid residues. This reaction, catalyzed by a hepatic carboxylase, requires reduced vitamin K, oxygen, and carbon dioxide. The function of -carboxyglutamic acid is uncertain. In prothrombin y-carboxyglutamic acid residues bound to metal ions participate as an intramolecular non-covalent bridge to maintain protein conformation. Additionally, these amino acids participate in the calcium-dependent molecular assembly of proteins on membrane surfaces through intermolecular bridges involving y-carboxyglutamic acid and metal ions.     

Calcium-binding properties of bovine factor X lacking the gamma-carboxyglutamic acid-containing region

In bovine protein C normal activation by the thrombin-thrombomodulin complex requires binding of calcium to one high affinity binding site, contained in a protein fragment that lacks the gamma-carboxyglutamic acid (Gla) region (Esmon, N. L., De Bault, L. E., and Esmon, C. T. (1983) J. Biol. Chem. 258, 5548-5553). In this work, the calcium binding to and the conformational change induced by calcium in the corresponding Gla-domainless fragment of bovine factor X, prepared by limited proteolysis by chymotrypsin, were compared with the calcium-binding properties of Gla-domainless protein C. Equilibrium dialysis experiments demonstrated that the proteolytically modified factor X has one high affinity calcium ion-binding site with Kd = 180 microM, a value almost identical to the Kd for the binding of calcium to proteolytically modified protein C. Measurements of the rate of disulfide bond reduction by thioredoxin showed that the disulfide bonds of both factor X and protein C lacking the Gla domains were more rapidly reduced in the absence than in the presence of calcium. Thus, calcium binding induces a conformational change in both proteolytically modified proteins. Calcium binding to Gla-domainless protein C is accompanied by a quenching of the intrinsic tryptophan fluorescence and by changes in the CD spectrum, indicative of perturbation of the environment of aromatic amino acids by the metal ion. However, no such changes were observed with the proteolytically modified factor X. This difference may be due to the fact that one tryptophan residue (in position 84) is present in the light chain of the proteolytically modified protein C but none in the light chain of the modified factor X. The light chain of factor X has beta-hydroxyaspartic acid in position 64 which is homologous to the beta-hydroxyaspartic acid in position 71 in the light chain of protein C. Our results are compatible with the hypothesis that beta-hydroxyaspartic acid is involved in the Ca2+ ion binding.     

The effect of divalent metal ions on the electrophoretic mobility of bovine prothrombin and bovine prothrombin fragment 1

Examination of metal ion-dependent effects on the electrophoretic mobility of bovine prothrombin and fragment 1 provides a useful and sensitive method for investigation of conformational processes in these proteins. Utilization of this method reveals a conformational change in bovine prothrombin and fragment 1 which occurs at low metal ion concentrations. Equilibrium dialysis studies indicate that the metal ion-induced shape change occurs concomitant with binding of a single calcium ion/molecule of prothrombin or fragment 1. Mixed metal electrophoretic mobility studies with Mg2+ and Ca2+ have demonstrated the "synergistic" effect for fragment 1 observed by others. Mixed metal equilibrium dialysis has provided experimental support for this observation and allows us to conclude that two tight Ca2+ sites are not affected by low Mg2+ concentrations and that the third Ca2+ site is also a tight site for Mg2+. Thus, at low Mg2+ concentrations and upon the addition of Ca2+, there are effectively three tight sites; consequently more Ca2+ will bind to the protein at lower total Ca2+ ion concentrations.     

A 42-kilodalton annexin-like protein is associated with plant vacuoles.

A 42-kD, calcium-dependent, membrane-binding protein (VCaB42) was associated with partially purified vacuole membrane. Membrane-dissociation assays indicated that VCaB42 binding to vacuole membranes was selective for calcium over other cations and that 50% of VCaB42 remained membrane bound at 61 +/- 11 nM free calcium. A 13-amino acid sequence obtained from VCaB42 showed 85% similarity with the endonexin fold, a sequence found in the annexin family of proteins that is thought to be essential for calcium and lipid binding. The greatest similarity in amino acid sequence was observed with annexin VIII (VAC-beta). The calcium-binding properties and sequence similarities suggest that VCaB42 is a member of the annexin family of calcium-dependent, membrane-binding proteins. Functional assays for VCaB42 on vacuole membrane transport processes indicated that it did not significantly affect the initial rate of calcium uptake into vacuole membrane vesicles. Because VCaB42 is vacuole localized (likely on the cytosolic surface of the vacuole) and is 50% dissociated within the physiological range of cytosolic free calcium, we hypothesize that this protein is a sensor that monitors cytosolic calcium levels and transmits that information to the vacuole.     

Molecular dynamics simulation of bovine prothrombin fragment 1 in the presence of calcium ions.

Early solvation-induced structural reorganization of calcium prothrombin fragment 1 is simulated with molecular dynamics. Initial coordinates are those of the 2.2-A resolution crystal structure [Soriano-Garcia, M., Padmanabhan, K., de Vos, A. M., & Tulinsky, A. (1992) Biochemistry 31, 2554-2556]. The molecular dynamics code AMBER, appropriately modified to include long-range (less than or equal to 22.0 A) ionic forces, was employed. The solution structure appears to equilibrate within 100 ps. Although minor changes are seen in various structural domains, the early solution structure basically maintains an intricate network of nine gamma-carboxyglutamic acid (Gla) residues encapsulating seven calcium ions. However, the Gla domain moves with respect to the kringle domain. This motion is mainly due to the movement of Ser34-Leu35 that appears to be a flexible hinge between the domains. The N-terminus of Ala 1 is in a tightly bound complex with three Gla residues that remains stable in the solution structure when the long-range electrostatic cutoff is employed and the near planar alignment of the seven calcium ions is only slightly distorted. The simulation structure is discussed in terms of experiments that studied calcium ion-induced quenching of the intrinsic fluorescence, protection of the N-terminal amino group from acetylation by calcium ions, chemical modification of the N-terminus to a trinitrophenyl derivative, and the possibility of a calcium-binding site(s) in the kringle domain.     

Monoclonal antibodies against human abnormal (des-gamma-carboxy)prothrombin specific for the calcium-free conformer of prothrombin

A monoclonal antibody JO1 X 1 was prepared against human abnormal prothrombin using the hybridoma technique. The clone secreting this antibody was selected on the basis of the ability of this antibody to bind to abnormal prothrombin, but not to prothrombin, in the presence of calcium ions. The antibodies were purified by affinity chromatography in EDTA on columns of prothrombin-Sepharose. Bound antibodies were eluted with 15 mM CaCl2. The kinetics of dissociation of antibody from the antibody-prothrombin complex with the addition of calcium ions fit a first-order kinetic model. Increasing CaCl2 concentration increased the rate of antibody-prothrombin dissociation. Ca(II) and Mn(II) inhibited antibody-prothrombin interaction; half-maximal binding was observed at 0.9 and 4 mM, respectively. Mg(II) had little effect on antibody-antigen interaction. The JO1 X 1 antibody bound fragment 1, fragment (1-39), abnormal prothrombin, and prothrombin equivalently in the presence of EDTA, but did not bind to des(1-44)prothrombin in the presence of EDTA or prothrombin in the presence of CaCl2. These results indicate that the monoclonal antibody JO1 X 1 is conformation specific for the calcium-free conformer of prothrombin and directed against an antigenic determinant near the NH2 terminus of prothrombin expressed in the 1-39 region of the protein. This analysis provides confirmation of the presence of a metal-free conformer of prothrombin.