Purification, characterization and ion binding properties of human brain S100b protein

Human brain S100b (beta beta) protein was purified using zinc-dependent affinity chromatography on phenyl-Sepharose. The calcium- and zinc-binding properties of the protein were studied by flow dialysis technique and the protein conformation both in the metal-free form and in the presence of Ca2+ or Zn2+ was investigated with ultraviolet spectroscopy, sulfhydryl reactivity and interaction with a hydrophobic fluorescence probe 6-(p-toluidino)naphthalene-2-sulfonic acid (TNS). Flow dialysis measurements of Ca2+ binding to human brain S100b (beta beta) protein revealed six Ca2+-binding sites which we assumed to represent three for each beta monomer, characterized by the macroscopic association constants K1 = 0.44 X 10(5) M-1; K2 = 0.1 X 10(5) M-1 and K3 = 0.08 X 10(5) M-1. In the presence of 120 mM KCl, the affinity of the protein for calcium is drastically reduced. Zinc-binding studies on human S100b protein showed that the protein bound two zinc ions per beta monomer, with macroscopic constants K1 = 4.47 X 10(7) M-1 and K2 = 0.1 X 10(7) M-1. Most of the Zn2+-induced conformational changes occurred after the binding of two zinc ions per mole of S100b protein. These results differ significantly from those for bovine protein and cast doubt on the conservation of the S100 structure during evolution. When calcium binding was studied in the presence of zinc, we noted an increase in the affinity of the protein for calcium, K1 = 4.4 X 10(5) M-1; K2 = 0.57 X 10(5) M-1; K3 = 0.023 X 10(5) M-1. These results indicated that the Ca2+- and Zn2+-binding sites on S100b protein are different and suggest that Zn2+ may regulate Ca2+ binding by increasing the affinity of the protein for calcium.     

Reinvestigation of the sulfhydryl reactivity in bovine brain S100b (beta beta) protein and the microtubule-associated tau proteins. Ca2+ stimulates disulfide cross-linking between the S100b beta-subunit and the microtubule-associated tau(2) protein

Zn2+ and Ca2+ affect the conformation of bovine brain S100b (beta beta) protein and the exposure of its Cys-84 beta. Zn2+ binding to high-affinity sites of native S100b protected the sulfhydryl groups against the thiol-specific reagent 5,5'-dithiobis(2-nitrobenzoate) and antagonized the Ca2+-stimulated reactivity of Cys-84 beta toward the reagent. Spectroscopic studies on the fluorescence properties of labeled S100b with the fluorescent probes bimane and acrylodan at Cys-84 beta confirmed the antagonistic effect of Ca2+ and Zn2+ with respect to the conformational properties of the protein. Measurements of fluorescence dynamics on bimane-labeled S100b indicated that the slow monomer-dimer equilibrium that characterizes the apoprotein at micromolar concentrations was shifted to the monomer form in the presence of Zn2+, a fact that could explain the previously reported Zn2+-dependent increase of S100b protein affinity for calcium. The difference in the effects of Ca2+ and Zn2+ on the reactivity of Cys-84 beta in S100b was confirmed when we observed that Ca2+ and Zn2+ have opposite actions on the formation of disulfide bridges between Cys-84 beta of the S100b beta-subunit and sulfhydryl groups on the microtubule-associated tau(2) protein. Ca2+ stimulated the covalent complex formation whereas Zn2+ inhibited it. We suggest that Zn2+ may have a modulatory function on Cys-84 beta reactivity in the S100b beta-subunit in vivo. Two types of divalent complexes between tau(2) and beta-subunit were formed in the presence of Ca2+, an equimolar complex tau(2)-beta 1 and a complex of one molecule of tau(2) with two beta-subunits, tau(2)-beta 2.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ions binding to S100 proteins. I. Calcium- and zinc-binding properties of bovine brain S100 alpha alpha, S100a (alpha beta), and S100b (beta beta) protein: Zn2+ regulates Ca2+ binding on S100b protein

Flow dialysis measurements of calcium binding to bovine brain S100 alpha alpha, S100a (alpha beta), and S100b (beta beta) proteins in 20 mM Tris-HCl buffer at pH 7.5 and 8.3 revealed that S100 proteins bind specifically 4 Ca2+ eq/mol of protein dimer. The specific calcium-binding sites had, therefore, been assigned to typical amino acid sequences on the alpha and beta subunit. The protein affinity for calcium is much lower in the presence of magnesium and potassium. Potassium strongly antagonizes calcium binding on two calcium-binding sites responsible for most of the Ca2+-induced conformational changes on S100 proteins (probably site II alpha and site II beta). Zinc-binding studies in the absence of divalent cations revealed eight zinc-binding sites/mol of S100b protein dimer that we assumed to correspond to 4 zinc-binding sites/beta subunit. Zinc binding to S100b studied with UV spectroscopy methods showed that the occupation of the four higher affinity sites and the four lower affinity sites on the protein dimer were responsible for different conformational changes in S100b structure. Zinc binding on the higher affinity sites regulates calcium binding to S100b by increasing the protein affinity for calcium and decreasing the antagonistic effect of potassium on calcium binding. Zinc-binding studies on S100a and S100 alpha alpha protein showed that the Trp-containing S100 proteins bind zinc more weakly than S100b protein. Calcium-binding studies on zinc-bound S100a proved that calcium- and zinc-binding sites were distinct although there was no increase in zinc-bound S100a affinity for calcium, as in S100b protein. Finally we provide evidence that discrepancies between previously published results on the optical properties of S100b protein probably result from oxidation of the sulfhydryl groups in the protein.     

Ions binding to S100 proteins. II. Conformational studies and calcium-induced conformational changes in S100 alpha alpha protein: the effect of acidic pH and calcium incubation on subunit exchange in S100a (alpha beta) protein

A rapid separation method for bovine brain S100 alpha alpha, S100a, and S100b protein using fast protein liquid chromatography on a Mono Q column and its application in preparation of a large amount of S100 alpha alpha protein are described. The conformation of S100 alpha alpha in the metal-free forms as well as in the presence of calcium were studied by UV absorption, circular dichroism, intrinsic fluorescence, sulfhydryl reactivity, and interaction with a hydrophobic fluorescent probe. The alpha-subunit appears to have nearly identical conformation in S100 alpha alpha and S100a protein dimers. We also confirmed that only the alpha-subunit exposes hydrophobic domains to solvent in the presence of calcium and that cysteine residues exposed upon Ca2+ binding to S100 proteins correspond to Cys 85 alpha and Cys 84 beta. Incubation of S100a with calcium and KCl proved that calcium binding to the putative calcium-binding sites (site I alpha, I beta) triggers a time- and temperature-dependent conformational change in the protein structure which decreases the antagonistic effect of KCl on calcium binding to sites II alpha and II beta and provokes subunit exchanges between protein dimers and the emergence of S100 alpha alpha and S100b (beta beta) proteins. Dynamic fluorescence measurements showed that incubating calcium at high S100a protein concentrations (greater than 10(-5) M) induces an apparent slow dimer-monomer equilibrium which might result in total subunit dissociation at lower protein concentrations. The effect of acidic pH on subunit dissociation in S100a protein (Morero, R. D., and Weber, G. (1982) Biochim. Biophys. Acta 703, 231-240) arises from conformational changes in the protein structure that are similar to those induced by Ca2+ incubation.     

Structural and ion-binding properties of an S100b protein mixed disulfide: comparison with the reappraised native S100b protein properties

S100b protein, chemically modified by thioethanol groups (linked via disulfide bonds to two out of four Cys per dimer) was largely similar to reduced native S100b protein in its overall structure and differed only by small modifications extending, however, to the whole protein structure. Studies combining direct Ca2+ binding and associated conformational changes revealed that this chemical modification markedly increased the Ca2(+)-binding affinities (especially in the presence of physiological concentrations of K+ and Mg2+) and introduced a strong positive cooperativity. Different binding models are discussed and it emerges that in both proteins the Ca2(+)-binding sites are not equivalent and probably interact. Like the reduced protein, chemically modified S100b protein binds four Zn2+ ions in two classes of sites (of high and low affinities). Whereas the overall Zn2+ affinity was only slightly decreased, the binding sequence was probably reversed by the introduction of thioethanol groups. Moreover, in the presence of zinc, the Ca2+ affinities were higher and even identical, in both proteins.     

Bovine Brain S100 Proteins: Separation and Characterization of a New S100 Protein Species

Three S100 protein species (S100a, S100b, S100a') have been purified from bovine brain using a modification of standard preparative methods. A higher yield for each protein was obtained at the last separation step. Characterization by urea/sodium dodecyl sulfate/polyacrylamide gel electrophoresis, UV absorption spectra, and fluorescence parameters provided evidence of a new tryptophan-containing S100 protein called S100a', which exhibits, as S100a and S100b, the properties of a Ca2+ binding protein.     

Zinc ion binding to human brain calcium binding proteins. Calmodulin and S100b protein

Comparative studies have been performed on the binding properties of zinc ions to human brain calmodulin and S100b protein. Calmodulin is characterized by two sets of Zn²⁺ binding sites, with K_D ranging from 8.10^?5M to 3.10^?4M. The S100b protein also exhibited two sets of zinc binding sites, with a much higher affinity. K_D = 10^?7 ? 10^?6M. We suggest that S100b protein should no longer be considered only as a “calcium binding protein” but also as a “zinc binding protein”, and that Zn²⁺ ions are involved in the functions of the S100 proteins.     

BAY K 8644, a 1,4-Dihydropyridine Ca2+ Channel Activator: Dissociation of Binding and Functional Effects in Brain Synaptosomes

K+-stimulated 45Ca2+ uptake into rat brain and guinea pig cerebral cortex synaptosomes was measured at 10 s and 90 s at K+ concentrations of 5-75 mM. Net increases in 45Ca2+ uptake were observed in rat and guinea pig brain synaptosomes. 45Ca2+ uptake under resting or depolarizing conditions was not increased by the 1,4-dihydropyridine BAY K 8644, which has been shown to activate Ca2+ channels in smooth and cardiac muscle. High-affinity [3H]nitrendipine binding in guinea pig synaptosomes (KD = 1.2 X 10(-10) M, Bmax = 0.56 pmol mg-1 protein) was competitively displaced with high affinity (IC50 2.3 X 10(-9) M) by BAY K 8644. Thus high-affinity Ca2+ channel antagonist and activator binding sites exist in synaptosome preparations, but their relationship to functional Ca2+ channels is not clear.     

Purification and properties of a novel nucleotide-hydrolysing enzyme (5''-nucleotidase) from Boophilus microplus.

Conformational changes in the beta-subunit of the bovine brain Ca2+-binding protein S100b (S100-beta) accompanying Ca2+ binding were investigated by analysis of the spectroscopic properties of the single tyrosine residue (Tyr17 beta) and flow-dialysis binding experiments. S100-beta binds Ca2+ sequentially at two sites to change the conformation of the protein. The first Ca2+ ion binds to site II beta, a typical Ca2+-binding site in the C-terminal region, and it does not significantly perturb the proximal environment of Tyr17 beta. After the first site is occupied, another Ca2+ ion binds to the N-terminal Ca2+-binding site, I beta, and strengthens a hydrogen bond between Tyr17 beta and a neighbouring carboxylate acceptor group, which results in a large increase in the Tyr17 beta fluorescence spectrum half-width and a positive absorption and c.d. signal between 290 and 275 nm. Ca2+ binding to the S100b.Zn2+6 complex, studied by flow-dialysis and fluorescence measurements showed that, although Zn2+ ions increase the affinity of S100b protein for Ca2+, the Ca2+-binding sequence was not changed. Tb3+ (terbium ion) binding studies on the S100b.Zn2+6 complex proved that Tb3+ antagonizes only Ca2+ binding site II beta and confirmed the sequential occupation of Ca2+-binding sites on the S100b.Zn2+6 complex.     

Implications on zinc binding to S100A2

Human S100A2 is an EF-hand calcium-binding S100 protein that is localized mainly in the nucleus and functions as tumor suppressor. In addition to Ca2+ S100A2 binds Zn2+ with a high affinity. Studies have been carried out to investigate whether Zn2+ acts as a regulatory ion for S100A2, as in the case of Ca2+. Using the method of competition with the Zn2+ chelator 4-(2-pyridylazo)-resorcinol, an apparent Kd of 25 nM has been determined for Zn2+ binding to S100A2. The affinity lies close to the range of intracellular free Zn2+ concentrations, suggesting that S100A2 is able to bind Zn2+ in the nucleus. Two Zn2+-binding sites have been identified using site directed mutagenesis and several spectroscopic techniques with Cd2+ and Co2+ as probes. In site 1 Zn2+ is bound by Cys21 and most likely by His 17. The binding of Zn2+ in site 2 induces the formation of a tetramer, whereby the Zn(2+) is coordinated by Cys2 from each subunit. Remarkably, only binding of Zn2+ to site 2 substantially weakens the affinity of S100A2 for Ca2+. Analysis of the individual Ca2+-binding constants revealed that the Ca2+ affinity of one EF-hand is decreased about 3-fold, whereas the other EF-hand exhibits a 300-fold decrease in affinity. These findings imply that S100A2 is regulated by both Zn2+ and Ca2+, and suggest that Zn2+ might deactivate S100A2 by inhibiting response to intracellular Ca2+ signals.     

Binding study of metal ions to S100 protein: 43Ca, 25Mg, 67Zn and 39K n.m.r.

The interactions of the S100 protein (S100) with metal cations such as Ca2+, Mg2+, Zn2+ and K+ were studied by the metal n.m.r. spectroscopy. The line widths of 43Ca, 25Mg, 67Zn and 39K n.m.r. markedly increased by adding all S100s. A broad 43Ca n.m.r. band of Ca(2+)-S100a solution was not affected by Zn2+ and K+, while it was greatly decreased by adding Mg2+. The 43Ca n.m.r. spectra of Ca(2+)-S100a0 and -S100b solutions consisted of two slow-exchangeable signals which corresponded to Ca2+ bound to two environmentally different sites of the S100a0. These two 43Ca n.m.r. signals were not affected by Zn2+ and K+. The line width of broad 25Mg n.m.r. band of the Mg(2+)-S100 solution greatly decreased by adding Ca2+, while it did not change by adding Zn2+ and K+. Further, the addition of Ca2+, Mg2+ and K+ did not affect the line width of the 67Zn n.m.r. of the Zn(2+)-S100 solutions. These findings suggest that: (1) Mg2+ binds to all S100s, and at least one of the Mg2+ binding sites of S100 molecule is the same as the Ca2+ binding site; (2) Zn2+ binds to S100s, although the binding site(s) is/are different from Ca(2+)- or Mg(2+)-binding site(s), and the environment of Zn2+ nuclei will not change even though Ca2+ binds to S100s.     

S100B-Mediated Inhibition of the Phosphorylation of GFAP Is Prevented by TRTK-12

S100B belongs to a family of calcium-binding proteins involved in cell cycle and cytoskeleton regulation. We observed an inhibitory effect of S100B on glial fibrillary acidic protein (GFAP) phosphorylation, when stimulated by cAMP or Ca2+/calmodulin, in a cytoskeletal fraction from primary astrocyte cultures. We found that S100B has no direct effect on CaM KII activity, the major kinase in this cytoskeletal fraction able to phosphorylate GFAP. The inhibition of GFAP phosphorylation is most likely due to the binding of S100B to the phosphorylation sites on this protein and blocking the access of these sites to the protein kinases. This inhibition was dependent on Ca2+. However, Zn2+ could substitute for Ca2+. The inhibitory effect of S100B was prevented by TRTK-12, a peptide that blocks S100B interaction with several target proteins including glial fibrillary acidic protein. These data suggest a role for S100B in the assembly of intermediate filaments in astrocytes.     

Identification of ω-Conotoxin Binding Sites on Adrenal Medullary Membranes: Possibility of Multiple Calcium Channels in Chromaffin Cells

Binding of 125I-omega-conotoxin GVIA and [3H]nitrendipine to membranes from bovine adrenal medulla was investigated to test for the presence of N- and L-type Ca2+ channels in adrenal chromaffin cells. Saturable, high-affinity binding sites for 125I-omega-conotoxin and [3H]nitrendipine were detected in a membrane fraction from adrenal medulla. [3H]Nitrendipine binding sites were found to have a KD of 500 +/- 170 pM and a Bmax of 26 +/- 11 pmol/g of protein. 125I-omega-Conotoxin binding sites had a KD of 215 +/- 56 pM and a Bmax of 105 +/- 18 pmol/g of protein, about four times the number of sites found for [3H]nitrendipine. 125I-omega-Conotoxin binding was potently inhibited by unlabeled toxin and Ca2+ but was unaffected by dihydropyridines, verapamil, and diltiazem. [3H]Nitrendipine binding was not affected by omega-conotoxin, whereas it was inhibited by other dihydropyridines. Bay K 8644 potentiated K+-evoked cytosolic Ca2+ transients measured by fura-2 fluorescence, and this potentiation was completely blocked by nifedipine. In contrast, omega-conotoxin had no effect on Bay K 8644-evoked Ca2+ transients. Thus, the binding sites for omega-conotoxin and for nitrendipine appear to be different. The results confirm the presence of L-type Ca2+ channels and open the possibility of N-type Ca2+ channels as the omega-conotoxin binding sites in chromaffin cell membranes.     

Purification and characterization of adipose tissue S-100b protein

We have purified S-100 protein from bovine brain using Ca2+-dependent affinity chromatography on N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide (W-7)-Sepharose (Endo, T., Tanaka, T., Isobe, T., Kasai, H., Okuyama, T., and Hidaka, H. (1981) J. Biol. Chem. 256, 12485-12489). By essentially the same procedure, W-7-Sepharose binding protein has been purified to apparent homogeneity from bovine abdominal adipose tissue. Electrophoretically, the purified protein from adipose tissue co-migrated with brain S-100b protein both in the presence and absence of sodium dodecyl sulfate and the protein was indistinguishable from brain S-100b region in terms of amino acid composition, two-dimensional tryptic peptide mapping and reactivity with anti-brain S-100b serum. Immunohistochemical analysis confirmed the existence of S-100b protein in the adipose cell where the protein seems to be located in both the nucleus and cytoplasm. Thus, the results indicate that the adipose cells contain the protein possibly identical with brain S-100b protein. In addition, the contents of S-100b protein in various rat tissues were measured by enzyme immunoassay method using the anti-bovine brain S-100b serum. Significant amounts of S-100b protein were found not only in the adipose tissue but also in the peripheral tissue such as trachea and skin. These observations suggest that S-100b protein should no longer be considered as a protein specific to nervous tissues.     

Kinetics of the conformational change of skeletal troponin C induced by Ca2+-Mg2+ exchange at the high-affinity Ca2+-binding sites

The rate constant of the conformational change of skeletal troponin C (TnC) induced by the Ca2+ binding reaction with the high-affinity Ca2+-binding sites was determined in the presence of Mg2+ by the fluorescence stopped-flow method in 0.1 M KCl, 50 mM Na-cacodylate-HCl pH 7.0 at 20 degrees C. The [MgCl2] dependence of the rate constants of the observed biphasic conformational change leveled off at the high [MgCl2] region: the rate constants were 60 +/- 9 s-1 and 8 +/- 2 s-1, respectively. These values are larger than the rate constants of the biphasic fluorescence intensity change of TnC induced by Mg2+ removal reaction at the high-affinity Ca2+-binding sites (37 +/- 7 s-1 and 3.0 +/- 0.6 s-1) under the same experimental conditions. These results suggest that the Ca2+-Mg2+ exchange reaction at the high-affinity Ca2+-binding sites is faster than the resultant conformational change accompanying the fluorescence intensity change. Based on these results, we also reexamine the molecular kinetic mechanism of the conformational change of the protein induced by the Mg2+ binding or removal reaction with the high affinity Ca2+-binding sites of skeletal TnC.     

New perspectives on S100 proteins: a multi-functional Ca 2+ -, Zn 2+ - and Cu 2+ -binding protein family

S100 proteins (16 members) show a very divergent pattern of cell- and tissue-specific expression, of subcel-lular localizations and relocations, of post-translational modifications, and of affinities for Ca 2+ , Zn 2+ , and Cu 2+ , consistent with their pleiotropic intra- and extracellular functions. Up to 40 target proteins are reported to interact with S100 proteins and for S100A1 alone 15 target proteins are presently known. Therefore it is not surprising that many functional roles have been proposed and that several human disorders such as cancer, neurodegenerative diseases, cardiomyopathies, inflammations, diabetes, and allergies are associated with an altered expression of S100 proteins. It is not unlikely that their biological activity in some cases is regulated by Zn 2+ and Cu 2+ , rather than by Ca 2+ Despite the numerous putative functions of S100 proteins, their three-dimensional structures of, e.g., S100B, S100A6, and S100A7 are surprisingly similar. They contain a compact dimerization domain whose conformation is rather insensitive to Ca 2+ binding and two lateral a-helices III and III, which project outward of each subunit when Ca 2+ is bound. Target docking depends on the two hydrophobic patches in front of the paired EF-hand generated by the binding of Ca 2+. The selec-tivity in target binding is assured by the central linker between the two EF-hands and the C-terminal tail. It appears that the S100-binding domain in some target proteins contains a basic amphiphilic a-helix and that the mode of interaction and activation bears structural similarity to that of calmodulin.© Kluwer Academic Publishers     

Presynaptic Cholinergic Mechanisms in the Rat Cerebellum: Evidence for Nicotinic, but Not Muscarinic Autoreceptors

The present study shows that N-[3H]methylcarbamylcholine ([3H]MCC) binds to a single population of high-affinity/low-density (KD = 5.0 nM; Bmax = 8.2 fmol/mg of protein) nicotinic binding sites in the rat cerebellum. Also, there exists a single class of high-affinity binding sites (KD = 4.8 nM; Bmax = 24.2 fmol/mg of protein) in the cerebellum for the M1 specific muscarinic ligand [3H]pirenzepine. In contrast, the M2 ligand, [3H]AF-DX 116, appears to bind to two classes of binding sites, i.e., a high-affinity (KD = 3 nM)/low-capacity (Bmax = 11.7 fmol/mg of protein) class, and a second class of lower affinity (KD = 28.4 nM) and higher capacity (Bmax = 36.3 fmol/mg of protein) sites. The putative M3 selective ligand [3H]4-diphenylacetoxy-N-methylpiperidine also binds to two distinct classes of binding sites in cerebellar homogenates, one of high affinity (KD = 0.5 nM)/low capacity (Bmax = 19.5 fmol/mg of protein) and one of low affinity (KD = 57.5 nM)/high capacity (Bmax = 140.6 fmol/mg of protein). In experiments which tested the effects of cholinergic drugs on acetylcholine release from cerebellar brain slices, the nicotinic agonist MCC enhanced spontaneous acetylcholine release in a concentration-dependent manner, and the maximal increase in acetylcholine release (59.0-68.0%) occurred at 10(-7) M. The effect of MCC to increase acetylcholine release was Ca2+-dependent and tetrodotoxin-insensitive, suggesting an action on cholinergic terminals. Also, the MCC-induced increase in acetylcholine release was effectively antagonized by dihydro-beta-erythroidine, d-tubocurarine, and kappa-bungarotoxin, but was insensitive to either atropine or alpha-bungarotoxin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Ca2+ and Zn2+-binding properties of nitrated S-100b protein from bovine brain.

The single tyrosine residue in S-100b protein was nitrated by treatment with tetranitromethane in 0.1 M-Tris/HCl buffer, pH 8.0, containing 2 mM-EDTA. The nitrated protein did not differ significantly in secondary structure from its native unmodified counterpart, as revealed by far-u.v. c.d. measurements. The effect of Ca2+ on the modified protein was different from that on the native protein, e.g. addition of Ca2+ resulted in a loss of helical content from 55 to 47% with the native protein whereas Ca2+ had no significant effect on the gross conformation of the nitrated derivative. Near-u.v. c.d. studies also indicated a very minimal effect on the tyrosine residue and this was also reflected in the u.v.-absorption difference spectrum. Polyacrylamide-gel electrophoresis in the absence of SDS showed the nitrated S-100b to move faster in the presence of EDTA compared with the calcium-bound state, suggesting that the modified protein does bind Ca2+ although it does not undergo a major conformational change in response to Ca2+ addition. In contradistinction, Zn2+ binding was not influenced by nitration, as demonstrated by aromatic c.d. and u.v.-difference spectroscopy. It is clear from this study that the single tyrosine residue in S-100b is critical to sense the Ca2+-induced conformational changes in the protein.     

Spectral studies of the Ca2+-dependent interaction of trifluoperazine with S100b

S100b is a calcium-binding protein that will bind to many calmodulin target molecules in a Ca²⁺-dependent manner. In order to study the Ca²⁺-dependent binding properties of S100b, its interaction with a calmodulin antagonist, trifluoperazine (TFP), was investigated using [¹⁹F]- and [¹H]-NMR and UV-difference spectroscopy. It was estimated from [¹⁹F]-NMR that in the absence of Ca²⁺, thek _1/2 value of TFP was 130 µM, while itsk _1/2 value decreased to 28 µM in the presence of Ca²⁺. The addition of KCl was not antagonistic to the Ca²⁺-dependent interaction of TFP to S100b. The chemical exchange rate of TFP with Ca²⁺-bound S100b was estimated to be 9×10² sec^?1. By comparison with TFP-calmodulin exchange rates, it is suggested that the TFP-binding site on S100b is structurally different from its binding sites on calmodulin. Proton NMR resonance broadening in the range 6.8–7.2 ppm, corresponding to phenylalanine nuclei of S100b, indicates that these residues may be involved in TFP binding. Addition of Ca²⁺ to a 1:1 mixture of S100b and TFP resulted in a red-shifted UV-difference spectrum, while no significant difference spectrum was detected when Mg²⁺ was added to a S100b-TFP solution. Thus, we suggest that Ca²⁺ induces the exposure of a hydrophobic domain on S100b containing one or more phenylalanine residues that will bind TFP but that this domain is different from the hydrophobic domain on calmodulin.     

Physicochemical properties of a novel Mr-21 000 Ca2+-binding protein of bovine brain.

The physicochemical properties of a novel Mr-21 000 Ca2+-binding protein isolated from bovine brain were investigated. The protein exhibited a partial specific volume of 0.724 ml/g, a degree of hydration of 0.47 g of water/g of protein and a mean residue weight of 119. Sedimentation equilibrium analysis revealed Mr = 22 600 in the absence of Ca2+; Ca2+ binding appeared to induce dimerization of the molecule. Size-exclusion chromatography indicated a compacting of the molecule on binding of Ca2+: the Stokes radius decreased from 2.75 nm in the absence of Ca2+ to 2.56 nm in its presence. Far-u.v.c.d. spectroscopy showed the apoprotein to be composed of 44% alpha-helix, 18% beta-pleated sheet and 38% random coil. Addition of either KCl (0.1 M) plus Mg2+ (1 mM), or Ca2+ (2 mM), changed the conformation to 49% alpha-helix, 18% beta-pleated sheet and 33% random coil. Near-u.v.c.d. and u.v. difference spectroscopy both indicated perturbations in the environments of all three types of aromatic amino acids on binding of Ca2+. Ca2+ binding also resulted in a 30% enhancement in the tryptophan fluorescence emission intensity. Ca2+ titration of the far-u.v.c.d. and fluorescence enhancement provided KD values of 9.91 microM and 4.68 microM respectively. Finally, the protein was shown to bind Zn2+ with KD = 1.44 microM (no Mg2+) and 1.82 microM (+ Mg2+). These observations strongly support the possibility that this novel Ca2+-binding protein resembles calmodulin and related Ca2+-binding proteins and undergoes a conformational change on binding of Ca2+ which reflects a physiological role in Ca2+-mediated regulation of brain function.