Innocuous character of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid and EDTA as metal-ion buffers in studying Ca2+ binding by alpha-lactalbumin

The binding of EGTA and EDTA to alpha-lactalbumin, first demonstrated by Kronman and Bratcher (Kronman, M. J., and Bratcher, S. C. (1983) J. Biol. Chem. 258, 5707-5709) and afterwards regarded as a significant source of error in estimating the binding constant of Ca2+ to the protein, has been investigated by comparison of the thermal unfolding curves of the protein in the absence and presence of the chelators and also by measuring the NMR spectra of the protein, the chelators, and the protein-chelator mixtures. The unfolding curve in the presence of a large excess of each chelator has been found to be identical to that in the absence of chelator, indicating that there is essentially no interaction between the chelators and alpha-lactalbumin. The NMR results have also supported this conclusion, and the innocuous character of these chelators as metal-ion buffers in studying the Ca2+-binding properties of alpha-lactalbumin is demonstrated. In order to re-examine the binding constant for Ca2+ of alpha-lactalbumin without the aid of chelating metal-ion buffers, the thermal unfolding curve of the protein in the presence of 0.1 mM excess Ca2+ but without chelators has been compared with the unfolding curve in the absence of Ca2+ at a constant concentration of Na+ (0.010 or 0.10 M) at pH 7.0. The binding constant of alpha-lactalbumin can be calculated from the increment of melting temperature caused by the presence of Ca2+ and from the enthalpy and heat capacity changes in the unfolding. Because Ca2+ binding to the unfolded protein can be neglected under the conditions employed, the binding constant evaluated corresponds to the binding constant to protein that has native structure. The constant obtained is 3-5 X 10(9) M-1 after corrections for binding of Na+ to the protein and for ionic strength, and this shows excellent agreement with the corresponding value previously estimated (2.9 +/- 1.0 X 10(9) M-1), although the latter value was obtained in the presence of EDTA. The apparent Ca2+-binding constant that has been discussed in most previous studies, without taking account of the folding-unfolding equilibrium associated with the binding process, also depends on the concentration of monovalent cations such as Na+, and the present results lead to values of 1.5 X 10(8) and 8.7 X 10(6) M-1 at 0.01 and 0.1 M Na+, respectively.     

Using protein design to dissect the effect of charged residues on metal binding and protein stability

Ca2+ controls biological processes by interacting with proteins with different affinities, which are largely influenced by the electrostatic interaction from the local negatively charged ligand residues in the coordination sphere. We have developed a general strategy for rationally designing stable Ca2+- and Ln3+-binding proteins that retain the native folding of the host protein. Domain 1 of cluster differentiation 2 (CD2) is the host for the two designed proteins in this study. We investigate the effect of local charge on Ca2+-binding affinity based on the folding properties and metal-binding affinities of the two proteins that have similarly located Ca2+-binding sites with two shared ligand positions. While mutation and Ca2+ binding do not alter the native structure of the protein, Ca2+ binding specifically induced changes around the designed Ca2+-binding site. The designed protein with a -5 charge at the binding sphere displays a 14-, 20-, and 12-fold increase in the binding affinity for Ca2+, Tb3+, and La3+, respectively, compared to the designed protein with a -3 charge, which suggests that higher local charges are preferred for both Ca2+ and Ln3+ binding. The localized charged residues significantly decrease the thermal stability of the designed protein with a -5 charge, which has a T(m) of 41 degrees C. Wild-type CD2 has a T(m) of 61 degrees C, which is similar to the designed protein with a -3 charge. This decrease is partially restored by Ca2+ binding. The effect on the protein stability is modulated by the environment and the secondary structure locations of the charged mutations. Our study demonstrates the capability and power of protein design in unveiling key determinants to Ca2+-binding affinity without the complexities of the global conformational changes, cooperativity, and multibinding process found in most natural Ca2+-binding proteins.     

Use of site-directed mutations in the individual Ca2(+)-binding sites of calmodulin to examine Ca2(+)-induced conformational changes

Mutant versions of the calmodulin of Drosophila melanogaster have been prepared for use in the study of Ca2+ binding and Ca2(+)-induced conformational changes. In each mutant, a conserved glutamic acid residue indicated to play a critical role in Ca2+ binding has been mutated to glutamine in one of the Ca2(+)-binding sites. Thus a series of four proteins, each with an analogous mutation in one of the four binding sites, has been generated. Here the Ca2(+)-induced conformational changes in these proteins have been examined by use of the fluorescent hydrophobic reporter molecule, 9-anthroyl choline. These studies confirm earlier work which indicates that the carboxyl-terminal pair of Ca2(+)-binding sites shows cooperative Ca2+ binding to produce a major conformational change in the protein. However, these studies provide evidence that the sites of the amino-terminal pair are more independent in their Ca2+ binding properties and contribute individually to the conformational changes associated with Ca2+ binding in the amino-terminal half of the protein. This work also indicates that mutation of either of the amino-terminal Ca2(+)-binding sites can influence the conformational change produced by Ca2+ binding to the carboxyl-terminal sites.     

On experimental artifacts in the use of metal ion chelators for the determination of the cation binding constants of alpha-lactalbumin. A reply

The binding constant of Ca2+ to the strong cation site of bovine alpha-lactalbumin has been measured directly by monitoring the free calcium concentration by Quin 2 fluorescence. A dissociation constant of 1-4 nM was calculated, which confirms the strong calcium binding properties of this protein. In order to examine whether the metal ion chelators EDTA or EGTA affect the cation binding equilbria by binding to bovine alpha-lactalbumin, calcium binding equilibria were carefully measured under highly stabilized pH and temperature conditions. Within the concentration ranges required for competitive binding by these ligands (EDTA or EGTA) (less than 1-3 mM) these chelators produced no artifacts, in contradiction to the data of Kronman and Bratcher (Kronman, M. J., and Bratcher, S. C. (1983) J. Biol. Chem. 258, 5707-5709).     

Salt enhances calmodulin-target interaction

Calmodulin (CaM) operates as a Ca(2+) sensor and is known to interact with and regulate hundreds of proteins involved in a great many aspects of cellular function. It is of considerable interest to understand the balance of forces in complex formation of CaM with its target proteins. Here we have studied the importance of electrostatic interactions in the complex between CaM and a peptide derived from smooth-muscle myosin light-chain kinase by experimental methods and Monte Carlo simulations of electrostatic interactions. We show by Monte Carlo simulations that, in agreement with experimental data, the binding affinity between CaM and highly charged peptides is surprisingly insensitive to changes in the net charge of both the protein and peptide. We observe an increase in the binding affinity between oppositely charged partners with increasing salt concentration from zero to 100 mM, showing that formation of globular CaM-kinase type complexes is facilitated at physiological ionic strength. We conclude that ionic interactions in complex formation are optimized at pH and saline similar to the cell environment, which probably overrules the electrostatic repulsion between the negatively charged Ca(2+)-binding domains of CaM. We propose a conceivable rationalization of CaM electrostatics associated with interdomain repulsion.     

Purification and properties of a 23 kDa Ca2(+)-binding protein from Drosophila melanogaster.

Recent reports have shown that there exists in mammalian brain a number of heat-stable Ca2(+)-binding proteins that are distinct from calmodulin [McDonald & Walsh (1985) Biochem. J. 232, 559-567]. We have attempted to characterize equivalent Ca2(+)-binding proteins from Drosophila. Affigel-phenothiazine chromatography, which can be used to purify calmodulin and other Ca2(+)-binding proteins, allowed the identification of a possible heat-stable 23 kDa Ca2(+)-binding protein. A purification procedure for this protein has been devised. Purified 23 kDa protein shows characteristics typical of a Ca2(+)-binding protein; there is a mobility shift on SDS/polyacrylamide gels in the presence of EGTA, and Western blotting, followed by the use of the 45Ca2+ overlay technique, confirms that the 23 kDa protein does bind Ca2+. 45Ca2+ binding studies indicate that this protein binds 1 mol of Ca2+/mol of protein, with Kd 1.9 microM. A single band with pI 5.2 is obtained on isoelectric focusing. Analysis of Western blots of Drosophila tissues probed with antibodies to the Ca2(+)-binding protein indicates that it has a widespread distribution, but is absent from muscle tissue. The antibodies also cross-react with a protein of identical molecular mass in extracts of sheep brain. The possible similarity between this Drosophila Ca2(+)-binding protein and mammalian proteins is discussed, and comparison is made between this Drosophila protein and other Ca2(+)-binding proteins purified from vertebrates.     

Interaction of ruthenium red with Ca2(+)-binding proteins.

The interaction of ruthenium red, [(NH3)5Ru-O-Ru(NH3)4-O-Ru(NH3)5]Cl6.4H2O, with various Ca2(+)-binding proteins was studied. Ruthenium red inhibited Ca2+ binding to the sarcoplasmic reticulum protein, calsequestrin, immobilized on Sepharose 4B. Furthermore, ruthenium red bound to calsequestrin with high affinity (Kd = 0.7 microM; Bmax = 218 nmol/mg protein). The dye stained calsequestrin in sodium dodecyl sulfate-polyacrylamide gels or on nitrocellulose paper and was displaced by Ca2+ (Ki = 1.4 mM). The specificity of ruthenium red staining of several Ca2(+)-binding proteins was investigated by comparison with two other detection methods, 45Ca2+ autoradiography and the Stains-all reaction. Ruthenium red bound to the same proteins detected by the 45Ca2+ overlay technique. Ruthenium red stained both the erythrocyte Band 3 anion transporter and the Ca2(+)-ATPase of skeletal muscle sarcoplasmic reticulum. Ruthenium red also stained the EF hand conformation Ca2(+)-binding proteins, calmodulin, troponin C, and S-100. This inorganic dye provides a simple, rapid method for detecting various types of Ca2(+)-binding proteins following electrophoresis.     

Interactions of calcium binding proteins, parvalbumin and alpha-lactalbumin, with dipalmitoylphosphatidylcholine vesicles

Interactions of Ca2+ binding proteins, pike (Esox lucius) parvalbumins pI 4.2 and 5.0, and bovine and human alpha-lactalbumins, with dipalmitoylphosphatidylcholine vesicles were studied by means of scanning microcalorimetry and intrinsic tyrosine and tryptophan fluorescence methods. The interactions of pike parvalbumins are modulated by Ca2+ and Mg2+ binding to the protein and induce some changes in the physical properties of both the proteins and liposomes. Liposomes increased thermal stability of Ca2+-loaded parvalbumin and decreased thermal stability of both Mg2+-loaded and metal-free protein. The interaction of parvalbumin with liposomes affects the phase transition from gel to liquid-crystalline state in liposomes. Ca2+-loaded alpha-lactalbumin interacts with liposomes in its native state while the metal-free protein binds to the liposomes mainly in its thermally denatured state. The results of the microcalorimetric and spectrofluorometric studies are supported by data obtained by means of gel-chromatography on Sepharose 4B. It may be suggested that these metal-modulated interactions of Ca2+-binding proteins with membranes have some functional significance.     

Characterizing the response of calcium signal transducers to generated calcium transients

Cellular Ca2+ transients and Ca2+-binding proteins regulate physiological phenomena as diverse as muscle contraction, neurosecretion, and cell division. When Ca2+ is rapidly mixed with slow Ca2+ chelators, EGTA, or Mg2+/EDTA, artificial Ca2+ transients (ACTs) of varying duration (0.1-50 ms half-widths (hws)) and amplitude can be generated. We have exposed several Ca2+ indicators, Ca2+-binding proteins, and a Ca2+-dependent enzyme to ACTs of various durations and observed their transient binding of Ca2+, complex formation, and/or activation. A 0.1 ms hw ACT transiently occupied approximately 70% of the N-terminal regulatory sites of troponin C consistent with their rapid Ca2+ on-rate (8.7 +/- 2.0 x 10(7) M-1 s-1). A 1.1 ms hw ACT produced approximately 90% transient binding of the N-terminal of calmodulin (CaM) to the RS-20 peptide, but little binding of CaM's C-terminal to RS-20. A 0.6 ms hw ACT was sufficient for the N-terminal of CaM to transiently bind approximately 60% of myosin light chain kinase (MLCK), while a 1.8 ms hw ACT produced approximately 22% transient activation of the sarcoplasmic reticulum (SR) Ca2+/ATPase. In both cases, the ACT had fallen back to baseline approximately 10-30 ms before maximal binding of CaM to MLCK or SR Ca2+/ATPase activation occurred and binding and enzyme activation persisted long after the Ca transient had subsided. The use of ACTs has allowed us to visualize how the Ca2+-exchange rates of Ca2+-binding proteins dictate their Ca2+-induced conformational changes, Ca2+-induced protein/peptide and protein/protein interactions, and enzyme activation and inactivation, in response to Ca2+ transients of various amplitude and duration. By characterizing the response of these proteins to ACTs, we can predict with greater certainty how they would respond to natural Ca2+ transients to regulate cellular phenomena.     

Two novel brain proteins, CaBP33 and CaBP37, are calcium-dependent phospholipid- and membrane-binding proteins

Two acidic Ca2(+)-binding proteins (CaBP33 and CaBP37) purified from bovine brain have been characterized in terms of immunological properties, heat-sensitivity, electrophoretic mobility, and Ca2(+)-dependent binding to negatively charged phospholipids and to brain membranes. They were induced to bind to membranes by homogenization of brain tissue in the presence of CaCl2. The membrane-bound CaBP33/CaBP37 mixture resisted extraction with detergents and was solubilized with high concentrations of EGTA/KCl. However, apparent Ca2(+)-independent binding of the two proteins to membranes seemed to occur as well. This latter fraction of membrane-bound CaBP33 and CaBP37 could be solubilized with Triton X-100, indicating that brain membranes normally contain the two proteins as intrinsic components.     

Novel type of very high affinity calcium-binding sites in beta-hydroxyasparagine-containing epidermal growth factor-like domains in vitamin K-dependent protein S

Vitamin K-dependent protein S is shown to contain four very high affinity Ca2(+)-binding sites. The number of sites and their affinities were determined from Ca2+ titration in the presence of the chromophoric chelator Quin 2. In 0.15 M NaCl, pH 7.5, the four macroscopic binding constants are K1 greater than or equal to 1 x 10(8) M-1, K2 = 3 +/- 2 x 10(7) M-1, K3 = 4 +/- 2 x 10(6) M-1, and K4 = 9 +/- 4 x 10(5) M-1. At low ionic strength, the corresponding values are K1 greater than or equal to 2 x 10(9) M-1, K2 = 9 +/- 4 x 10(8) M-1, K3 = 2 +/- 1 x 10(8) M-1, and K4 = 9 +/- 4 x 10(7) M-1. To localize the Ca2(+)-binding sites, protein S was subjected to proteolysis using lysyl endopeptidase. This yielded a 20-21-kDa fragment which comprised the third and fourth epidermal growth factor (EGF)-like domains and remained high affinity Ca2(+)-binding site(s). The susceptibility of the EGF-like domains to proteolysis increased when Ca2+ was removed from protein S indicating that the Ca2+ binding is important for the stability and/or conformation of the EGF domains. Three of the four EGF-like domains in protein S contain beta-hydroxyasparagine. In each of these domains there is a cluster of three or four negatively charged amino acid residues which are likely to contribute to the extraordinary high Ca2+ affinity. From sequence homology it is suggested that this novel type of high affinity Ca2(+)-binding site is present in several other proteins, e.g. in the EGF-like domains in the low sensity lipoproteins receptor, thrombomodulin, the Notch protein of Drosophila melanogaster, and transforming growth factor beta 1-binding protein.     

Calbindin-D28K, a 1 alpha,25-dihydroxyvitamin D3-induced calcium-binding protein, binds five or six Ca2+ ions with high affinity

Calbindin-D28K is a 1 alpha,25-dihydroxyvitamin D3-dependent protein that belongs to the superfamily of high affinity calcium-binding proteins which includes parvalbumin, calmodulin, and troponin C. All of these proteins bind Ca2+ ligands by an alpha-helix-loop-alpha-helix domain that is termed an EF-hand. Calbindin-D28K has been reported previously to have four high affinity Ca2(+)-binding sites (KD less than 10(-7)) as quantitated by equilibrium dialysis. With the determination of the amino acid sequence, it was clear that there are in fact six apparent EF-hand domains, although the Ca2(+)-binding functionality of the two additional domains was unclear. It was of interest to quantitate the Ca2(+)-binding ability of chick intestinal calbindin-D28K utilizing several different Ca2+ titration methods that cover a range of macroscopic binding constants for weak or strong Ca2+ sites. Titrations with the Ca2+ chelator dibromo-1,2-bis(2-aminophenoxy)-ethane-N,N,N',N'-tetraacetic acid (5,5'-Br2BAPTA), a Ca2+ selective electrode, and as followed by 1H NMR, which measure KD values of 10(-6)-10(-8) M, 10(-4)-10(-7) and 10(-3)-10(-5) M, respectively, gave no evidence for the presence of weak Ca2(+)-binding sites. However, Ca2+ titration of the fluorescent Ca2+ chelator Quin 2 in the presence of calbindin-D28K yielded a least squares fit optimal for 5.7 +/- 0.8 Ca2(+)-binding sites with macroscopic dissociation constants around 10(-8) M. The binding of Ca2+ by calbindin was found to be cooperative with at least two of the sites exhibiting positive cooperativity.     

No need to be HAMLET or BAMLET to interact with histones: binding of monomeric alpha-lactalbumin to histones and basic poly-amino acids

The ability of a specific complex of human alpha-lactalbumin with oleic acid (HAMLET) to induce cell death with selectivity for tumor and undifferentiated cells was shown recently to be mediated by interaction of HAMLET with histone proteins irreversibly disrupting chromatin structure [Duringer, C., et al. (2003) J. Biol. Chem. 278, 42131-42135]. Here we show that monomeric alpha-lactalbumin (alpha-LA) in the absence of fatty acids is also able to bind efficiently to the primary target of HAMLET, histone HIII, regardless of Ca(2+) content. Thus, the modification of alpha-LA by oleic acid is not required for binding to histones. We suggest that interaction of negatively charged alpha-LA with the basic histone stabilizes apo-alpha-LA and destabilizes the Ca(2+)-bound protein due to compensation for excess negative charge of alpha-LA's Ca(2+)-binding loop by positively charged residues of the histone. Spectrofluorimetric curves of titration of alpha-LA by histone H3 were well approximated by a scheme of cooperative binding of four alpha-LA molecules per molecule of histone, with an equilibrium dissociation constant of 1.0 microM. Such a stoichiometry of binding implies that the binding process is not site-specific with respect to histone and likely is driven by just electrostatic interactions. Co-incubation of positively charged poly-amino acids (poly-Lys and poly-Arg) with alpha-LA resulted in effects which were similar to those caused by histone HIII, confirming the electrostatic nature of the alpha-LA-histone interaction. In all cases that were studied, the binding was accompanied by aggregation. The data indicate that alpha-lactalbumin can be used as a basis for the design of antitumor agents, acting through disorganization of chromatin structure due to interaction between alpha-LA and histone proteins.     

Calcium regulates folding and disulfide-bond formation in alpha-lactalbumin

Refolding and disulfide bond formation in reduced denatured bovine alpha-lactalbumin is shown to be Ca2+-dependent. Whereas in the absence of Ca2+ only about 2% of the native active protein is regenerated, in the presence of Ca2+, almost quantitative renaturation is obtained. A close coupling between Ca2+-binding and native disulfide bond formation is also indicated by spontaneous disulfide scrambling in the apoprotein in the presence of low concentrations of thiols. This phenomenon is not found in other disulfide-containing proteins including the homologous chicken lysozyme. It is proposed that the alpha-lactalbumin Ca2+-binding site has the in vivo function of imposing Ca2+ regulation on the folding of nascent alpha-lactalbumin and thereby on lactose synthesis.     

Effect of metal ion binding on the secondary structure of bovine alpha-lactalbumin as examined by infrared spectroscopy

We have examined the influence of monovalent and divalent cations on the secondary structure of bovine alpha-lactalbumin at neutral pH using Fourier-transform infrared spectroscopy. Our present studies are based on previously reported amide I' component band assignments for this protein [Prestrelski, S. J., Byler, D. M., & Thompson, M. P. (1991) Int. J. Pept. Protein Res. 37, 508-512]. The results indicate that upon dissolution, alpha-lactalbumin undergoes a small, but significant, time-dependent conformational change, regardless of the ions present. Additionally, these studies provide the first quantitative measure of the well-known secondary structural change which accompanies calcium binding. Results indicate that removal of Ca2+ from holo alpha-lactalbumin results in local unfolding of the Ca(2+)-binding loop; the spectra indicate that approximately 16% of the backbone chain changes from a rigid coordination complex to an unordered loop. We have also examined the effects of binding of several other metal ions. Our studies have revealed that binding of Mn2+ to apo alpha-lactalbumin (Ca(2+)-free), while inducing a small, but significant, conformational change, does not cause the alpha-lactalbumin backbone conformation to change to that of the holo (Ca(2+)-bound) form as characterized by infrared spectroscopy. Similar changes to those induced by Mn2+ are observed upon binding of Na+ to apo alpha-lactalbumin, and furthermore, even at very high concentrations (0.2 M), Na+ does not stabilize a structure similar to the holo form. Binding of Zn2+ to the apo form of alpha-lactalbumin does not result in significant backbone conformational changes, suggesting a rigid Zn(2+)-binding site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Spectroscopic, thermodynamic and kinetic properties of Candida nitratophila nitrate reductase.

HL-60 cells possess a 60 kDa Ca2(+)-binding protein that is contained in a discrete subcellular compartment, referred to as calciosomes. Subcellular fractionation studies have suggested that, in HL-60 cells, this intracellular compartment is an Ins(1,4,5)P3-sensitive Ca2+ store. In order to investigate the structural relationship of the 60 kDa Ca2(+)-binding protein of HL-60 cells to other Ca2(+)-binding proteins, we have purified the protein by ammonium sulphate extraction, acid precipitation, and DEAE-cellulose and phenyl-Sepharose column chromatography. The N-terminal sequence of the protein shows 93% identity with rabbit muscle calreticulin, a recently cloned sarcoplasmic reticulum Ca2(+)-binding protein. No amino acid sequence similarity with calsequestrin was found, although the purified protein cross-reacted with anti-calsequestrin antibodies. The calreticulin-related protein of HL-60 cells might play a role as an intravesicular Ca2(+)-binding protein of an Ins(1,4,5)P3-sensitive Ca2+ store.     

Three Ca2+-binding proteins from porcine liver and intestine differ immunologically and physicochemically and are distinct in Ca2+ affinities

Intestinal brush-border-derived membrane vesicles contain, after demembranation in the presence of Ca2+, a subset of polypeptides that are specifically solubilized by the addition of Ca2+ chelators. As described previously, this fractionation scheme leads to the enrichment of two major proteins (I and II), one of which has been shown to be identical to the cellular p36K target of Rous sarcoma virus-encoded tyrosine-specific protein kinase (Gerke, V., and Weber, K., (1984) EMBO J. 3, 227-233). We have applied a similar protocol to membrane vesicles from porcine liver and purified a third Ca2+-binding protein (III). All three proteins had wide tissue distributions, and were absent from brain, red blood cells, and cardiac and skeletal muscle. Relative amounts varied between tissues, with protein I low in liver and protein III very low in intestine. Despite their similar extractability the three proteins (I, II, and III) are clearly distinct as far as immunological, biochemical, and physicochemical properties are concerned. They also show characteristic differences in their affinities for Ca2+ ions. The association constants of Ca2+ binding for proteins I and III have been estimated by means of indirect methods to be 10(4) M-1 (protein I) and 10(6) M-1 (protein III), while the direct Hummel-Dreyer method reveals Ca2+ binding to protein II, characterized by an association constant of 0.4 X 10(5) M-1 in the absence and 0.2 X 10(5) M-1 in the presence of 2 mM MgCl2. Conformational changes upon binding Ca2+ are described for protein II using circular dichroism, fluorescence emission, and UV difference spectra. These alterations could be attributed to an increased exposure of tyrosine and tryptophan residues to a more aqueous environment, and led to increased hydrophobicity of protein II that would explain the observed Ca2+-dependent interaction with hydrophobic matrices like phenyl-Sepharose.     

A citrate-binding site in calmodulin

Calmodulin (CaM) is a major Ca2+ messenger which, upon Ca2+ activation, binds and activates a number of target enzymes involved in crucial cellular processes. The dependence on Ca2+ ion concentration suggests that CaM activation may be modulated by low-affinity Ca2+ chelators. The effect on CaM structure and function of citrate ion, a Ca2+ chelator commonly found in the cytosol and the mitochondria, was therefore investigated. A series of structural and biochemical methods, including tryptic mapping, immunological recognition by specific monoclonal antibodies, CIDNP-NMR, binding to specific ligands and association with radiolabeled citrate, showed that citrate induces conformational modifications in CaM which affect the shape and activity of the protein. These changes were shown to be associated with the C-terminal lobe of the molecule and involve actual binding of citrate to CaM. Analyzing X-ray structures of several citrate-binding proteins by computerized molecular graphics enabled us to identify a putative citrate-binding site (CBS) on the CaM molecule around residues Arg106-His107. Owing to the tight proximity of this site to the third Ca(2+)-binding loop of CaM, binding of citrate is presumably translated into changes in Ca2+ binding to site III (and indirectly to site IV). These changes apparently affect the structural and biochemical properties of the conformation-sensitive protein.     

Calcium-regulated interactions of human alpha-lactalbumin with bee venom melittin

Affinity chromatography, fluorescence and circular dichroism spectroscopy methods have been used to study the interaction of melittin, a 26-residue peptide from bee venom, with Ca2(+)-binding alpha-lactalbumin from human milk. It has been revealed that melittin binds to the apo- and acidic states of alpha-lactalbumin while the presence of Ca2+ makes the interaction essentially weaker. The association constant for the complex of melittin with apo-alpha-lactalbumin determined from spectropolarimetric melittin-titration data is 2 X 10(7) M-1. The complexation of alpha-lactalbumin with melittin decreases its affinity to Ca2+ by three orders of magnitude. The interaction of apo-alpha-lactalbumin with melittin causes some changes in the environment of its aromatic amino acid residues and drastically alters the conformation of melittin, increasing its alpha-helical content but leaving its single tryptophan residue accessible to water. In the case of the acidic state of alpha-lactalbumin the interaction does not induce an increase in alpha-helical content of melittin.     

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.