Biochemical characterization of the penta-EF-hand protein grancalcin and identification of L-plastin as a binding partner.

Grancalcin is a recently described Ca(2+)-binding protein especially abundant in human neutrophils. Grancalcin belongs to the penta-EF-hand subfamily of EF-hand proteins, which also comprises calpain, sorcin, peflin, and ALG-2. Penta-EF-hand members are typified by two novel types of EF-hands: one that binds Ca(2+) although it has an unusual Ca(2+) coordination loop and one that does not bind Ca(2+) but is directly involved in homodimerization. We have developed a novel method for purification of native grancalcin and found that the N terminus of wild-type grancalcin is acetylated. This posttranslational modification does not affect the secondary structure or conformation of the protein. We found that both native and recombinant grancalcin always exists as a homodimer, regardless of the Ca(2+) load. Flow dialysis showed that recombinant grancalcin binds two Ca(2+) per subunit with positive cooperativity and moderate affinity ([Ca(2+)](0.5) of 25 and 83 microm in the presence and absence of octyl glycoside, respectively) and that the sites are of the Ca(2+)-specific type. Furthermore, we showed, by several independent methods, that grancalcin undergoes important conformational changes upon binding of Ca(2+) and subsequently exposes hydrophobic amino acid residues, which direct the protein to hydrophobic surfaces. By affinity chromatography of solubilized human neutrophils on immobilized grancalcin, L-plastin, a leukocyte-specific actin-bundling protein, was found to interact with grancalcin in a negative Ca(2+)-dependent manner. This was substantiated by co-immunoprecipitation of grancalcin by anti-L-plastin antibodies and vice versa.

Brain S100A5 is a novel calcium-, zinc-, and copper ion-binding protein of the EF-hand superfamily.

S100A5 is a novel member of the EF-hand superfamily of calcium-binding proteins that is poorly characterized at the protein level. Immunohistochemical analysis demonstrates that it is expressed in very restricted regions of the adult brain. Here we characterized the human recombinant S100A5, especially its interaction with Ca(2+), Zn(2+), and Cu(2+). Flow dialysis revealed that the homodimeric S100A5 binds four Ca(2+) ions with strong positive cooperativity and an affinity 20-100-fold higher than the other S100 proteins studied under identical conditions. S100A5 also binds two Zn(2+) ions and four Cu(2+) ions per dimer. Cu(2+) binding strongly impairs the binding of Ca(2+); however, none of these ions change the alpha-helical-rich secondary structure. After covalent labeling of an exposed thiol with 2-(4'-(iodoacetamide)anilino)-naphthalene-6-sulfonic acid, binding of Cu(2+), but not of Ca(2+) or Zn(2+), strongly decreased its fluorescence. In light of the three-dimensional structure of S100 proteins, our data suggest that in each subunit the single Zn(2+) site is located at the opposite side of the EF-hands. The two Cu(2+)-binding sites likely share ligands of the EF-hands. The potential role of S100A5 in copper homeostasis is discussed.

Cation- and peptide-binding properties of human centrin 2.

Centrin and calmodulin (CaM) are closely related four-EF-hand Ca(2+)-binding proteins. While CaM is monomeric, centrin 2 is dimeric and binds only two Ca(2+) per dimer, likely to site IV in each monomer. Ca(2+) binding to centrin 2 displays pronounced negative cooperativity and a [Ca(2+)](0.5) of 30 microM. As in CaM, Ca(2+) binding leads to the exposure of a hydrophobic probe-accessible patch on the surface of centrin 2. Provided Ca(2+) is present, centrin 2 forms a 1:1 peptide:monomer complex with melittin with an affinity of 100 nM. The complex binds four instead of two Ca(2+). Our data point to surprising differences in the mode of activation of these homologous proteins.

Two forms of the apoptosis-linked protein ALG-2 with different Ca(2+) affinities and target recognition.

The apoptosis-linked gene ALG-2 encodes a Ca(2+)-binding protein of the penta EF-hand family. To investigate the Ca(2+) binding properties of the recombinant ALG-2 protein, we have cloned ALG-2 cDNA from mouse liver mRNA. Sequence analysis showed that two types of clones were present. One (named ALG-2,5) corresponds to the published ALG-2 sequence (Vito, P., Lacana, E., and D'Adamio, L. (1996) Science 271, 521-525); the second (named ALG-2,1) is 6 nucleotides shorter, and the corresponding protein lacks the amino acid residues Gly(121) and Phe(122). Both transcripts are present in mouse tissues in the same 2:1 molar ratio. The ALG-2,5 and ALG-2,1 recombinant proteins are fully soluble in the metal-free form but can be precipitated from bacterial lysates by Ca(2+). In the presence of Tween the Ca(2+) binding profiles display two high affinity sites with [Ca(2+)](0.5) values of 1.2 and 3.1 microM for ALG-2,5 and ALG-2,1, respectively, plus one low affinity site. Using the yeast two-hybrid system we demonstrate that both proteins have a strong tendency to form homo- and heterodimers. In contrast to ALG-2, 5, the ALG-2,1 isoform does not interact with the target protein AIP-1, earlier described to play a role in apoptosis (Vito, P., Pellegrini, L., Guiet, C., and D'Adamio, L. (1999) J. Biol. Chem. 274, 1533-1540). We propose that the minor sequence difference between ALG-2,5 and ALG-2,1 affects the Ca(2+) binding properties and function of the proteins.

S100A13. Biochemical characterization and subcellular localization in different cell lines.

S100 proteins became of major interest because of their divergent cell- and tissue-specific expression, their close association with a number of human diseases, and their importance for clinical diagnostics. Here, we report for the first time the purification and characterization of human recombinant S100A13. Flow dialysis revealed that the homodimeric S100A13 binds four Ca(2+) in two sets of binding sites, both displaying positive cooperativity but of very different affinity. Fluorescence and difference spectrophotometry indicate that the Trp/Tyr signal changes are almost complete upon binding of Ca(2+) to the two high affinity sites, which probably correspond to the C-terminal EF-hands in each subunit. The far-UV circular dichroic signal also changes upon binding of the first two Ca(2+). So far, the tissue distribution of S100A13 has not been well characterized. Here, we show that S100A13 is widely expressed in various types of tissues with a high expression level in thyroid gland. Using specific antisera against S100A13, high protein expression was detected in follicle cells of thyroid, Leydig cells of testis, and specific cells of brain. In human smooth muscle cells, which co-express S100A2 in the nucleus and S100A1 in stress fibers, S100A13 shows a unique subcellular localization in the perinuclear area. These data suggest diverse functions for this protein in signal transduction.

Remodeling of the AB site of rat parvalbumin and oncomodulin into a canonical EF-hand.

Parvalbumin (PV) and the homologous protein oncomodulin (OM) contain three EF-hand motifs, but the first site (AB) cannot bind Ca2+. Here we aimed to recreate the putative ancestral proteins [D19-28E]PV and [D19-28E]OM by replacing the 10-residue-long nonfunctional loop in the AB site by a 12-residue canonical loop. To create an optical conformational probe we also expressed the homologs with a F102W replacement. Unexpectedly, in none of the proteins did the mutation reactivate the AB site. The AB-remodeled parvalbumins bind two Ca2+ ions with strong positive cooperativity (nH = 2) and moderate affinity ([Ca2+]0.5 = 2 microM), compared with [Ca2+]0.5 = 37 nM and nH = 1 for the wild-type protein. Increasing Mg2+ concentrations changed nH from 2 to 0.65, but without modification of the [Ca2+]0. 5-value. CD revealed that the Ca2+ and Mg2+ forms of the remodeled parvalbumins lost one-third of their alpha helix content compared with the Ca2+ form of wild-type parvalbumin. However, the microenvironment of single Trp residues in the hydrophobic cores, monitored using intrinsic fluorescence and difference optical density, is the same. The metal-free remodeled parvalbumins possess unfolded conformations. The AB-remodeled oncomodulins also bind two Ca2+ with [Ca2+]0.5 = 43 microM and nH = 1.45. Mg2+ does not affect Ca2+ binding. Again the Ca2+ forms display two-thirds of the alpha-helical content in the wild-type, while their core is still strongly hydrophobic as monitored by Trp and Tyr fluorescence. The metal-free oncomodulins are partially unfolded and seem not to possess a hydrophobic core. Our data indicate that AB-remodeled parvalbumin has the potential to regulate cell functions, whereas it is unlikely that [D19-28E]OM can play a regulatory role in vivo. The predicted evolution of the AB site from a canonical to an abortive EF-hand may have been dictated by the need for stronger interaction with Mg2+ and Ca2+, and a high conformational stability of the metal-free forms.

Tyrosine phosphorylation modulates the interaction of calmodulin with its target proteins.

The activation of six target enzymes by calmodulin phosphorylated on Tyr99 (PCaM) and the binding affinities of their respective calmodulin binding domains were tested. The six enzymes were: myosin light chain kinase (MLCK), 3'-5'-cyclic nucleotide phosphodiesterase (PDE), plasma membrane (PM) Ca2+-ATPase, Ca2+-CaM dependent protein phosphatase 2B (calcineurin), neuronal nitric oxide synthase (NOS) and type II Ca2+-calmodulin dependent protein kinase (CaM kinase II). In general, tyrosine phosphorylation led to an increase in the activatory properties of calmodulin (CaM). For plasma membrane (PM) Ca2+-ATPase, PDE and CaM kinase II, the primary effect was a decrease in the concentration at which half maximal velocity was attained (Kact). In contrast, for calcineurin and NOS phosphorylation of CaM significantly increased the Vmax. For MLCK, however, neither Vmax nor Kact were affected by tyrosine phosphorylation. Direct determination by fluorescence techniques of the dissociation constants with synthetic peptides corresponding to the CaM-binding domain of the six analysed enzymes revealed that phosphorylation of Tyr99 on CaM generally increased its affinity for the peptides.

The binding of calcium to the B-repeat segment of SdrD, a cell surface protein of Staphylococcus aureus.

In the Sdr family of Staphylococcus aureus cell surface proteins, three recently cloned members (Josefsson, E., McCrea, K., Ni Eidhin, D., O'Connell, D., Cox, J. A., Hook, M., and Foster, T. (1998) Microbiology, in press) display variable numbers of B-repeats, i.e. segments of 110-113 residues that probably make up one folding unit. Each B-repeat contains one conserved EF-hand motif and two acidic stretches. Equilibrium dialysis revealed that segment B1-B5 of SrdD contains 14 Ca2+-binding sites with high affinity ([Ca2+]0.5, 4 microM), whereas flow dialysis yielded 5 sites of high affinity (class I) and 10 of low affinity (class II). The discrepancy could be explained by the slow induction of high affinity in the class II sites. Kinetic experiments using fluorescent Ca2+ indicators corroborated slow binding of Ca2+ at the latter sites. Circular dichroism and Trp fluorescence showed that, whereas the Ca2+ form is well folded, the metal-free form seems strongly disorganized. The Ca2+-induced conformational changes comprise both fast and slow steps, giving thus a structural support for the induction of class II Ca2+-binding sites. The B-repeats may act as rulers or springs that modulate the distance between the interactive A region and the bacterial cell surface.

Binding of Ca2+ and Zn2+ to human nuclear S100A2 and mutant proteins.

The Ca2+-binding protein S100A2 is an unusual member of the S100 family, characterized by its nuclear localization and down-regulated expression in tumorigenic cells. In this study, we investigated the properties of human recombinant S100A2 (wtS100A2) and of two mutants in which the amino-terminal Ca2+-binding site I (N mutant) and in addition the carboxyl-terminal site II (NC mutant) were replaced by the canonical loop (EF-site) of alpha-parvalbumin. Size exclusion chromatography and circular dichroism showed that, irrespective of the state of cation binding, wtS100A2 and mutants are dimers and rich in alpha-helical structure. Flow dialysis revealed that wtS100A2 binds four Ca2+ atoms per dimer with pronounced positive cooperativity. Both mutants also bind four Ca2+ atoms but with a higher affinity than wtS100A2 and with negative cooperativity. The binding of the first two Ca2+ ions to the N mutant occurred with 100-fold higher affinity than in wtS100A2 and a 2-fold increase for the last two Ca2+ ions. A further 2-3-fold increase of affinity was observed for respective binding steps of the NC mutant. The Hummel-Dryer method demonstrated that the wild type and mutants bind four Zn2+ atoms per dimer with similar affinity. Fluorescence and difference spectrophotometry showed that the binding of Ca2+ and Zn2+ induces considerable conformational changes, mostly attributable to changes in the microenvironment of Tyr76 located in site II. Fluorescence enhancement of 4,4'-dianilino-1, 1'-binaphthyl-5,5'-disulfonic acid clearly indicated that Ca2+ and Zn2+ binding induce a hydrophobic patch at the surface of wtS100A2, which, as in calmodulin, may be instrumental for the regulatory role of S100A2 in the nucleus.

Phosphorylation of calmodulin alters its potency as an activator of target enzymes.

Previous work has shown that calmodulin (CaM) is constitutively phosphorylated in rat liver, probably by casein kinase II [Quadroni, M., James, P., and Carafoli, E. (1994) J. Biol. Chem. 269, 16116-16122]. A procedure is now described for the isolation of the phosphorylated forms of calmodulin (PCaM) free from CaM, since in vitro phosphorylation experiments yield a 50:50 mixture of 3-4 times phosphorylated CaM and native CaM. The activation of six target enzymes by PCaM was tested: myosin light chain kinase, 3',5'-cyclic nucleotide phosphodiesterase, plasma membrane Ca2+-ATPase, Ca2+-CaM-dependent protein phosphatase 2B (calcineurin), neuronal nitric oxide synthase, and CaM-kinase II. In general, the phosphorylation of CaM caused a decrease in enzyme binding affinity, increasing the Kact by 2-4-fold for MLCK, PDE, PM Ca2+-ATPase, and calcineurin. The Vmax at saturating concentrations of PCaM was less affected, with the exception of CaM-kinase II, which was only minimally activated by PCaM and NOS whose Vmax was increased 2.6 times by PCaM with respect to CaM. Phosphorylation of calmodulin had very little effect on the binding of calcium to the enzyme despite the fact that Ser 101 which is phosphorylated is located in the third calcium binding loop. CD measurements performed on CaM and PCaM indicated that phosphorylation causes a marked decrease in the alpha-helical content of the protein. Phosphorylated CaM is very prone to dephosphorylation and was thus tested as a substrate for several phosphatases. It was unaffected by calcineurin (PP2B), but was a reasonable substrate for the pleiotropic phosphatases PP1gamma and PP2A.

Comparison of the Ca2+-binding properties of human recombinant calretinin-22k and calretinin.

Calretinin-22k (CR-22k) is a splice product of calretinin (CR) found specifically in cancer cells, and possesses four EF-hands and a differently processed C-terminal end. The Ca2+-binding properties of recombinant human calretinin CR-22k were investigated by flow dialysis and spectroscopic methods and compared with those of CR. CR possesses four Ca2+-binding sites with positive cooperativity (nH = 1.3) and a [Ca2+]0.5 of 1.5 microM, plus one low affinity site with an intrinsic dissociation constant (K'D) of 0.5 mM. CR-22k contains three Ca2+-binding sites with nH of 1.3 and [Ca2+]0.5 of 1.2 microM, plus a low affinity site with K'D of 1 mM. All the sites seem to be of the Ca2+-specific type. Limited proteolysis and thiol reactivity suggest that that the C terminus of full-length CR, but not of CR-22k, is in close proximity of site I leading to mutual shielding. Circular dichroism (CD) spectra predict that the content of alpha-helix in CR and CR-22k is similar and that Ca2+ binding leads to very small changes in the CD spectra of both proteins. The optical properties are very similar for CR-22k and CR, even though CR-22k possesses one additional Trp at the C-terminal end, and revealed that the Trp residues are organized into a hydrophobic core in the metal-free proteins and become even better shielded from the aqueous environment upon binding of Ca2+. The fluorescence of the hydrophobic probe 2-p-toluidinylnaphtalene-6-sulfonate is markedly enhanced by the two proteins already in the absence of Ca2+ and is further increased by binding of Ca2+. The trypsinolysis patterns of CR and CR-22k are markedly dependent on the presence or absence of Ca2+. Together, our data suggest the presence of an allosteric conformational unit encompassing sites I-III for CR-22k and I-IV for CR, with a very similar conformation and conformational changes for both proteins. In the allosteric unit of CR, site IV is fully active, whereas in CR-22k this site has a 80-fold decreased affinity, due to the decreased amphiphilic properties of the C-terminal helix of this site. Some very specific Ca2+-dependent conformational changes suggest that both CR and CR-22k belong to the "sensor"-type family of Ca2+-binding proteins.

Ion-binding properties of recombinant S100beta and two derivatives with either an inactivated Ca2+ site II or a normalized Ca2+ site I.

S100beta contains one unusual and one canonical Ca2+-binding motif. In this study, we measured Ca2+-binding and ensuing conformational changes of recombinant S100beta (rS100beta) and of two mutant forms in which either the canonical loop was inactivated (NoEF) or the unusual one replaced by a canonical one (Caloops). Caloops binds two Ca2+ per monomer with a 3-fold higher affinity than rS100beta; the affinity of NoEF was too low for accurate direct determination. All three proteins bind 3-4 Zn2+ per monomer. Tyrosine 17 fluorescence spectra showed a decrease of intensity upon binding of Ca2+ to the three proteins and an increase upon binding of Zn2+ to rS100beta and NoEF but not in Caloops. The fluorescence change as a function of the Ca2+ concentration yielded half-maximal changes ([Ca2+]0.5) at 1.7, 11.3 and 0.55 mM free Ca2+ for rS100beta NoEF and Caloops, respectively. Our data demonstrate that in S100beta alterations in one site can affect the Ca2+ binding properties of the other site.

Site-specific replacement of amino acid residues in the CD site of rat parvalbumin changes the metal specificity of this Ca2+/Mg(2+)-mixed site toward a Ca(2+)-specific site.

Rat parvalbumin (PV) and oncomodulin (OM) display considerable sequence similarity and structural similarity, but differ in the affinity and selectivity of metal binding to their CD site, a Ca2+/Mg(2+)-mixed site in PV and a Ca(2+)-specific site in OM. In an attempt to identify the structural basis for these differences, mutations were introduced in the previously generated [W102]PV mutant, which contains a unique tryptophan as a conformational-sensitive fluorescent probe inside the hydrophobic core. In the present report, we substituted selected amino acid residues in the CD site of PV by those present at identical positions in OM. One mutant protein, named [F66, W102]PV, has one new substitution in which isoleucine at position 66 was exchanged by phenylalanine. The second mutant protein, [I46, I50, L58, F66, W102]PV, has four new substitutions, namely V46-->I, L50-->I, I58-->L and I66-->F. Tryptophan fluorescence and difference spectrophotometry indicated that the mutations do not alter significantly the hydrophobic core. Both mutant proteins display two metal-binding sites of identical affinities with intrinsic affinity constants K'Ca2+ of 2.9 x 10(7) M-1 for [F66, W102]PV and 1.7 x 10(7) M-1 for [I46, I50, L58, F66, W102]PV and K'Mg2+ of 3.1 x 10(4) M-1 for [F66, W102]PV and 1.9 x 10(4) M-1 for [I46, I50, L58, F66, W102]PV. Thus, the five-residue substitution, but not the two-residue one, leads to a small decrease of affinity compared to [W102]PV (K'Ca2+ = 2.7 x 10(7) M-1, K'Mg2+ = 4.4 x 10(4) M-1). Despite these similarities, the Mg2+ effect on Ca2+ binding is different for the two mutant parvalbumins: the Ca(2+)-binding isotherms of [F66, W102]PV undergo a parallel shift upon increasing Mg2+ concentrations, which indicates that the Mg2+ effect on the two Ca(2+)-binding sites is the same and quantitatively very similar to that described for [W102]PV. In [I46, I50, L58, F66, W102]PV, Mg2+ antagonizes the binding of the second Ca2+ (likely at the EF site) much more than that of the first Ca2+ (likely the CD site). According to the competition equation, the two sites display KMg2+.compet values of 390 M-1 and 3.9 x 10(3) M-1, respectively. These data indicate that (a) the single I66-->F mutation does not modify the cation binding parameters. (b) Multiple modifications in the hydrophobic core still do not change the affinity for Ca2+ and Mg2+, but strongly affect the Mg2+ antagonism and probably the selectivity of the CD site.

Chimeras of parvalbumin and oncomodulin involving exchange of the complete CD site show that the Ca2+/Mg2+ specificity is an intrinsic property of the site.

Rat parvalbumin (PV) and oncomodulin (OM) differ in the affinity and selectivity of metal binding to their CD site, which is a high-affinity Ca2+/Mg(2+)-mixed site in PV and a low-affinity Ca(2+)-specific site in OM. To assess to what degree the Ca2+/Mg2+ specificity and affinity of an EF-hand motif in a protein is intrinsically determined by its sequence, the complete CD sites were exchanged, yielding two chimeras, [S41-Q71]PV and [D41-S71]OM. The optical characteristics of a Trp102, inserted in the hydrophobic core of PV, OM and the two chimeras, are very similar in all four proteins, which suggests that the hydrophobic core is qualitatively similar in the chimeras as in the parent proteins. Direct Ca2+ and Mg2+ binding monitored by flow dialysis and gel filtration revealed that [S41-Q71]PV binds only one Mg2+ with an intrinsic affinity K'Mg2+ of 3.0 x 10(4) M-1 and two Ca2+ with an identical K'Ca2+ of 4.4 x 10(6) M-1, whereas [D41-S71]OM binds two Mg2+ with a mean K'Mg2+ of 2 x 10(4) M-1 and two Ca2+ with a K'Ca2+ of 1.3 x 10(7) M-1. K'Ca2+ of the CD site of [S41-Q71]PV was 2.5-fold higher than of the CD site in [W102]OM, but 5-6-fold lower than that of the CD site in [W102]PV. In [D41-S71]OM, K'Ca2+ of the CD site was twofold lower than in [W102]PV, but eightfold higher than in [W102]OM. These results indicate that the sequence of the CD site determines its Ca2+/Mg(2+)-specificity, whereas its affinity for Ca2+ influenced by the protein into which the CD site is inserted. The inserted CD site in turn influences the affinity of the EF site to which it is paired in the host protein and the paired sites display an equalized affinity for Ca2+. Mg2+ decreases the affinity of the chimeras for Ca2+, but not according to a simple competition model. The Mg2+ antagonism is much more pronounced in [D41-S71]OM than in [S41-Q71]PV, but in each chimera the CD and EF site are quantitatively affected in the same manner. Thus, [S41-Q71]PV which can only bind a single Mg2+ ion, displays a Ca2+/Mg(2+)-antagonism for both sites with a KMg.compet of 2.3 x 10(2) M-1. These results confirm the 'equalizer' principle in the cation-binding parameters of [S41-Q71]PV: both sites display the same Ca2+ affinity and Mg2+ antagonism. In [D41-S71]OM with its two Ca2+/Mg2+ sites the antagonism shows qualitatively the same complexity as in wild-type PV, although it is somewhat weaker in amplitude.

Human recombinant alpha-parvalbumin and nine mutants with individually inactivated calcium- and magnesium-binding sites: biochemical and immunological properties.

Human recombinant alpha-parvalbumin (PVwt) and nine mutant proteins, containing inactivating substitutions at positions essential for Ca2+ binding in the CD Ca(2+)-binding site (PVE62V, PVD51A, PVD51A,62V), the EF site (PVE101V, PVD90A, PVD90A,E101V) or in both (PVE62V,E101V, PVD51A,D90A, PVD51A,E62V,D90A,E101V), were expressed and purified. Flow dialysis revealed that PVwt binds 2 Ca2+ with equal K'Ca, of 2.3 x 10(7) M-1 and that Mg2+ competes with a K'Mg.compet. of 4.9 x 10(3) M-1. The three mutants with an inactivated CD site bind 1 Ca2+ with K'Ca, of 2.0 to 2.3 x 10(7) M-1 and K'Mg.compet. of 3.4 to 4.6 x 10(3) M-1, i.e. very similar to those of PVwt. The mutants with an inactivated EF site bind 1 Ca2+ with K'Ca values of 7.9 x 10(6), 4.5 x 10(6) and 3.6 x 10(6) M-1 for PVD91A, PVE102V and PVE101V,D91A, respectively. The K'Mg.compet values of these mutants are about 4-times lower than in PVwt. The three mutants with both sites inactivated bind neither Ca2+ nor Mg2+. After excitation at 259 nm, human PV, which contains neither Tyr nor Trp, shows maximal fluorescence emission at 283 nm. Binding of either Ca2+ or Mg2+ to PVwt or to mutants with an inactivated EF site lead to a 1.8-fold decrease in fluorescence intensity, whereas the mutants with an inactivated CD show only a very slight decrease upon binding of Ca2+ or Mg2+. Specific antibodies against human alpha-parvalbumin were raised in rabbits. Their reactivity was tested against the mutant proteins, and their potential value for location and functional studies was investigated.

Characterization of the Ca2+-binding properties of calgizzarin (S100C) isolated from chicken gizzard smooth muscle.

Calgizzarin is a Ca2+-binding protein of the S100 family that has been implicated in the regulation of cytoskeletal function through its Ca2+-dependent interaction with annexin I. The Ca2+-binding properties of calgizzarin (S100C) have not previously been thoroughly characterized. Calgizzarin, therefore, was purified from chicken gizzard smooth muscle by exploiting its Ca2+-dependent interaction with the hydrophobic matrix phenyl-Sepharose and is shown by 45Ca2+ overlay to bind Ca2+ more weakly than does calmodulin. Gel filtration in the absence and presence of Ca2+ suggested a dimeric structure of calgizzarin and indicated a more compact structure in the presence of Ca2+. Flow dialysis experiments indicated that, at physiological ionic strength, calgizzarin binds two Ca2+ ions per monomer (four per native dimer), as predicted from the deduced amino acid sequence which contains two putative EF-hands, with [Ca2+]0.5 of 0.52 mM and nH of 1.4 in the absence of Mg2+ and [Ca2+]0.5 of 0.3 mM and nH of 1.2 in the presence of 10 mM mgCl2. The hydrophobic fluorescent probe 2-p-toluidinylnaphthalene-6-sulphonate was used to demonstrate Ca(2+)-dependent exposure of a hydrophobic site(s) in calgizzarin. This approach also indicated the ability of calgizzarin to bind Zn2+. Interestingly, the affinity of calgizzarin for Ca2+ was enhanced approximately 10-fold in the presence of the hydrophobic probe, possibly reflecting an increased affinity for Ca2+ when calgizzarin binds to a target protein. Finally, the distribution of calgizzarin among chicken tissues was examined by immunoblotting: calgizzarin was expressed at its highest levels in lung tissue, followed by smooth muscle tissues (oesophagus, large intestine, trachea, and gizzard), kidney, liver, brain, and heart; it was not detected in small intestine or skeletal muscle.

Cation binding and conformational changes in VILIP and NCS-1, two neuron-specific calcium-binding proteins.

VILIP and NCS-1, neural-specific, 22-kDa Ca(2+)-binding proteins possessing four EF-hands, were expressed in Escherichia coli to study their divalent cation properties. Flow dialysis (Ca2+ binding) and equilibrium gel filtration (Mg2+ binding) revealed that both recombinant proteins possess only two active metal-binding sites, which can accommodate either Ca2+ or Mg2+. VILIP binds cations without cooperativity with intrinsic affinity constants K'Ca of 1.0 x 10(6) M-1 and K'Mg of 4.8 x 10(3) M-1.Mg2+ antagonizes Ca2+ binding by shifting the isotherms to higher free Ca2+ concentrations without changing their shape. The competition equation yields a K'Mg, comp value of 180 M-1 for both sites. NCS-1 binds two Mg2+ without cooperativity with K'Mg of 8.3 x 10(4) M-1 and two Ca2+ with very strong positive cooperativity (nH = 1.96). In the absence of Mg2+ the K'Ca1 and K'Ca2 values are 8.9 x 10(4) and 1.4 x 10(8) M-1, respectively, which represent an allosteric increase of 1600-fold. Mg2+ shifts the Ca(2+)-binding isotherms to higher Ca2+ concentrations, yielding a K'Mg, comp value of 800 M-1 for both sites. Thus VILIP and NCS-1 show three remarkable differences in the Ca2+/Mg2+ binding parameters: 1) VILIP binds Ca2+ with much lower affinity than NCS-1; 2) VILIP binds Ca2+ in a noncooperative way, whereas NCS-1 shows maximal positive cooperativity; 3) in VILIP the Mg2+/Ca2+ antagonism is much weaker than in NCS-1. Conformational changes monitored by Trp fluorescence indicate that the metal-free forms already are highly structured. Ca2+ binding promotes a 20-30% increase of fluorescence in both proteins, but whereas the Mg2+ form of VILIP has the same fluorescence properties as the metal-free form, Mg(2+)-saturated NCS-1 has those of the Ca2+ form. Near UV difference spectra confirmed that in VILIP the Mg2+ form is very similar to the metal-free form; in NCS-1 it is different, especially in the Tyr region. NCS-1 possesses one unique Cys-38 in EF-hand site I. Its reactivity (kSH) toward 5,5'-dithiobis-(2-nitrobenzoic acid) (DTNB) is the same for the Ca(2+)- and Mg(2+)-loaded protein, but kSH is 4-fold higher in metal-free NCS-1. VILIP possesses two additional thiols, one of which is inaccessible to DTNB in the native protein. The reactivity of the two accessible thiols is identical in the metal-free and Mg2+ forms and 5-fold higher than in the Ca2+ form.(ABSTRACT TRUNCATED AT 400 WORDS)

Inactivation of individual Ca(2+)-binding sites in the paired EF-hand sites of parvalbumin reveals asymmetrical metal-binding properties.

Previously a rat parvalbumin mutant protein PVF102W was constructed with a reporter Trp at position 102 in the middle of the hydrophobic center [Pauls, T. L., et al. (1993) J. Biol. Chem. 268, 20897-20903]. In the present study three new parvalbumin mutant proteins, derived from PVF102W and containing alterations at positions essential for Ca2+ binding in either one of the two Ca(2+)-binding sites (PV-CD and PV-EF) or in both (PV-CD/-EF), were expressed and purified. With the flow dialysis method it was established that both PV-CD and PV-EF bind 1 Ca2+ with affinity constants KCa of 1.1 x 10(7) and 3.2 x 10(6) M-1, respectively. Mg2+ binding, monitored by equilibrium gel filtration in the absence of Ca2+, showed that both mutants bind 1 Mg2+ with KMg = 8 10(4) for PV-CD and 3 x 10(3) M-1 for PV-EF. Compared to the parameters of the parent mutant PVF102W (two sites with equal affinities of 2.7 x 10(7) and 3 x 10(4) M-1 for Ca2+ and Mg2+, respectively), these data indicate that inactivation of the EF site, much more than of the CD site, impairs divalent cation binding. The binding of Ca2+ and Mg2+ is mutually exclusive, indicative of a Ca2+/Mg2+ mixed site. However, as for PVF102W, the KMg values obtained from the competition equation are approximately 40-fold lower than the affinities measured by direct binding. PV-CD/-EF binds neither Ca2+ nor Mg2+. Trp fluorimetry revealed that in the three mutant PVs the residue Trp-102 is deeply buried in the hydrophobic core.(ABSTRACT TRUNCATED AT 250 WORDS)

Purification and characterization of the recombinant human calcium-binding S100 proteins CAPL and CACY.

The S100 proteins CAPL and CACY are expressed in a tissue- and cell-specific manner and have been reported to be associated with the metastatic phenotype of tumor cells. In order to study the biochemical, cation-binding, and conformational properties, we produced and purified large amounts of the recombinant human proteins in Escherichia coli. Several characteristics of native proteins are shown to correspond to those of the bacterially expressed proteins. Both are able to form homodimers in vitro, probably the biologically active species, but not heterodimers. The Ca(2+)-binding parameters were studied by flow offlysis at physiological ionic strength. Both isotherms show a maximum of two Ca2+ per protein and are insensitive to Mg2+, indicating that the sites are of the Ca(2+)-specific type. The isotherms show slight (CAPL, nH = 1.15) or pronounced (CACY, nH = 1.33) positive cooperativity with K0.5 values of 0.32 mM (CACY) and 0.15 mM (CAPL), indicating that the sites are of the low-affinity type. Conformational changes in the Tyr microenvironment of CACY indicate that Ca2+ binding induces a shift of Tyr to a less polar environment. Mg2+ does not affect the fluorescence properties nor does it induce a difference spectrum, thus suggesting that at physiological ionic conditions it does not interact with the protein. The Ca(2+)-induced difference spectra of CAPL are about 3 times smaller than those of CACY, suggesting that the additional Tyr84 in CACY is much more sensitive to Ca2+ than the two Tyr residues conserved in both proteins.

Metal binding properties of recombinant rat parvalbumin wild-type and F102W mutant.

Rat parvalbumin (PV), an EF-hand type Ca(2+)-binding protein, was expressed in Escherichia coli and mutated by replacing a Phe at position 102 with a unique Trp in order to introduce a distinct fluorescent label into the protein. Mass spectroscopy and NMR data indicate that the recombinant wild-type (PVWT) and F102W mutant (PVF102W) proteins have the expected molecular weight and retain the native structure. Both proteins contain two non-cooperative Ca2+/Mg(2+)-binding sites with intrinsic affinity constants, KCa and KMg, of 2.4 +/- 0.9 x 10(7) M-1 and of 2.9 +/- 0.2 x 10(4) M-1, respectively, for PVWT, and KCa and KMg, of 2.7 +/- 1.1 x 10(7) M-1 and of 4.4 +/- 0.3 x 10(4) M-1, respectively, for PVF102W. Based on the highly similar metal binding properties of PVWT and PVF102W the latter protein was used to study cation-dependent conformational changes. Trp fluorescence emission and UV difference spectra of PVF102W indicated that the Trp residue at position 102 is confined to a hydrophobic core and conformationally strongly restricted. Upon Ca2+ or Mg2+ binding the structural organization of the region around the Trp is hardly affected, but there are significant changes in its electrostatic environment. The conformational change upon binding of Ca2+ and Mg2+, as monitored by UV difference spectrophotometry, increases linearly from 0 to 2 cations bound, indicating that the binding of both ions contributes equally to the structural organization in this protein.