Insulin-metal ion interactions: the binding of divalent cations to insulin hexamers and tetramers and the assembly of insulin hexamers

An insulin hexamer containing one B10-bound Co(III) ion and one unoccupied B10 site has been synthesized. The properties of the monosubstituted hexamer show that occupancy of only one B10 site by Co3+ is sufficient to stabilize the hexameric form under the conditions of pH and concentration used in these studies. The experimentally determined, second-order rate constants for the binding of Zn2+ and Co2+ to the unoccupied B10 site are consistent with literature rate constants for the rate of association of these divalent metal ions with similar small molecule ligands. These findings indicate that the rate-limiting steps for Zn2+ and Co2+ binding involve the removal of the first aqua ligand. The rate constant for the binding of Cd2+ is significantly lower than the literature values for small molecule chelators, which suggests that some other protein-related process is rate-limiting for Cd2+ binding to the unoccupied, preformed B10 site. The kinetics of the assembly of insulin in the presence of limiting metal ion provides strong evidence indicating that the B13 site of the tetramer species can bind Zn2+, Cd2+, or Ca2+ prior to hexamer formation and that such binding assists hexamer formation. Both the tetramer and the hexamer B13 sites were found to exhibit similar affinities for Zn2+ and Cd2+ (Kd congruent to 9 microM), whereas the tetramer B13 sites bind Ca2+ much more weakly (Kd congruent to 1 mM for tetramer vs 83 microM for hexamer). The second-order rate constants estimated for the association of Zn2+ and Cd2+ to the tetrameric site indicate that the loss of the first inner-sphere aqua ligand is the rate-limiting step for binding.     

Structural differences in the two calcium binding sites of the porcine intestinal calcium binding protein: a multinuclear NMR study

Cadmium-113 and calcium-43 NMR spectra of Cd2+ and Ca2+ bound to the porcine intestinal calcium binding protein (ICaBP; Mr 9000) contain two resonances. The first resonance is characterized by NMR parameters resembling those found for these cations bound to proteins containing the typical helix-loop-helix calcium binding domains of parvalbumin, calmodulin, and troponin C, which are defined as EF-hands by Kretsinger [Kretsinger, R. H. (1976) Annu. Rev. Biochem. 45, 239]. The second resonance in both spectra has a unique chemical shift and is consequently assigned to the metal ion bound in the N-terminal site of ICaBP. This site is characterized by an insertion of a proline in the loop of the helix-loop-helix domain and will be called the pseudo-EF-hand site. The binding of Cd2+ to the apo form of ICaBP is sequential. The EF-hand site is filled first. Both binding sites have similar, but not identical, affinities for Ca2+: at a Ca2+ to protein ratio of 1:1, 65% of the ion is bound in the EF-hand site and 35% in the pseudo-EF-hand site. The two sites do not appear to act independently; thus, replacement of Ca2+ or Cd2+ by La3+ in the EF-hand site causes changes in the environment of the ions in the pseudo-EF-hand site. In addition, the chemical shift of Cd2+ bound to the EF-hand site is dependent on the presence or absence of Ca2+ or Cd2+ in the pseudo-EF-hand site.(ABSTRACT TRUNCATED AT 250 WORDS)     

Quantitative measurements of the cooperativity in an EF-hand protein with sequential calcium binding.

Positive cooperativity, defined as an enhancement of the ligand affinity at one site as a consequence of binding the same type of ligand at another site, is a free energy coupling between binding sites. It can be present both in systems with sites having identical ligand affinities and in systems where the binding sites have different affinities. When the sites have widely different affinities such that they are filled with ligand in a sequential manner, it is often difficult to quantify or even detect the positive cooperativity, if it occurs. This study presents verification and quantitative measurements of the free energy coupling between the two calcium binding sites in a mutant form of calbindin D9k. Wild-type calbindin D9k binds two calcium ions with similar affinities and positive cooperativity--the free energy coupling, delta delta G, is around -8 kJ.mol-1 (Linse S, et al., 1991, Biochemistry 30: 154-162). The mutant, with the substitution Asn 56-->Ala, binds calcium in a sequential manner. In the present work we have taken advantage of the variations among different metal ions in terms of their preferences for the two binding sites in calbindin D9k. Combined studies of the binding of Ca2+, Cd2+, and La3+ have allowed us to conclude that in this mutant delta delta G < -6.4 kJ.mol-1, and that Cd2+ and La3+ also bind to this protein with positive cooperativity. The results justify the use of the (Ca2+)1 state of the Asn 56-->Ala mutant, as well as the (Cd2+)1 state of the wild type, as models for the half-saturated states along the two pathways of cooperative Ca2+ binding in calbindin D9k.     

A flow-dialysis method for obtaining relative measures of association constants in calmodulin-metal-ion systems.

A flow-dialysis apparatus suitable for the study of high-affinity metal-binding proteins has been utilized to study calmodulin-metal exchange as a measure of relative calmodulin-metal association constants. Calmodulin labelled with radioactive 153Gd was dialysed against buffer containing various competing metal ions. The rate of label exchange was monitored by a gamma-ray scintillation detector. Competing metals used were Ca2+ and Cd2+, and the lanthanides Gd3+, Eu3+, La3+ and Lu3+. All exchange processes were first-order, and two categories of metal were found: Ca2+ and Cd2+ in one, the lanthanides comprising the other. In addition calmodulin-metal complexes with radioactive 109Cd and 45Ca released the bound label without any competing metal being added to the buffer. The kinetics of this metal loss can be described by two consecutive first-order processes, and the fraction of label associated with each rate can be determined. Studies of phosphodiesterase activation by calmodulin show Cd2+ and calmodulin to cause 80% of the maximum activation found when Ca2+ and calmodulin are used.     

Kinetics of conformational changes induced by the binding of various metal ions to bovine alpha-lactalbumin.

The kinetic effects of the binding of various metal ions (Ca(2+), Cd(2+), Co(2+), Mg(2+), Mn(2+), Sr(2+) and Zn(2+)) to apo bovine alpha-lactalbumin has been monitored by means of stopped-flow fluorescence spectroscopy. Our results show that the measured rate constant for the binding of metal ions to the Ca(2+)-site increases with increasing binding constant. This is, however, not the case for metal ions binding to the Zn(2+)-site. The binding experiments performed at different temperatures allowed us to calculate the activation energy for the transition from the metal-free to the metal-loaded state of the protein. These values do not depend on the nature of the metal ion but are correlated with the type of binding site. As a result, we were able to demonstrate that Mg(2+), a metal ion which was thought to bind to the Ca(2+)-site, shows the same binding characteristics as Co(2+) and Zn(2+) and therefore most likely interacts with the residues belonging to the Zn(2+)-binding site.     

Evidence for noncooperative metal binding to the alpha domain of human metallothionein

In the present study, we investigated the metal-binding reactivity of the isolated alpha domain of human metallothionein isoform 1a, with specific emphasis on resolving the debate concerning the cooperative nature of the metal-binding mechanism. The metallation reaction of the metal-free alpha domain with Cd2+ was unequivocally shown to proceed by a noncooperative mechanism at physiologic pH by CD and UV absorption spectroscopy and ESI MS. The data clearly show the presence of intermediate partially metallated metallothionein species under limiting Cd2+ conditions. Titration with four molar equivalents of Cd2+ was required for the formation of the Cd4alpha species in 100% abundance. The implications of a noncooperative metal-binding mechanism are that the partially metallated and metal-free species are stable intermediates, and thus may have a potential role in the currently undefined function of metallothionein.     

Metal binding of metallothionein-3 versus metallothionein-2: lower affinity and higher plasticity

Mammalian metallothioneins (MTs) are involved in cellular metabolism of zinc and copper and in cytoprotection against toxic metals and reactive oxygen species. MT-3 plays a specific role in the brain and is down-regulated in Alzheimer's disease. To evaluate differences in metal binding, we conducted direct metal competition experiments with MT-3 and MT-2 using electrospray ionization mass spectroscopy (ESI-MS). Results demonstrate that MT-3 binds Zn2+ and Cd2+ ions more weakly than MT-2 but exposes higher metal-binding capacity and plasticity. Titration with Cd2+ ions demonstrates that metal-binding affinities of individual clusters of MT-2 and MT-3 are decreasing in the following order: four-metal cluster of MT-2>three-metal cluster of MT-2 approximately four-metal cluster of MT-3>three-metal cluster of MT-3>extra metal-binding sites of MT-3. To evaluate the reasons for weaker metal-binding affinity of MT-3 and the enhanced resistance of MT-3 towards proteolysis under zinc-depleted cellular conditions, we studied the secondary structures of apo-MT-3 and apo-MT-2 by CD spectroscopy. Results showed that apo-MT-3 and apo-MT-2 have almost equal helical content (approximately 10%) in aqueous buffer, but that MT-3 had slightly higher tendency to form alpha-helical secondary structure in TFE-water mixtures. Secondary structure predictions also indicated some differences between MT-3 and MT-2, by predicting random coil for common MTs, but 22% alpha-helical structure for MT-3. Combined, all results highlight further differences between MT-3 and common MTs, which may be related with their functional specificities.     

Spectroscopic studies on cadmium (II)- and cobalt(II)-substituted metallothionein from the crab Cancer pagurus. Evidence for one additional low-affinity metal-binding site

The binding of diamagnetic Cd(II) and paramagnetic Co(II) ions to the metal-free form of crab, Cancer pagurus, metallothionein (MT) was studied by various spectroscopic techniques. Both reconstituted and native Cd(II)-MT containing 6 mol Cd(II)/mol protein display electronic absorption, circular dichroism (CD) and magnetic circular dichroism (MCD) spectra which were indistinguishable. The stoichiometric replacement of Cd(II) ions in native Cd(II)6-MT by paramagnetic Co(II) ions enabled the geometry of the metal-binding sites to be probed. The electronic absorption and MCD spectra of Co(II)6-MT revealed features characteristic of distorted tetrahedral tetrathiolate Co(II) coordination for all six metal-binding sites. The stepwise incorporation of Cd(II) and Co(II) ions into this protein was monitored by electronic absorption and CD, and by electronic absorption and EPR spectroscopy, respectively. The results indicate that the metal-thiolate cluster structure is generated when more than four metal ions are bound. Below this titration point separate tetrahedral tetrathiolate complexes exist. This suggests that the cluster formation occurs in a two-step process. Furthermore, the spectroscopic features in both Cd(II)- and Co(II)-metal derivatives above the full metal occupancy of six suggest the existence of one additional metal-binding site. The subsequent loss of one Cd(II) ion from crab Cancer Cd(II)7-MT in the gel filtration studies demonstrate the low metal-binding affinity of the latter site. While the spectroscopic properties indicate an exclusively tetrahedral type of metal-thiolate sulfur coordination for the binding of the first six metal ions, they suggest that the seventh metal ion is coordinated in a different fashion.     

Structural and binding studies of the three-metal center in two mycobacterial PPM Ser/Thr protein phosphatases

Phospho-Ser/Thr protein phosphatases (PPs) are dinuclear metalloenzymes classed into two large families, PPP and PPM, on the basis of sequence similarity and metal ion dependence. The archetype of the PPM family is the α isoform of human PP2C (PP2Cα), which folds into an α/β domain similar to those of PPP enzymes. The recent structural studies of three bacterial PPM phosphatases, Mycobacterium tuberculosis MtPstP, Mycobacterium smegmatis MspP, and Streptococcus agalactiae STP, confirmed the conservation of the overall fold and dinuclear metal center in the family, but surprisingly revealed the presence of a third conserved metal-binding site in the active site. To gain insight into the roles of the three-metal center in bacterial enzymes, we report structural and metal-binding studies of MtPstP and MspP. The structure of MtPstP in a new trigonal crystal form revealed a fully active enzyme with the canonical dinuclear metal center but without the third metal ion bound to the catalytic site. The absence of metal correlates with a partially unstructured flap segment, indicating that the third manganese ion contributes to reposition the flap, but is dispensable for catalysis. Studies of metal binding to MspP using isothermal titration calorimetry revealed that the three Mn²⁺-binding sites display distinct affinities, with dissociation constants in the nano- and micromolar range for the two catalytic metal ions and a significantly lower affinity for the third metal-binding site. In agreement, the structure of inactive MspP at acidic pH was determined at atomic resolution and shown to lack the third metal ion in the active site. Structural comparisons of all bacterial phosphatases revealed positional variations in the third metal-binding site that are correlated with the presence of bound substrate and the conformation of the flap segment, supporting a role of this metal ion in assisting enzyme-substrate interactions.     

Distinct metal ion binding sites on Ca(2+)-activated K+ channels in inside-out patches of human erythrocytes.

Effects of Cd2+, Co2+, Pb2+, Fe2+ and Mg2+ (1-100 microM) on single-channel properties of the intermediate conductance Ca(2+)-activated K+ (CaK) channels were investigated in inside-out patches of human erythrocytes in a physiological K+ gradient. Cd2+, Co2+ and Pb2+, but not Fe2+ and Mg2+, were able to induce CaK channel openings. The potency of the metals to open CaK channels in human erythrocytes follows the sequence Pb2+, Cd2+ > Ca2+ > or = Co2+ > Mg2+, Fe2+. At higher concentrations Pb2+, Cd2+ and Co2+ block the CaK channel by reducing the opening frequency and the single-channel current amplitude. The potency of the metals to reduce CaK channel opening frequency follows the sequence Pb2+ > Cd2+, Co2+ > Ca2+, which differs from the potency sequence Cd2+ > Pb2+, Co2+ > Ca2+ to reduce the unitary single-channel current amplitude. Fe2+ reduced the channel opening frequency and enhanced the two open times of CaK channels activated by Ca2+, whereas up to 100 microM Mg2+ had no effect on any of the measured single-channel parameters. It is concluded that the activation of CaK channels of human erythrocytes by various metal ions occurs through an interaction with the same regulatory site at which Ca2+ activates these channels. The different potency orders for the activating and blocking effects suggest the presence of at least one activation and two blocking sites. A modulatory binding site for Fe2+ exists as well. In addition, the CaK channels in human erythrocytes are distinct from other subtypes of Ca(2+)-activated K+ channels in their sensitivity to the metal ions.     

Ca2+-dependent regulation of calmodulin binding and adenylate cyclase activation in bovine cerebellar membranes

The binding parameters of 125I-labeled calmodulin to bovine cerebellar membranes have been determined and correlated with the activation of adenylate cyclase by calmodulin. In the presence of saturating levels of free Ca2+ calmodulin binds to a finite number of specific membrane sites with a dissociation constant (Kd) of 1.2 nM. Furthermore, Scatchard analysis reveals a second population of binding sites with a 100-fold lower affinity for calmodulin. The Ca2+-dependence of calmodulin binding and of adenylate cyclase activation varies with the amount of calmodulin present, as can be inferred from the model of sequential equilibrium reactions which describes the activation of calmodulin-dependent enzymes. On the basis of this model, a quantitative analysis of the effect of free Ca2+ and of free calmodulin concentration on both binding and activation of adenylate cyclase was carried out. This analysis shows that both processes take place only when calmodulin is complexed with at least three Ca2+ atoms. The concentration of the active calmodulin X Ca2+ species required for half-maximal activation of adenylate cyclase is very similar to the Kd of the high affinity binding sites on brain membranes. A Hill coefficient of approx. 1 was found for both processes indicating an absence of cooperativity. Phenothiazines and thioxanthenes antipsychotic agents inhibit calmodulin binding to membranes and calmodulin-dependent activation of adenylate cyclase with a similar order of potency. These results suggest that the Ca2+-dependent binding of calmodulin to specific high affinity sites on brain membranes regulates the activation of adenylate cyclase by calmodulin.     

13C and 113Cd NMR studies of the chelation of metal ions by the calcium binding protein parvalbumin

13C NMR spectra are presented for the calcium binding protein parvalbumin (pI 4.25) from carp muscle in several different metal bound forms: with Ca2+ in both the CD and EF calcium binding sites, with Cd2+ in both sites, with 113Cd2+ in both sites, and with 113Cd2+ in the CD site and Lu3+ in the EF site. The different metals differentially shift the 13C NMR resonances of the protein ligands involved in chelation of the metal ion. In addition, direct 13C-113Cd spin-spin coupling is observed which allows the assignment of protein carbonyl and carboxyl 13C NMR resonances to ligands directly interacting with the metal ions in the CD and EF binding sites. The displacement of 113Cd2+ from the EF site by Lu3+ further allows these resonances to be assigned to the CD or EF site. The occupancy of the two sites in the two cadmium species and in the mixed Cd2+/Lu3+ species is verified by 113Cd NMR. The resolution in these 113Cd NMR spectra is sufficient to demonstrate direct interaction between the two metal binding sites.     

Loss of a metal-binding site in gelsolin leads to familial amyloidosis-Finnish type.

Mutations in domain 2 (D2, residues 151-266) of the actin-binding protein gelsolin cause familial amyloidosis-Finnish type (FAF). These mutations, D187N or D187Y, lead to abnormal proteolysis of plasma gelsolin at residues 172-173 and a second hydrolysis at residue 243, resulting in an amyloidogenic fragment. Here we present the structure of human gelsolin D2 at 1.65 A and find that Asp 187 is part of a Cd2+ metal-binding site. Two Ca2+ ions are required for a conformational transition of gelsolin to its active form. Differential scanning calorimetry (DSC) and molecular dynamics (MD) simulations suggest that the Cd2+-binding site in D2 is one of these two Ca2+-binding sites and is essential to the stability of D2. Mutation of Asp 187 to Asn disrupts Ca2+ binding in D2, leading to instabilities upon Ca2+ activation. These instabilities make the domain a target for aberrant proteolysis, thereby enacting the first step in the cascade leading to FAF.     

Metal binding and metal-induced conformational change of frog bone gamma-carboxyglutamic acid-containing protein

Ca2+ or Cd2+ binding and the conformational change induced by the metal binding in two frog bone Gla-proteins (BGP, termed BGP-1 and BGP-2) were studied by equilibrium dialysis and CD measurement. By CD measurement in the far-ultraviolet region, the alpha-helix content of both apoBGPs was found to be 8%. Binding of both Ca2+ and Cd2+ was accompanied with a change in the CD spectrum, and the alpha-helix content increased to 15 and 25% for BGP-1 and BGP-2, respectively. CD measurement in the near-ultraviolet region indicated that the environment of aromatic amino acid residues in the protein molecule was changed by metal binding. Equilibrium dialysis experiments indicated that each of these two protein binds specifically 2 mol of Ca2+, and nonspecifically an additional 3-4 mol of Ca2+ in 0.02 M Tris-HCl/0.15 M NaCl (pH 7.4), at 4 degrees C. According to the two separate binding sites model, BGP-1 has 1 high-affinity Ca2+ binding site (Kd1 = 0.17 mM) and 1 low-affinity site (Kd2 = 0.29 mM), and BGP-2 contains 1 high-affinity site (Kd1 = 0.14 mM) and 1 low-affinity site (Kd2 = 0.67 mM). In addition, 2 Cd2+ bound to a high-affinity binding site on BGP-1 with Kd1 of 10.4 microM, and 1 Cd2+ bound to a low-affinity binding site with Kd2 of 41.5 microM. On the other hand, BGP-2 had three classes of binding sites and 1 Cd2+ bound to each binding site with Kd1 = 3.6 microM, Kd2 = 16.3 microM, Kd3 = 51.7 microM, respectively.(ABSTRACT TRUNCATED AT 250 WORDS)     

Cadmium-substituted skeletal troponin C. Cadmium-113 NMR spectroscopy and metal binding investigations

The binding of cadmium to skeletal troponin C (STnC) has been measured by equilibrium binding and by 113Cd NMR spectroscopy. The equilibrium binding experiments have shown that there are two cadmium binding sites on STnC with a high affinity for Cd2+ (KCd congruent to 10(7) M-1) and two with a lower affinity for Cd2+ (KCd congruent to 10(3) M-1). The former binding constant is comparable to Ca2+ binding to the Ca2+-Mg2+ (structural) sites of STnC and the latter is about a factor of one hundred less than Ca2+ binding to the Ca2+-specific (regulatory) sites of STnC. In the presence of Mg2+ the affinity of Cd2+ for the higher affinity sites was lowered, yielding a KMg of approximately 10(3) M-1. These data clearly suggest that the two sites with high affinity for Cd2+ are the same as the Ca2+-Mg2+ sites (Zot, H., and Potter, J. D. (1982) J. Biol. Chem. 257, 7678-7683). The 113Cd NMR is shown to be temperature-dependent. The room temperature spectrum consists of two resonances at -107.8 and -112.7 ppm with respect to a 0.1 M solution of Cd(ClO4)2. Lowering the temperature to 4 degrees C alters the cadmium exchange dynamics, and results in a four line 113Cd spectrum. The two new resonances at -103.1 and -109.8 ppm probably arise from cadmium binding to the Ca2+-specific (regulatory) sites on STnC; whereas, the resonances at -107.8 and -112.7 ppm correspond to cadmium binding at the Ca2+-Mg2+ (structural) sites, respectively. When the 113Cd2+-substituted protein was titrated with Ca2+, the two resonances corresponding to the high affinity sites were reduced in intensity, followed by a reduction in intensity of the lower affinity Cd2+ sites. Based on the assignments made here and the known binding constants of STnC for Ca2+ (Potter, J. D., and Gergely, J. (1975) J. Biol. Chem. 250, 4628-4633) and the Cd2+ affinities reported here, one would not predict these results. Ca2+ should have first bound to the sites with the lower affinity Cd2+. Since the direct binding experiments clearly demonstrate that the high affinity Cd2+ sites are the Ca2+-Mg2+ sites, we can only conclude that Cd2+ binding to the protein (probably to the lower affinity Ca2+-specific sites) dramatically alters the affinity of the Ca2+-Mg2+ sites for Ca2+. It is suggested that an allosteric coupling network exists between all classes of binding sites.     

The specificity and function of the metal-binding sites in the integrin beta3 A-domain

The A-domains within integrin beta subunits contain three metal sites termed the metal ion-dependent adhesion site (MIDAS), site adjacent to the metal ion-dependent adhesion site (ADMIDAS), and ligand-induced metal-binding site (LIMBS), and these sites are involved in ligand engagement. The selectivity of these metal sites and their role in ligand binding have been investigated by expressing a fragment corresponding to the beta3 A-domain, beta3-(109-352), and single point mutants in which each of the cation-binding sites has been disabled. Equilibrium dialysis experiments identified three Mn2+- and two Ca2+-binding sites with the LIMBS being the site that did not bind Ca2+. Although the ADMIDAS could bind Ca2+, it did not bind Mg2+. These results indicate that the Ca2+-specific site that inhibits ligand binding is the ADMIDAS. Two different assay systems, surface plasmon resonance and a microtiter plate assay, demonstrated that the beta3 A-domain fragment bound fibrinogen in the presence of 0.1 mm Ca2+ but not in 3 mm Ca2+. This behavior recapitulated the effects of Ca2+ on fibrinogen binding to alphavbeta3 but not alphaIIbbeta3. Disabling any of the three cation-binding sites abrogated fibrinogen binding. These results indicate that the specificities of the three metal-binding sites for divalent cations are distinct and that each site can regulate the ligand binding potential of the beta3 A-domain.     

Calcium-induced cooperativity of manganese binding to concanavalin A.

Titrations employing electron spin resonance spectroscopy and equilibrium dialysis studies have revealed that Mn2+ binding to concanavalin A is cooperative in the presence and noncooperative in the absence of Ca2+. The degree of cooperativity increases with increasing pH. Hill coefficients range from 1.4 at pH 5.0 to 1.8 at pH 6.85. In addition to inducing cooperativity in Mn2+ binding, Ca2+ influences the pH dependence and increases the affinity of Mn2+ binding. In contrast to previous suggestions based mostly on work conducted near pH 5, demetallized concanavalin A does bind Ca2+ with an appreciable binding constant. These observations indicate that at physiological pH the role of metal ions in determining functional properties of concanavalin A is different from that suggested by metal binding studies conducted at lower pH values.     

Sequential binding and sensing of Zn(II) by Bacillus subtilis Zur

Bacillus subtilis Zur (BsZur) represses high-affinity zinc-uptake systems and alternative ribosomal proteins in response to zinc replete conditions. Sequence alignments and structural studies of related Fur family proteins suggest that BsZur may contain three zinc-binding sites (sites 1-3). Mutational analyses confirm the essential structural role of site 1, while mutants affected in sites 2 and 3 retain partial repressor function. Purified BsZur binds a maximum of two Zn(II) per monomer at site 1 and site 2. Site 3 residues are important for dimerization, but do not directly bind Zn(II). Analyses of metal-binding affinities reveals negative cooperativity between the two site 2 binding events in each dimer. DNA-binding studies indicate that BsZur is sequentially activated from an inactive dimer (Zur(2):Zn(2)) to a partially active asymmetric dimer (Zur(2):Zn(3)), and finally to the fully zinc-loaded active form (Zur(2):Zn(4)). BsZur with a C84S mutation in site 2 forms a Zur(2):Zn(3) form with normal metal- and DNA-binding affinities but is impaired in formation of the Zur(2):Zn(4) high affinity DNA-binding state. This mutant retains partial repressor activity in vivo, thereby supporting a model in which stepwise activation by zinc serves to broaden the physiological response to a wider range of metal concentrations.     

Comparison of the binding of Na+ and Ca2+ to bovine alpha-lactalbumin

alpha-Lactalbumin is a metal-binding protein which binds Ca2+- and Na+-ions competitively to one specific site, giving rise to a large conformational change of the protein. For this reason, the enthalpy change of binding Ca2+ to apo-alpha-lactalbumin (delta Ho) is strongly dependent on the concentration of Na+ ions in the medium. From that relationship a molar enthalpy of -145 +/- 3 kJ X mol-1 is calculated for the Ca2+-binding at pH 7.4 and 25 degrees C, while a delta Ho of -5 +/- 3 kJ X mol-1 is found to substitute a complexed Na+ by a Ca2+-ion. These measurements also allowed us to calculate a binding constant for Na+ of 195 +/- 18 M-1. The molar enthalpy of Na+-loading was found to be -142 +/- 3 kJ X mol-1, a value very close to delta Ho of the binding of Ca2+ to alpha-lactalbumin. Both enthalpy changes in binding Ca2+ and Na+ are independent of the protein concentration. These exothermic values are in agreement with the hypothesis that both Na+- and Ca2+-ions are able to induce the same conformational change in alpha-lactalbumin upon which hydrophobic regions are removed from the solvent, yielding a less hydrophobic protein. The latter is confirmed by means of affinity measurements of the hydrophobic fluorescent probe 4,4'-bis[1-(phenylamino)-8-naphthalene sulphonate](bis-ANS) to alpha-lactalbumin. The association constant (Ka) decreased from (6.6 +/- 0.5) X 10(4) M-1 in the absence of NaCl to (2.7 +/- 0.2) X 10(4) M-1 in 75 mM NaCl, while the maximum intensity (Imax) of the binary bis-ANS-alpha-lactalbumin complex remained constant at 0.44 +/- 0.02 (arbitrary units). The Ka value of bis-ANS for Ca2+-alpha-lactalbumin was determined at (1.7 +/- 0.2) X 10(4) M-1 and Imax was 0.43 +/- 0.02 (arbitrary units). The difference in hydrophobicity between the two conformational states of the protein was further demonstrated by adsorption experiments of both conformers to phenyl-Sepharose. Apo-alpha-lactalbumin, hydrophobically bound to phenyl-Sepharose, can be eluted by adding Ca2- or Na+-solutions.