Calorimetric studies on calcium and magnesium binding by troponin C from bullfrog skeletal muscle

Microcalorimetic titrations were carried out to measure the thermodynamic functions of bullfrog skeletal muscle troponin C (TnC) in the interaction with Ca2+ and Mg2+, at 25 degrees C and at pH 7.0. Enthalpy titration curves with Ca2+ were composed of three stages both in the presence and in the absence of Mg2+. The first (0-2 mol Ca2+/mol TnC) and the third (greater than 3 mol Ca2+/mol TnC) stages were exothermic and the second stage (2-3 mol Ca2+/mol TnC) was endothermic. Mg2+ affected the first stage to decrease the amount of heat produced but not the second and third stages. The enthalpy titration with Mg2+, in the absence of Ca2+, was slightly exothermic initially and then became endothermic beyond 2-3 mol Mg2+/mol TnC. Absorption of heat was observed throughout the additions of Mg2+ in the presence of 1 mM Ca2+. The results indicate that bullfrog TnC has two high-affinity Ca2+-Mg2+ sites, two low-affinity Ca2(+)-specific sites, and two or around two Mg2(+)-specific sites. Based on the enthalpy and entropy changes, the Ca2+ binding reactions of TnC were classified into three types, indicating thermodynamic variety in the binding sites of the molecule.     

Entropic drive in the sarcoplasmic reticulum ATPase interaction with Mg2+ and Pi.

Thermodynamic quantities for the binding of Mg2+ (in the presence of Ca2+) and Pi (in the presence of Mg2+ and absence of Ca2+) to sarcoplasmic reticulum ATPase were determined from isothermal titration calorimetry measurements at 25 degrees C. Mg2+ and Pi are involved in reversal of the ATPase hydrolytic reaction, and their interactions with the ATPase are conveniently studied under equilibrium conditions. We found that the Mg2+ binding reaction is endothermic with a binding constant (Kb) = 142 +/- 4 M(-1), a binding enthalpy of 180 +/- 3 kJ mol(-1), and an entropy contribution (TdeltaSb) = 192 +/- 3 kJ mol(-1). Similarly, Pi binding is also an endothermic reaction with Kb = 167 +/- 17 M(-1), deltaHb = 65.3 +/- 5.4 kJ mol(-1), and TdeltaSb = 77.9 +/- 5.4 kJ mol(-1). Our measurements demonstrate that the ATPase can absorb heat from the environment upon ligand binding, and emphasize the important role of entropic mechanisms in energy transduction by this enzyme.     

Calcium- and magnesium-binding properties of oncomodulin. Direct binding studies and microcalorimetry

Ca2+ binding to the wild type recombinant oncomodulin was studied by equilibrium flow dialysis in the absence and presence of 1, 2, and 10 mM Mg2+. Direct Mg2(+)-binding experiments were carried out by the Hummel-Dryer gel filtration technique. These studies revealed that in the absence of Mg2+ oncomodulin binds two Ca2+ with KCa = 2.2 x 10(7) and 1.7 x 10(6) M-1, respectively. In the absence of Ca2+ the protein binds only one Mg2+ with KMg = 4.0 x 10(3) M-1.Mg2+ antagonizes Ca2+ binding at the high affinity site according to the rule of direct competition. Ca2+ binding to the low affinity site is only slightly affected by Mg2+, so that in the presence of 2-3 mM Mg2+ the two sites have apparently an equal affinity for Ca2+. Microcalorimetry showed that, in spite of the different affinities of the two Ca2(+)-binding sites, delta H0 for the binding of each Ca2+ is identical and exothermic for -18.9 kJ/site. It follows that the entropy gain upon binding of Ca2+ is +77.1 J K-1 site-1 for the high affinity Ca2(+)-Mg2+ site and +56.0 J K-1 site-1 for the low affinity Ca2(+)-specific site. Mg2+ binding is endothermic for +13 kJ/site with an entropy change of +111 J K-1 site-1. The thermodynamic characteristics of the Ca2(+)-Mg2+ site resemble most those of site II (the so-called EF domain) of toad alpha-parvalbumin. The characteristics of Ca2+ binding to the specific site (likely the CD domain) are different from those of the Ca2+ specific sites in troponin C and in calmodulin and suggest that in oncomodulin hydrophobic forces do not play a predominant role in the binding process at the specific site.     

Thermodynamics of the Ca2+ binding to bovine alpha-lactalbumin

Bovine alpha-lactalbumin contains one strong Ca2+-binding site. The free energy (delta G0), enthalpy (delta H0), and entropy (delta S0) of binding of Ca2+ to this site have been calculated from microcalorimetric experiments. The enthalpy of binding was dependent on the metal-free bovine alpha-lactalbumin concentration. At 0.8 mg ml-1, metal-free bovine alpha-lactalbumin delta H0 was -110 +/- 6 kJ mol-1. At this concentration the binding constant was estimated from a mathematical analysis of the titration curves to be greater than 10(7) M-1. This means that delta G0 is smaller than -40 kJ mol-1 and delta S0 is less negative than -235 J.K-1 mol-1. The binding of Ca2+ is therefore enthalpy-driven. From binding experiments as a function of temperature, a delta Cp value of -4.1 kJ.K-1 mol-1 was calculated. This value is dependent on the protein concentration. A tentative explanation for this large value is given.     

Effects of trifluoperazine on calcium binding by calmodulin. A microcalorimetric study

Microcalorimetric titrations of calmodulin with Ca2+ and trifluoperazine (TFP) at various molar ratios have been carried out at 25 degrees C and at pH 7.0. Ca2+ binding to calmodulin produces heat (-delta H) in the presence of TFP, while heat is absorbed in the absence of TFP. The total heat produced by Ca2+ binding to all four sites is increased at increasing TFP-to-calmodulin ratios, attaining a plateau at about 7. These results indicate that at the higher ratios, the enthalpy changes (delta H) associated with Ca2+ binding are affected by TFP molecules bound at both high- and low-affinity sites. In addition, the Ca2+ binding reaction of the calmodulin-TFP complex is driven solely by a favorable enthalpy change of -27 kJ/mol of site; the entropy change (delta S) is -35 J/mol/K. These thermodynamic changes are opposite to those for TFP-free calmodulin and distinctly different from other Ca2+ binding proteins such as skeletal and cardiac troponin C and parvalbumin, where the reaction is driven by favorable changes of entropy as well as enthalpy.     

High-pressure effect on the equilibrium and kinetics of cyanide binding to chloroperoxidase

The kinetics of cyanide binding to chloroperoxidase were studied using a high-pressure stopped-flow technique at 25 degrees C and pH 4.7 in a pressure range from 1 to 1000 bar. The activation volume change for the association reaction is delta V not equal to + = -2.5 +/- 0.5 ml/mol. The total reaction volume change, determined from the pressure dependence of the equilibrium constant, is delta V degrees = -17.8 +/- 1.3 ml/mol. The effect of temperature was studied at 1 bar yielding delta H not equal to + = 29 +/- 1 kJ/mol, delta S not equal to + = -58 +/- 4 J/mol per K. Equilibrium studies give delta H degrees = -41 +/- 3 kJ/mol and delta S degrees = -59 +/- 10 J/mol per K. Possible contributions to the binding process are discussed: changes in spin state, bond formation and conformation changes in the protein. An activation volume analog of the Hammond postulate is considered.     

Microcalorimetric investigation of the interaction of calmodulin with seminalplasmin and myosin light chain kinase

Flow microcalorimetric titrations of calmodulin with seminalplasmin at 25 degrees C revealed that the high affinity one-to-one complex in the presence of Ca2+ (Comte, M., Malnoe, A., and Cox, J. A. (1986) Biochem. J. 240, 567-573) is entirely enthalpy-driven (delta H0 = -50 kJ.mol-1; delta S0 = O J.K-1.mol-1; delta Cp0 = O J.K-1.mol-1) and is not influenced by the proton or Mg2+ concentration. The Sr2+- and Cd2+-promoted high affinity complexes are also exothermic for -49 and -45 kJ.mol-1, respectively. The observed low affinity interaction in the absence of divalent ions displays no enthalpy change. No enthalpy changes are observed when calmodulin and seminalplasmin are mixed in the presence of millimolar concentrations of Mg2+, Zn2+, or Mn2+. Enthalpy titrations of the 1:1 calmodulin-seminalplasmin complex with Ca2+ and of partly Ca2+-saturated calmodulin with seminalplasmin revealed that only the species calmodulin.Can greater than or equal to 2 is fully competent for high affinity interaction with seminalplasmin. Binding of the second Ca2+ is strongly enhanced (K2 greater than or equal to 5 X 10(7) M-1) as compared to that in free calmodulin (K2 = 2.6 X 10(5) M-1). This is essentially due to the concomitant strongly exothermic step of isomerization of the calmodulin-seminalplasmin complex from its low to its high affinity form. Binding of the remaining two Ca2+ to the high affinity seminalplasmin-calmodulin complex displays the same affinity constants and endothermic enthalpy change as in free calmodulin. A microcalorimetric study on the complex formation between Ca2+-saturated calmodulin and turkey gizzard myosin light chain kinase revealed that the interaction is strongly exothermic with an important overall gain of order (delta H0 = -85 kJ.mol-1; delta S0 = -122 J.K-1.mol-1) and occurs with significant proton uptake (0.44 H+ per mol at pH 7.5). The observed low affinity interaction (K = 2.2 X 10(5) M-1) in the absence of Ca2+ (Mamar-Bachi, A., and Cox, J. A. (1987) Cell Calcium 8, 473-482) displays neither a change in enthalpy nor in protonation.     

The thermodynamics of calcium binding to thermolysin

Calcium binding isotherms were determined for thermolysin in the range pH 5.6-10.5, and from 5 to 45 degrees C. An extensive statistical analysis of the binding data suggests that at least two of the four binding sites bind Ca2+ with complete positive cooperativity and independently of the other two. Nonlinear regression analysis of the binding data was used to calculate cooperative (K1) and independent (K2) binding constants for the four calcium sites. Thermodynamic parameters obtained from a van't Hoff analysis indicate that calcium binding to both cooperative and independent sites is an entropy-driven process. At pH 7.0, delta H1 = 90.4 kJ/mol; delta H2 = 97.5 kJ/mol; delta S1 = 456 J K-1 mol-1; delta S2 = 262 J K-1 mol-1. These results are compared to those obtained for other calcium-binding proteins. An analysis of the pH dependence of the calcium binding constants indicates that the binding of four protons at the cooperative site and one to two protons at the independent sites, modulates the calcium affinity. This confirms an earlier structural assignment of the double-site as the locus of the two cooperatively binding Ca2+. Calcium binding to thermolysin is enhanced in the presence of an active site directed inhibitor, suggesting that there may be positive cooperativity between substrate and calcium binding.     

Calorimetric experiments of Mn2+ -binding to alpha-lactalbumin

We measured by batch microcalorimetry the standard enthalpy change delta H degrees of the binding of Mn2+ to apo-bovine alpha-lactalbumin; delta H degrees = -90 +/- k J.mol-1. The binding constants, KMn2+, calculated from the calorimetric and circular dichroism titration curves, are (4.6 +/- 1).10(5) M-1 and (2.1 +/- 0.4).10(5) M-1, respectively. Batch calorimetry confirms the competitive binding Ca2+, Mn2+ and Na+ to the same site. The relatively small enthalpy change for Mn2+ binding compared to Ca2+ binding favours a model of a rigid and almost ideal Ca2+-complexating site, different from the well-known EF-hand structures. Cation binding to the high-affinity site most probably triggers the movement of an alpha-helix which is directly connected to the complexating loop.     

Comparison of the binding of Ca2+ and Mn2+ to bovine alpha-lactalbumin and equine lysozyme

The enthalpy change of the binding of Ca2+ and Mn2+ to equine lysozyme was measured at 25 degrees C and pH 7.5 by batch microcalorimetry: delta H degrees Ca2+ = -76 +/- 5 kJ mol-1, delta H degrees Mn2+ = -21 +/- 10 kJ mol-1. Binding constants, log KCa2+ = 6.5 +/- 0.2 and log KMn2+ = 4.1 +/- 0.5, were calculated from the calorimetric data. Therefore, delta S degrees Ca2+ = -131 +/- 20 JK-1 mol-1 and delta S degrees Mn2+ = 8 +/- 44 JK-1 mol-1. Removal of Ca2+ induces small but significant changes in the circular dichroism spectrum, indicating the existence of a partially unfolded apo-conformation, comparable with, but different from, the apo-conformation of bovine alpha-lactalbumin.     

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.     

Interactions of sodium pentobarbital with D-glucose and L-sorbose transport in human red cells.

Pentobarbital acts as a mixed inhibitor of net D-glucose exit, as monitored photometrically from human red cells. At 30 degrees C the Ki of pentobarbital for inhibition of Vmax of zero-trans net glucose exit is 2.16+/-0.14 mM; the affinity of the external site of the transporter for D-glucose is also reduced to 50% of control by 1. 66+/-0.06 mM pentobarbital. Pentobarbital reduces the temperature coefficient of D-glucose binding to the external site. Pentobarbital (4 mM) reduces the enthalpy of D-glucose interaction from 49.3+/-9.6 to 16.24+/-5.50 kJ/mol (P<0.05). Pentobarbital (8 mM) increases the activation energy of glucose exit from control 54.7+/-2.5 kJ/mol to 114+/-13 kJ/mol (P<0.01). Pentobarbital reduces the rate of L-sorbose exit from human red cells, in the temperature range 45 degrees C-30 degrees C (P<0.001). On cooling from 45 degrees C to 30 degrees C, in the presence of pentobarbital (4 mM), the Ki (sorbose, glucose) decreases from 30.6+/-7.8 mM to 14+/-1.9 mM; whereas in control cells, Ki (sorbose, glucose) increases from 6.8+/-1.3 mM at 45 degrees C to 23.4+/-4.5 mM at 30 degrees C (P<0.002). Thus, the glucose inhibition of sorbose exit is changed from an endothermic process (enthalpy change=+60.6+/-14.7 kJ/mol) to an exothermic process (enthalpy change=-43+/-6.2 7 kJ/mol) by pentobarbital (4 mM) (P<0.005). These findings indicate that pentobarbital acts by preventing glucose-induced conformational changes in glucose transporters by binding to 'non-catalytic' sites in the transporter.     

Thermodynamics of active-site ligand binding to Escherichia coli glutamine synthetase

Active-site ligand interactions with dodecameric glutamine synthetase from Escherichia coli have been studied by calorimetry and fluorometry using the nonhydrolyzable ATP analogue 5'-adenylyl imidodiphosphate (AMP-PNP), L-glutamate, L-Met-(S)-sulfoximine, and the transition-state analogue L-Met-(S)-sulfoximine phosphate. Measurements were made with the unadenylylated enzyme at pH 7.1 in the presence of 100 mM KCl and 1.0 mM MnCl2, under which conditions the two catalytically essential metal ion sites per subunit are occupied and the stoichiometry of active-site ligand binding is equal to 1.0 equiv/subunit. Thermodynamic linkage functions indicate that there is strong synergism between the binding of AMP-PNP and L-Met-(S)-sulfoximine (delta delta G' = -6.4 kJ/mol). In contrast, there is a small antagonistic effect between the binding of AMP-PNP and L-glutamate (delta delta G' = +1.4 kJ/mol). Proton effects were negligible (less than or equal to 0.2 equiv of H+ release or uptake/mol) for the different binding reactions. The binding of AMP-PNP (or ATP) to the enzyme is entropically controlled at 303 K with delta H = +5.4 kJ/mol and delta S = +150 J/(K.mol). At 303 K, the binding of L-glutamate (delta H = -22.2 kJ/mol) or L-Met-(S)-sulfoximine [delta H = -45.6 kJ/mol with delta Cp approximately equal to -670 +/- 420 J/(K.mol)] to the AMP-PNP.Mn.enzyme complex is enthalpically controlled with opposing delta S values of -29 or -46 J/(K.mol), respectively. The overall enthalpy change is negative and the overall entropy change is positive for the simultaneous binding of AMP-PNP and L-glutamate or of AMP-PNP and L-Met-(S)-sulfoximine to the enzyme. For the binding of the transition-state analogue L-Met-(S)-sulfoximine phosphate (which inactivates the enzyme by blocking active sites), both enthalpic and entropic contributions also are favorable at 303 K [delta G' approximately equal to -109 and delta H = -54.8 kJ/mol of subunit and delta S approximately equal to +180 J/(K.mol)].     

Kinetics and energetics of the binding between barley alpha-amylase/subtilisin inhibitor and barley alpha-amylase 2 analyzed by surface plasmon resonance and isothermal titration calorimetry

The kinetics and energetics of the binding between barley alpha-amylase/subtilisin inhibitor (BASI) or BASI mutants and barley alpha-amylase 2 (AMY2) were determined using surface plasmon resonance and isothermal titration calorimetry (ITC). Binding kinetics were in accordance with a 1:1 binding model. At pH 5.5, [Ca(2+)] = 5 mM, and 25 degrees C, the k(on) and k(off) values were 8.3 x 10(+4) M(-1) s(-1) and 26.0 x 10(-4) s(-1), respectively, corresponding to a K(D) of 31 nM. K(D) was dependent on pH, and while k(off) decreased 16-fold upon increasing pH from 5.5 to 8.0, k(on) was barely affected. The crystal structure of AMY2-BASI shows a fully hydrated Ca(2+) at the protein interface, and at pH 6.5 increase of [Ca(2+)] in the 2 microM to 5 mM range raised the affinity 30-fold mainly due to reduced k(off). The K(D) was weakly temperature-dependent in the interval from 5 to 35 degrees C as k(on) and k(off) were only increasing 4- and 12-fold, respectively. A small salt dependence of k(on) and k(off) suggested a minor role for global electrostatic forces in the binding and dissociation steps. Substitution of a positively charged side chain in the mutant K140L within the AMY2 inhibitory site of BASI accordingly did not change k(on), whereas k(off) increased 13-fold. ITC showed that the formation of the AMY2-BASI complex is characterized by a large exothermic heat (Delta H = -69 +/- 7 kJ mol(-1)), a K(D) of 25 nM (27 degrees C, pH 5.5), and an unfavorable change in entropy (-T Delta S = 26 +/- 7 kJ mol(-1)). Calculations based on the thermodynamic data indicated minimal structural changes during complex formation.     

Structure-function relationships in EF-hand Ca2+-binding proteins. Protein engineering and biophysical studies of calbindin D9k

Genes encoding the minor A component of bovine calbindins D9k--the smallest protein known with a pair of EF-hand calcium-binding sites--with amino acid substitutions and/or deletions have been synthesized and expressed in Escherichia coli and characterized with different biophysical techniques. The mutations are confined to the N-terminal Ca2+-binding site and constitute Pro-20----Gly (M1), Pro-20----Gly and Asn-21 deleted (M2), Pro-20 deleted (M3), and Tyr-13----Phe (M4). 1H, 43Ca, and 113Cd NMR studies show that the structural changes induced are primarily localized in the modified region, with hardly any effects on the C-terminal Ca2+-binding site. The Ca2+ exchange rate for the N-terminal site changes from 3 s-1 in the wild-type protein (M0) and M4 to 5000 s-1 in M2 and M3, whereas there is no detectable variation in the Ca2+ exchange from the C-terminal site. The macroscopic Ca2+-binding constants have been obtained from equilibration in the presence of the fluorescent chelator 2-[[2-[bis(carboxymethyl)-amino]- 5-methylphenoxy]methyl]-6-methoxy-8-[bis(carboxymethyl)amino]quinoline or by using a Ca2+-selective electrode. The Ca2+ affinity of M4 was similar to that of M0, whereas the largest differences were found for the second stoichiometric step in M2 and M3. Microcalorimetric data show that the enthalpy of Ca2+ binding is negative (-8 to -13 kJ.mol-1) for all sites except the N-terminal site in M2 and M3 (+5 kJ.mol-1). The binding entropy is strongly positive in all cases. Cooperative Ca2+ binding in M0 and M4 was established through the values of the macroscopic Ca2+-binding constants. Through the observed changes in the 1H NMR spectra during Ca2+ titrations we could obtain ratios between site binding constants in M0 and M4. These ratios in combination with the macroscopic binding constants yielded the interaction free energy between the sites delta delta G as -5.1 +/- 0.4 kJ.mol-1 (M0) and less than -3.9 kJ.mol-1 (M4). There is evidence (from 113Cd NMR) for site-site interactions also in M1, M2, and M3, but the magnitude of delta delta G could not be determined because of sequential Ca2+ binding.     

Calcium-proton and calcium-magnesium antagonisms in calmodulin: microcalorimetric and potentiometric analyses

Microcalorimetry, pH potentiometry, and direct binding studies by equilibrium dialysis or gel filtration were performed to determine the thermodynamic functions delta Ho, delta Go, and delta So guiding the interactions of Ca2+, Mg2+, and H+ with bovine brain calmodulin. At pH 7.5, Ca2+ and Mg2+ binding are both endothermic with enthalpy changes of 19.5 and 72.8 kJ X (mol of calmodulin)-1, respectively. These enthalpy changes are identical for each of the four ion-binding domains. The affinity constants also are identical with intrinsic values of 10(5) M-1 for Ca2+ and 140 M-1 for Mg2+. Ca2+ and Mg2+ do not compete for the same binding sites: at high concentrations of both ions, a calmodulin-Ca4-Mg4 species is formed with an enthalpy value of 24.4 kJ X mol-1 with respect to calmodulin-Ca4 and -28.8 kJ X mol-1 with respect to calmodulin-Mg4. Moreover, in the presence of high concentrations of Ca2+, the affinity of each of the four ion-binding domains in calmodulin for Mg2+ is decreased by a factor of 4 and vice versa, indicative of negative free-energy coupling between Ca2+ and Mg2+ binding. Protons antagonize Ca2+ and Mg2+ binding in a different manner. Ca2+-H+ antagonism is identical in each of the four Ca2+-binding domains in the pH range 7.5-5.2. Our analyses suggest that three chemical geometries, probably carboxyl-carboxylate interactions, are responsible for this antagonism with ionization constants of 10(6.2) M-1 in the metal-free protein. Mg2+-H+ antagonism also is identical for each of the Mg2+-binding sites but is qualitatively different from Ca2+-H+ antagonism.(ABSTRACT TRUNCATED AT 250 WORDS)     

Thermodynamics of cation binding to rabbit skeletal muscle calsequestrin. Evidence for distinct Ca(2+)- and Mg(2+)-binding sites

Ca2+ binding to rabbit skeletal calsequestrin was studied at physiological ionic strength by equilibrium flow dialysis, Hummel-Dryer gel filtration and microcalorimetry. 31 Ca(2+)-binding sites with a mean dissociation constant (KD) of 0.79 mM were titrated in the absence, and 23 sites with a KD of 0.88 mM in the presence of 3 mM Mg2+. No cooperativity was observed. For Mg2+ binding, the combination of gel filtration and microcalorimetry yielded a stoichiometry of 26 Mg2+/protein with a KD of 2mM. 1 mM Ca2+ decreased the stoichiometry to 20 Mg2+/protein. Binding of Ca2+ in the absence and presence of 3 mM Mg2+ was accompanied by a release of 2.0 and 2.7 H+/protein, respectively. Mg2+ binding did not lead to a significant proton release suggesting a qualitative difference in the Ca(2+)- and Mg(2+)-binding sites. After correction for proton release, the enthalpy change for Ca2+ binding was very low (-1.5 kJ/protein in the absence, and -15 kJ/protein in the presence of 3 mM Mg2+). The entropy change (+59 J/K.site in the absence and +56 J/K.site in the presence of Mg2+) was therefore virtually the sole driving force for Ca2+ binding. Mg2+ binding is slightly more exothermic (-12.6 kJ/protein), but as for Ca2+, the entropy change (+50 J/K.site) constituted the major driving force of the reaction. A fluorimetric study indicates that the conformation of tryptophan in Mg(2+)-saturated calsequestrin was clearly different from that in the Ca(2+)-saturated protein, but that the (Ca2+ + Mg2+)-saturated protein was not distinct from the Ca(2+)-saturated protein. Thus, in addition to the thermodynamic characterization of the Ca2+/calsequestrin interaction, our data indicate that Ca2+ and Mg2+ do not bind to the same sites on calsequestrin. The data also predict considerable proton fluxes upon Ca(2+)-Mg2+ exchange in vivo.     

Nuclear magnetic resonance study on rabbit skeletal troponin C: calcium-induced conformational change

Rabbit skeletal muscle troponin C (TnC) was investigated by means of 1H NMR in the presence of dithiothreitol that prevents dimerization of the protein. Two-dimensional (2D) 1H NMR spectra were observed in order to assign resonances to specific amino acids. One-dimensional 1H NMR spectra were observed as a function of Ca2+ concentration. The Ca2+-induced spectral change is categorized into two types: type 1 corresponds to the conformational change of the C-terminal-half domain (Ca2+ high-affinity sites) and type 2 to that of the N-terminal-half domain (Ca2+ low-affinity sites). From the 2D NMR spectra and Ca2+ titration data, it was suggested that (1) amide protons of Gly-108, Ile-110, Gly-144, and Ile-146 are hydrogen-bonded when the C-terminal-half domain binds 2 mol of Ca2+ and (2) hydrogen bonds of Gly-108, Ile-110, Gly-144, and Ile-146 are destroyed or weakened when the C-terminal-half domain releases 2 mol of Ca2+. Nuclear Overhauser enhancement difference spectra as well as the Ca2+ titration data suggested that a hydrophobic cluster is formed in the C-terminal-half domain when the C-terminal-half domain binds 2 mol of Ca2+. A hydrophobic cluster exists in the N-terminal-half domain without regard to Ca2+ binding to the N-terminal-half domain. The spectra of Tyr-10 showed both types of spectral change during the Ca2+ titration. The results suggested that Tyr-10 of apo-TnC interacts with the C-terminal-half domain.     

Conformational stability of bovine holo and apo adrenodoxin--a scanning calorimetric study.

Holo and apo adrenodoxin were studied by differential scanning calorimetry, absorption spectroscopy, limited proteolysis, and size-exclusion chromatography. To determine the conformational stability of adrenodoxin, a method was found that prevents the irreversible destruction of the iron-sulfur center. The approach makes use of a buffer solution that contains sodium sulfide and mercaptoethanol. The thermal transition of adrenodoxin takes place at Ttrs = 46-57 degrees C, depending on the Na2S concentration with a denaturation enthalpy of delta H = 300-380 kJ/mol. From delta H versus Ttrs a heat capacity change was determined as delta Cp = 7.5 +/- 1.2 kJ/mol/K. The apo protein is less stable than the holo protein as judged by the lower denaturation enthalpy (delta H = 93 +/- 14 kJ/mol at Ttrs = 37.4 +/- 3.3 degrees C) and the higher proteolytic susceptibility. The importance of the iron-sulfur cluster for the conformational stability of adrenodoxin and some conditions for refolding of the thermally denatured protein are discussed.