Peptide binding by calmodulin and its proteolytic fragments and by troponin C

Calmodulin and troponin C exhibit calcium-dependent binding of 1 mol/mol of dynorphin. The dissociation constants of the complexes, determined in 0.20 N KC1-1.0 mM CaCI2, pH 7.3, are 0.6 microM for calmodulin, 2.4 microM for rabbit fast skeletal muscle troponin C, and 9 microM for bovine heart troponin C. Experiments with deletion peptides of dynorphin show that peptide chain length and especially charge affect the binding of the peptides by calmodulin. Dynorphin, but not mastoparan or melittin, inhibits adenosinetriphosphatase activity in a reconstituted rabbit skeletal muscle actomyosin assay. The inhibition is partially reversed by the addition of calmodulin or troponin C in the presence of calcium. Calmodulin also exhibits calcium-dependent binding of a synthetic peptide corresponding to positions 104-115 of rabbit fast skeletal muscle troponin I. Mastoparan is a tetradecapeptide from the vespid wasp having exceptional affinity for calmodulin, with Kd approximately 0.3 nM [Malencik, D.A., & Anderson, S.R. (1983) Biochem. Biophys. Res. Commun. 114, 50]. The addition of 1 mol/mol of mastoparan to the complex of calmodulin with dynorphin results in complete dissociation of dynorphin. Similar titrations of the skeletal muscle troponin C-dynorphin complex produce a gradual dissociation consistent with a dissociation constant of 0.2 microM for the troponin C-mastoparan complex. Fluorescence anisotropy measurements using the intrinsic tryptophan fluorescence of mastoparan X show strongly calcium-dependent binding by proteolytic fragments of calmodulin. binding by proteolytic fragments of calmodulin.(ABSTRACT TRUNCATED AT 250 WORDS)     

Interaction of calmodulin with the particulate fraction of cardiac muscle

Tritiated calmodulin (T-CM) was bound to the EGTA-treated particulate fraction of cardiac muscle in a calcium-dependent manner with half-maximal binding occurring between 0.8 to 1.2 microM calcium. Binding exhibited high specificity at an optimum pH of 7.4-7.6. An excess of parvalbumin and other globular proteins did not displace T-CM. The Kd for the interaction was 2.5 +/- 0.83 microM. Binding was trypsin-sensitive, inhibited by high ionic strength and was heat inactivated at a midpoint of 48 - 50 degrees C. Competitive displacement of T-CM occurred with unlabeled troponin C and calmodulin over the same concentration range. The first-order rate constant of T-CM dissociation was 3.27 min-1. Calcium-dependent binding of T-CM was inhibited equally by both mepacrine and trifluoperazine with 50 percent inhibition occurring at 70 microM.     

On the mechanism of calmodulin-induced inhibition of microtubule assembly in vitro

Binding of calmodulin to microtubule-associated proteins (MAPs) was analyzed by the equilibrium gel filtration method. The apparent dissociation constant (Kd) of calmodulin binding was found to be 2 microM for tau, and 5 microM for MAP2. These Kd values were similar to the Kd previously determined for calmodulin binding to tubulin. The inhibitory effect of increasing concentrations of calmodulin on the kinetics of microtubule assembly from tau and tubulin was not mimicked by decreasing the concentration of tau alone or tubulin alone. These results suggest that calmodulin inhibits microtubule assembly by its binding to both MAPs and tubulin.     

Binding of hormones and neuropeptides by calmodulin

Calmodulin exhibits high-affinity, calcium-dependent binding of 1 mol/mol of the vasoactive intestinal peptide (VIP), secretin, and either the 42- or 43-residue gastric inhibitory peptide (GIP) with dissociation constants of 0.05-0.14 microM. The affinity of VIP for calmodulin approaches its affinity for the cell-surface VIP receptors. These peptides compete with both smooth muscle myosin light chain kinase and glucagon in calmodulin binding. Calculation of amino acid frequencies for eight calmodulin binding peptides (VIP, GIP, secretin, ACTH, beta-endorphin, substance P, glucagon, and dynorphin [Malencik, D. A., & Anderson, S. R. (1982) Biochemistry 21, 3480]) shows a below-average incidence of glutamyl residues, above-average incidence of glutaminyl residues, and average incidence of both aspartyl and asparaginyl residues. Predictions of structure from sequence suggest that the bound peptides contain strongly basic turns and coils in close association with regions having above-average beta-sheet potential. The temperature dependence of glucagon binding by calmodulin shows that the association is enthalpy driven.     

Calmodulin binding by calcineurin. Ligand-induced renaturation of protein immobilized on nitrocellulose

The interaction of calmodulin with calcineurin, a calcium- and calmodulin-stimulated protein phosphatase, was investigated using a solid-phase assay. Binding of 125I-calmodulin by calcineurin immobilized on nitrocellulose membrane filters was of high affinity, reversible, and calcium-dependent. Complex binding kinetics reflected a time- and calcium/calmodulin-dependent conformational change of calcineurin which was shown to be ligand-induced renaturation. After renaturation and removal of calmodulin, immobilized calcineurin exhibited simple 125I-calmodulin binding kinetics with a single class of independent sites. The maximum stoichiometry of 125I-calmodulin binding to immobilized calcineurin was 0.1 mol/mol. The association rate (K1 = 8.9 x 10(3) M-1 S-1) and the dissociation rate (K-1 = 8.5 x 10(-5) s-1) yielded a dissociation constant of Kd = 10 nM. Equilibrium binding analyses gave a Kd value of 16 nM. The affinity of 125I-calmodulin for immobilized calcineurin was half that of unmodified calmodulin. Using equilibrium competition experiments, we determined, for the first time, the dissociation constant for the binding of native calmodulin by calcineurin in solution, Kd less than or equal to 0.1 nM (Kd for 125I-calmodulin = 0.23 +/- 0.09 nM). The effects of ionic strength and pH on 125I-calmodulin binding to immobilized calcineurin were characterized. The dissociation rate was dependent on free calcium concentration, with half-maximal rate at 700 nM calcium. 125I-Calmodulin equilibrium binding by the immobilized A subunit of calcineurin exhibited half the affinity of the holoenzyme, Kd = 30 nM. The described phenomenon, of reversible denaturation associated with immobilization of a protein on nitrocellulose, may be a general one open to exploitation in other systems.     

Tubulin-myosin interaction. Some properties of binding between tubulin and myosin

This report presents evidence suggesting the direct binding between tubulin and myosin: (1) coprecipitation of tubulin with myosin occurred at a low ionic strength at which no precipitation of tubulin by itself occurred; (2) the amount of tubulin coprecipitated was unchanged when the coprecipitate was washed thoroughly; (3) about 2 mol of tubulin dimer could bind per mol of myosin at the maximum under our experimental conditions. The binding of about 1 mol of tubulin dimer was influenced by the presence of F-actin, but that of the other 1 mol of tubulin dimer was uninfluenced. In the former binding, tubulin or actin which bound first to myosin was suggested to have a priority. With regard to the priority of the binding, a similar result was obtained from the experiments of tubulin interference in actin activation of myosin Mg2+-ATPase. The tubulin-myosin binding occurred moderately even at 0 degrees C and was not affected by Ca2+ (2 mM), colchicine (200 microM), or Mg-ATP (4 mM), reflecting that the ability of tubulin to bind to myosin was different from the ability of tubulin to form microtubules and that the nature of tubulin-myosin binding was different from that of F-actin-myosin binding. Besides tubulin-myosin interaction, a possible interaction between microtubule-associated proteins (MAPs) and actomyosin was suggested from the data that MAPs activated actomyosin MG2+-ATPase activity while purified tubulin inhibited the activity.     

Regulation of calmodulin binding to P-57. A neurospecific calmodulin binding protein

P-57 is a neural-specific calmodulin binding protein with novel calmodulin binding properties. P-57 exhibits higher affinity for calmodulin-Sepharose in the absence of free Ca2+ than in the presence of Ca2+ (Andreasen, T.J., Luetje, C.W., Heideman, W. & Storm, D.R. (1983) Biochemistry 22, 4615-4618; Cimler, B. M., Andreasen, T.J., Andreasen, K.I. & Storm, D.R. (1985) J. Biol. Chem. 260, 10784-10788). In this study, the dissociation constants for P-57 and immunopurified 5-[[(iodoacetylamino)ethyl]-amino]-1-naphthalenesulfonic acid-labeled calmodulin (AEDANS-CaM) were determined under low and high ionic strength conditions. In the absence of added KCl, the dissociation constants for the P-57 X AEDANS-CaM complex were 2.3 X 10(-7) +/- 6 X 10(-8) M and 1.0 X 10(-6) +/- 3 X 10(-7) M in the presence and absence of excess Ca2+ chelator. The addition of KCl to 150 mM increased the Ca2+-independent and -dependent dissociation constants to 3.4 X 10(-6) +/- 9 X 10(-7) M and 3.0 X 10(-6) +/- 9 X 10(-7) M, respectively. The association of P-57 with AEDANS-CaM under low Ca2+ conditions was determined as a function of KCl concentrations. By taking into account the amount of P-57 found in brain and its affinity for calmodulin, it is concluded that most or all of the CaM would be complexed to P-57 in unstimulated cells. P-57 was phosphorylated by the Ca2+-phospholipid-dependent protein kinase (protein kinase C) with a phosphate:protein molar ratio of 1.3. Phosphoamino acid analysis demonstrated phosphorylation at a serine residue. CaM decreased the rate of phosphorylation of P-57 by protein kinase C, and phosphorylation prevented P-57 binding to calmodulin-Sepharose. P-57 was not phosphorylated by the catalytic subunit of the cAMP-dependent protein kinase. It is proposed that P-57 binds and localizes calmodulin at specific sites within the cell and that free calmodulin is released locally in response to phosphorylation of P-57 by protein kinase C and/or to increases in intracellular free Ca2+. This regulatory mechanism, which appears to be specific to brain, would serve to decrease the response time for Ca2+-calmodulin-regulated processes.     

Binding of microtubule-associated protein 2 and tau to the intermediate filament reassembled from neurofilament 70-kDa subunit protein. Its regulation by calmodulin

Two major brain microtubule-associated proteins (MAPs), MAP2 and tau, were found to bind to the intermediate filaments reassembled from neurofilament 70-kDa subunit protein (= 70-kDa filaments). The binding was saturable. The apparent dissociation constant (KD) for the binding of MAP2 to the 70-kDa filaments was estimated to be 4.8 X 10(-7) M, and the maximum binding reached 1 mol of MAP2/approximately 30 mol of 70-kDa protein. The apparent KD for the tau binding was 1.6 X 10(-6) M, and the maximum binding was 1 mol of tau/approximately 3 mol of 70-kDa protein. It was also found that MAP2 and tau did not compete with each other for binding to the 70-kDa filaments. Most interestingly, calmodulin, a ubiquitous Ca2+-binding protein in eukaryotic cells, was found to inhibit the binding of MAP2 and tau to the 70-kDa filaments. The inhibition by calmodulin was regulated by changes in Ca2+ concentration around 10(-6) M, and was canceled by trifluoperazine, a calmodulin inhibitor.     

Quantitative analysis of the interaction between S-100 proteins and brain tubulin

S-100 was shown to regulate the in vitro assembly of brain microtubule proteins (MTPs) in a Ca2+-mediated way by acting on both the nucleation and the elongation of microtubules (MTs). Here data will be shown suggesting that S-100 binds to tubulin. The binding is time-, temperature-, Ca2+-, and pH-dependent, and saturable with respect to S-100. At pH 6.75, the saturation curve is biphasic, displaying a high affinity component (dissociation constant, Kd1, approximately 0.1 microM) and a low affinity component (Kd2 approximately 3.8 microM). At pH 6.75, as the free Ca2+ concentration raises from 0 to 100 microM, the overall binding capacity increases from 0.065 to 0.66 mol S-100/mol tubulin dimer. This finding, together with the observation that the S-100 effect on MTP assembly is Ca2+-dependent at that pH, suggests that the S-100-induced inhibition of MTP assembly depends on S-100 binding to the low affinity sites on the tubulin molecule. The S-100 binding to tubulin is pH-dependent; as the pH raises from 6.75 to 8.3, both binding components are affected, the major changes consisting of an increase in the binding capacity and a decrease in the overall affinity. Moreover, as the pH raises, Ca2+ is no longer required for S-100 to bind to tubulin. S-100 also interacts with a component of whole MTPs (probably tubulin, on the basis of the above results). No S-100 binding to microtubule-associated proteins (MAPs) could be evidenced by the techniques employed in this study. On the contrary, some competition between S-100 and MAPs for binding sites or tubulin seems to occur.     

Surface plasmon resonance studies of complex formation between cytochrome c and bovine cytochrome c oxidase incorporated into a supported planar lipid bilayer. II. Binding of cytochrome c to oxidase-containing cardiolipin/phosphatidylcholine membranes.

Complex formation between horse heart cytochrome c (cyt c) and bovine cytochrome c oxidase (cco) incorporated into a supported planar egg phosphatidylcholine membrane containing varying amounts of cardiolipin (CL) (0-20 mol%) has been studied under low (10 mM) and medium (160 mM) ionic strength conditions by surface plasmon resonance (SPR) spectroscopy. Both specific and nonspecific modes of cyt c binding are observed. The dissociation constant of the specific interaction between cyt c and cco increases from approximately 6.5 microM at low ionic strength to 18 microM at medium ionic strength, whereas the final saturation level of bound protein is independent of salt concentration and corresponds to approximately 53% of the total cco molecules present in the membrane. This suggests a 1:1 binding stoichiometry between the two proteins. The nonspecific binding component is governed by electrostatic interactions between cyt c and the membrane lipids and results in a partially ionic strength-reversible protein-membrane association. Thus, hydrophobic interactions between cyt c and the membrane, which are the predominant mode of binding in the absence of cco, are greatly suppressed. Both the amount of nonspecifically bound protein and the binding affinity can be varied over a broad range by changing the ionic strength and the extent of CL incorporation into the membrane. Under conditions approximating the physiological state in the mitochondrion (i.e., 20 mol% CL and medium ionic strength), 1-1.5 cyt c molecules are bound to the lipid phase per molecule of cco, with a dissociation constant of 0.1 microM. The possible physiological significance of these observations is discussed.     

N-acetylcolchinol O-methyl ether and thiocolchicine, potent analogs of colchicine modified in the C ring. Evaluation of the mechanistic basis for their enhanced biological properties

Two colchicine analogs with modifications only in the C ring are better inhibitors than colchicine of cell growth and tubulin polymerization. Radiolabeled thiocolchicine (with a thiomethyl instead of a methoxy group at position C-10) and N-acetylcolchinol O-methyl ether (NCME) (with a methoxy-substituted benzenoid instead of the methoxy-substituted tropone C ring) were prepared for comparison with colchicine. Scatchard analysis indicated a single binding site with KD values of 1.0-2.3 microM. Thiocolchicine was bound 2-4 times as rapidly as colchicine, but the activation energies of the reactions were nearly identical (18 kcal/mol for colchicine, 20 kcal/mol for thiocolchicine). NCME bound to tubulin in a biphasic reaction. The faster phase was 60 times as fast as colchicine binding at 37 degrees C, and a substantial reaction occurred at 0 degrees C. The rate of the faster phase of NCME binding changed relatively little as a function of temperature, so the activation energy was only 7.0 kcal/mol. Dissociation reactions were also evaluated, and at 37 degrees C the half-lives of the tubulin-drug complexes were 11 min for NCME, 24 h for thiocolchicine, and 27 h for colchicine. Relative dissociation rates as a function of temperature varied little among the drug complexes. Activation energies for the dissociation reactions were 30 kcal/mol for thiocolchicine, 27 kcal/mol for NCME, and 24 kcal/mol for colchicine. Comparison of the activation energies of association and dissociation yielded free energies for the binding reactions of -20 kcal/mol for NCME, -10 kcal/mol for thiocolchicine, and -6 kcal/mol for colchicine. The greater effectiveness of NCME and thiocolchicine as compared with colchicine in biological assays probably derives from their more rapid binding to tubulin and the lower free energies of their binding reactions.     

Rate constants for calmodulin binding to Ca2+-ATPase in erythrocyte membranes

The Ca2+-ATPase (ATP phosphohydrolase, EC 3.6.1.3) in human erythrocyte membranes, which is part of the Ca2+ pump, can be activated by binding of calmodulin. Rate constants (k1) for association of calmodulin and enzyme, which depends on the Ca2+ concentration, have been determined by the aid of an enzyme model. k1 increased from 0.25 . 10(6) to 17.3 . 10(6) M-1 . min-1 (70 times) when the free Ca2+ concentration was raised from 0.7 to 20 microM. The binding of calmodulin to the Ca2+-ATPase is reversible. The rate constants (k-1) for dissociation of enzyme-calmodulin complex decreased from 6.0 to 0.044 min-1 (135 times) when the free Ca2+ concentration was increased from 0.1 to 2-20 microM. The apparent dissociation constant Kd = k-1/k1 accordingly increased from 2.5 nM to 25 microM (or higher) when the Ca2+ concentration was reduced from 20 to 0.1 microM. Therefore, at 10(-7) M free Ca2+ most of the Ca2+-pump enzyme will not bind calmodulin. For the intact cell the time dependences of activation and deactivation of the Ca2+-pump enzyme have been estimated from the rate constants above. The results suggest that the Ca2+ pump is well suited to maintain a cytosolic concentration of 10(-7) M free Ca2+ (or lower) in the unstimulated cell and, when the cell is stimulated, to allow transient Ca2+ signals up to approx. 10(-5) M in the cytosol.     

Yeast hexokinase: substrate-induced association--dissociation reactions in the binding of glucose to hexokinase P-II.

A method is described for the purification of native hexokinases P-I and P-II from yeast using preparative isoelectric focussing to separate the isozymes. The binding of glucose to hexokinase P-II, and the effect of this on the monomer--dimer association--dissociation reaction have been investigated quantitatively by a combination of titrations of intrinsic protein fluorescence and equilibrium ultracentrifugation. Association constants for the monomer-dimer reaction decreased with increasing pH, ionic strength and concentration of glucose. Saturating concentrations of glucose did not bring about complete dissociation of the enzyme showing that both sites were occupired in the dimer. At pH 8.0 and high ionic strength, where the enzyme existed as monomer, the dissociation constant of the enzyme-glucose complex was 3 X 10(-4) mol 1(-1) and was independent of the concentration of enzyme. Binding to the dimeric form at low pH and ionic strength (I=0.02 mol 1(-1), pH less than 7.5) was also independent of enzyme concentration (in the range 10-1000 mug ml-1) but was much weaker. The process could be described by a single dissociation constant, showing that the two available sites on the dimer were equivalent and non-cooperative; values of the intrinsic dissociation constant varied from 2.5 X 10(-3) mol 1(-1) at pH 7.0 to 6 X 10(-3) at pH 6.5. Under intermediate conditions (pH 7.0, ionic strength=0.15 mol 1(-1)), where monomer and dimer coexisted, the binding of glucose showed weak positive cooperatively (Hill coefficient 1.2); in addition, the binding was dependent upon the concentration of enzyme in the direction of stronger binding at lower concentrations. The results show that the phenomenon of half-sites reactivity observed in the binding of glucose to crystalline hexokinase P-II does not occur in solution; the simplest explanation of our finding the two sites to be equivalent is that the dimer results from the homologous association of two identical subunits.     

Aluminum interaction with calmodulin. Evidence for altered structure and function from optical and enzymatic studies

The interaction of aluminum ions with bovine brain calmodulin has been examined by fluorescence spectroscopy, circular dichroic spectrophotometry and equilibrium dialysis, and by the calmodulin-dependent activation of 3',5'-cyclic nucleotide phosphodiesterase. These experiments show that aluminum binds stoichiometrically and cooperatively to calmodulin. Binding of aluminum at a molar ratio of 2:1 to calmodulin suffices to induce a major structural change. Estimates from spectroscopic data indicate that the binding affinity for the first mol of aluminum bound to the protein is about one order of magnitude stronger than that of calcium to its comparable site. These estimates agree with a dissociation constant of 0.4 microM derived from equilibrium dialysis experiments. Interaction of aluminum with calmodulin induces a helix-coil transition and enhances the hydrophobic surface area much more than calcium does. A molar ratio of 4:1 for [aluminum]/[calmodulin] is sufficient to block completely the activity of the calcium-calmodulin-dependent phosphodiesterase. Highly hydrated aluminum ions apparently promote solvent-rich, disordered polypeptide regions in calmodulin which, in turn, profoundly influence the protein's flexibility.     

Fluorescence studies on the interaction between two cytochromes extracted from the yeast, Hansenula anomala

The binding of cytochrome c to the cytochrome b2 core, both extracted from the yeast, Hansenula anomala, has been studied. Cytochrome b2 core heme is extracted and replaced by the fluorescent probe, 2-p-toluidinylnaphthalene-6-sulfonate (TNS). A dissociation constant in the range of 85 microM is found for the TNS-apoprotein complex with a stoichiometry of 1:1. The interaction between the two proteins is followed by monitoring changes in the TNS fluorescence. We find the interaction between the cytochrome c and the apocytochrome b2 core to be dependent upon the ionic strength. The dissociation constant of this complex at 20 mM ionic strength is 6 +/- 2 microM with a 1:1 stoichiometry. This dissociation constant is similar to that estimated, by other researchers, for the dimer Zn cytochrome c-cytochrome b2 core complex.     

Thermodynamics of Ca2+ binding to calmodulin and its tryptic fragments.

The binding of Ca2+ to calmodulin and its two tryptic fragments has been studied using microcalorimetry. The binding process is accompanied by the uptake or release of protons, depending on the ionic strength. With no added salt, the total enthalpy change for the binding of four calcium ions to calmodulin is -41 kJ mol-1 but in the presence of 0.15 mM KCl delta Htot is +17 kJ mol-1. The mode of binding of Ca2+ is also completely different with and without added salt. It is also shown that for the C-terminal fragment of calmodulin, TR2C, the drastic reduction in delta Gtot for the binding process on increasing the ionic strength is largely an enthalpic effect. Domain interactions in calmodulin are indicated by the fact that the sum of the enthalpies of calcium binding to the two tryptic fragments is not the same as the total binding enthalpy to calmodulin itself. The binding of Ca2+ to calmodulin has also been studied calorimetrically at different temperatures in the range 21-37 degrees C. delta Cp is large and negative in this interval.     

Drug-protein interactions: binding of chlorpromazine to calmodulin, calmodulin fragments, and related calcium binding proteins

The quantitative binding of a phenothiazine drug to calmodulin, calmodulin fragments, and structurally related calcium binding proteins was measured under conditions of thermodynamic equilibrium by using a gel filtration method. Plant and animal calmodulins, troponin C, S100 alpha, and S100 beta bind chlorpromazine in a calcium-dependent manner with different stoichiometries and affinities for the drug. The interaction between calmodulin and chlorpromazine appears to be a complex, calcium-dependent phenomenon. Bovine brain calmodulin bound approximately 5 mol of drug per mol of protein with apparent half-maximal binding at 17 microM drug. Large fragments of calmodulin had limited ability to bind chlorpromazine. The largest fragment, containing residues 1-90, retained only 5% of the drug binding activity of the intact protein. A reinvestigation of the chlorpromazine inhibition of calmodulin stimulation of cyclic nucleotide phosphodiesterase further indicated a complex, multiple equilibrium among the reaction components and demonstrated that the order of addition of components to the reaction altered the drug concentration required for half-maximal inhibition of the activity over a 10-fold range. These results confirm previous observations using immobilized phenothiazines [Marshak, D.R., Watterson, D.M., & Van Eldik, L.J. (1981) Proc. Natl. Acad. Sci. U.S.A. 78, 6793-6797] that indicated a subclass of calcium-modulated proteins bound phenothiazines in a calcium-dependent manner, demonstrate that the interaction between phenothiazines and calmodulin is more complex than previously assumed, and suggest that extended regions of the calmodulin molecule capable of forming the appropriate conformation are required for specific, high-affinity, calcium-dependent drug binding activity.     

Thermodynamics of calmodulin binding to cardiac and skeletal muscle ryanodine receptor ion channels

The skeletal muscle (RyR1) and cardiac muscle (RyR2) ryanodine receptor calcium release channels contain a single, conserved calmodulin (CaM) binding domain, yet are differentially regulated by CaM. Here, we report that high-affinity [(35)S]CaM binding to RyR1 is driven by favorable enthalpic and entropic contributions at Ca(2+) concentrations from <0.01 to 100 microM. At 0.15 microM Ca(2+), [(35)S]CaM bound to RyR2 with decreased affinity and binding enthalpy compared with RyR1. The rates of [(35)S]CaM dissociation from RyR1 increased as the temperature was raised, whereas at 0.15 microM Ca(2+) the rate from RyR2 was little affected. The results suggest major differences in the energetics of CaM binding to and dissociation from RyR1 and RyR2.     

Calcium binding to complexes of calmodulin and calmodulin binding proteins

The free energy of coupling for binding of Ca2+ and the calmodulin-sensitive phosphodiesterase to calmodulin was determined and compared to coupling energies for two other calmodulin binding proteins, troponin I and myosin light chain kinase. Free energies of coupling were determined by quantitating binding of Ca2+ to calmodulin complexed to calmodulin binding proteins with Quin 2 to monitor free Ca2+ concentrations. The geometric means of the dissociation constants (-Kd) for Ca2+ binding to calmodulin in the presence of equimolar rabbit skeletal muscle troponin I, rabbit skeletal muscle myosin light chain kinase, and bovine heart calmodulin sensitive phosphodiesterase were 2.1, 1.1, and 0.55 microM. The free-energy couplings for the binding of four Ca2+ and these proteins to calmodulin were -4.48, -6.00, and -7.64 kcal, respectively. The Ca2+-independent Kd for binding of the phosphodiesterase to calmodulin was estimated at 80 mM, indicating that complexes between calmodulin and this enzyme would not exist within the cell under low Ca2+ conditions. The large free-energy coupling values reflect the increase in Ca2+ affinity of calmodulin when it is complexed to calmodulin binding proteins and define the apparent positive cooperativity for Ca2+ binding expected for each system. These data suggest that in vitro differences in free-energy coupling for various calmodulin-regulated enzymes may lead to differing Ca2+ sensitivities of the enzymes.