A fluorescence temperature-jump study on Ca2(+)-induced conformational changes in calmodulin

Calmodulin has been shown to alter its conformation so as to interact with a number of target proteins upon Ca2+ binding. A Ca2(+)-binding study of calmodulin was performed by monitoring the fluorescence of intrinsic tyrosine residues and the probe 1-anilinonaphthalene-8-sulfonate (ANS). ANS fluorescence was shown to reflect Ca2+ binding to both high- and low-affinity sites. On the one hand, tyrosine fluorescence was sensitive only to the high-affinity Ca2+ binding. Temperature-jump investigation of the ternary complex of Ca2(+)-calmodulin-ANS in combination with monitoring of ANS fluorescence demonstrated the kinetic characteristics of the conformational change. The relaxation process was attributed to Ca2(+)-induced conformational change and the rate constants of this process were evaluated. On the basis of the rate constants of the conformational change, a rapid response of calmodulin in Ca2+ signaling is suggested.     

Ca2+ binding and conformational change in two series of point mutations to the individual Ca(2+)-binding sites of calmodulin.

Two series of site-directed mutations to the individual Ca(2+)-binding sites of Drosophila melanogaster calmodulin have been generated and studied. In each mutant, a conserved glutamic acid residue at position 12 in all of the Ca(2+)-binding loops has been mutated in one site. In one series the residue is changed to glutamine; in the second series the change is to lysine. The Ca(2+)-binding properties of these mutants and the wild-type protein under pseudo-physiological conditions are presented. In addition, Ca(2+)-induced changes to the environment of the single tyrosine residue (Tyr-138) have been studied for some of the mutants. Ca2+ binding to the wild-type protein is best modeled as two pairs of sites with a higher affinity pair that shows strong cooperativity. For all but one of these eight mutant proteins, only three Ca(2+)-binding events can be detected. In three of the amino-terminal mutants, the three residual sites are (i) a pair of relatively high affinity sites and (ii) a weakened low affinity site. For all four carboxyl-terminal mutations, the residual sites are three relatively low affinity sites. In general, mutations to sites 2 and 4 prove more deleterious than mutations to sites 1 and 3. The Ca(2+)-induced conformational changes in the vicinity of Tyr-138 are relatively undisturbed by mutations of site 1. However, the changes to Tyr-138 in the carboxyl-terminal site mutants indicate that upon disruption of the cooperative binding at the high affinity sites, conformational change in the carboxyl terminus occurs in two phases. It appears that binding of Ca2+ to either carboxyl-terminal site can elicit the first phase of the response but the second phase is almost abolished when site 4 is the mutated site. The final conformations of site 3 and 4 mutants are thus significantly different.     

Ca2(+)-induced conformational changes and location of Ca2+ transport sites in sarcoplasmic reticulum Ca2(+)-ATPase as detected by the use of proteolytic enzyme (V8)

Treatment of Ca2(+)-ATPase from sarcoplasmic reticulum with V8 protease from Staphylococcus aureus produced appreciable amounts of a Ca2(+)-ATPase fragment (p85) in the presence of Ca2+ (E1 conformation of the enzyme), along with many other peptide fragments that were also formed in the presence of [ethylenebis(oxyethylenenitrilo)]tetraacetic acid (E2 conformation). p85 was formed as a carboxyl-terminal cleavage product of Ca2(+)-ATPase by a split of the peptide bond between Glu-231 and Ile-232. Other conformation-dependent V8 splits were localized to the "hinge" region, involved in ATP binding, between the middle and COOH-terminal one-third of the Ca2(+)-ATPase polypeptide chain. Representative split products in this region (p48,p31) were identified as NH2-terminal and COOH-terminal cleavage products of p85. In the membrane p85 probably remains associated with its complementary NH2-terminal fragment(s) and retains the capacity to bind Ca2+ as evidenced by resistance to V8 degradation in Ca2+ and ability to become phosphorylated by ATP. However, the hydrolysis rate of the phosphorylated enzyme is reduced, indicating that peptide cleavage at Glu-231 interferes with Ca2+ transport steps after phosphorylation. Binding of Ca2+ to V8 and tryptic fragments of Ca2(+)-ATPase was studied on the basis of Ca2(+)-induced changes in electrophoretic mobility and 45Ca2+ autoradiography after transfer of peptides to Immobilon membranes. These data indicate binding by the NH2-terminal 1-198 amino acid residues (corresponding to the tryptic A2 fragment) and the COOH-terminal 715-1001 amino acid residues (corresponding to p31). By contrast the central portion of Ca2(+)-ATPase, including the NH2-terminal portion of p85, is devoid of Ca2+ binding. These results question an earlier proposition that Ca2(+)-binding is located to the "stalk" region of Ca2(+)-ATPase (Brandl, C. J., Green, N. M., Korczak, B., and MacLennan, D. H.) (1986) Cell 44, 597-607) but are in agreement with recent data obtained by oligonucleotide-directed mutagenesis of Ca2(+)-ATPase (Clarke, D. M., Loo, T. W., Inesi, G., and MacLennan, D. H. (1989) Nature 339, 476-478). These different studies suggest that Ca2+ translocation sites may have an intramembranous location and are formed predominantly by the carboxyl-terminal part of the Ca2(+)-ATPase polypeptide chain.     

Low affinity Ca2+-binding sites of calcineurin B mediate conformational changes in calcineurin A

Limited proteolysis of calcineurin in the presence of Ca(2+) suggested that its calmodulin-binding domain, readily degraded by proteases, was unfolded while calcineurin B was compactly folded [Hubbard, M. J., and Klee, C. B. (1989) Biochemistry 28, 1868-1874]. Moreover, in the crystal structure of calcineurin, with the four Ca(2+) sites of calcineurin B occupied, the calmodulin-binding domain is not visible in the electron density map [Kissinger, C. R., et al. (1995) Nature 378, 641-644]. Limited proteolysis of calcineurin in the presence of EGTA, shows that, when the low affinity sites of calcineurin B are not occupied, the calmodulin-binding domain is completely protected against proteolytic attack. Slow cleavages are, however, detected in the linker region between the calmodulin-binding and the autoinhibitory domains of calcineurin A. Upon prolonged exposure to the protease, selective cleavages in carboxyl-terminal end of the first helix and the central helix linker of calcineurin B and the calcineurin B-binding helix of calcineurin A are also detected. Thus, Ca(2+) binding to the low-affinity sites of calcineurin B affects the conformation of calcineurin B and induces a conformational change of the regulatory domain of calcineurin A, resulting in the exposure of the calmodulin-binding domain. This conformational change is needed for the partial activation of the enzyme in the absence of calmodulin and its full activation by calmodulin. A synthetic peptide corresponding to the calmodulin-binding domain is shown to interact with a peptide corresponding to the calcineurin B-binding domain, and this interaction is prevented by calcineurin B in the presence but not the absence of Ca(2+). These observations provide a mechanism to explain the dependence on Ca(2+) binding to calcineurin B for calmodulin activation and for the 10-20-fold increase in affinity of calcineurin for Ca(2+) upon removal of the regulatory domain by limited proteolysis [Stemmer, P. M., and Klee, C. B. (1994) Biochemistry 33, 6859-6866].     

Ca2(+)-induced conformational change and aggregation of chromogranin A

Chromogranin A, the most abundant protein in bovine adrenal chromaffin granules, bound calmodulin in a Ca2(+)-dependent manner, and the calmodulin-binding property was utilized to purify chromogranin A. Chromogranin A has been described in the past as a "random-coil polypeptide" with little alpha-helix or beta-sheet conformation. However, circular dichroism measurements with pure, native chromogranin A revealed relatively high alpha-helical contents (40% at the intravesicular pH of 5.5). Fluorescence studies confirmed previous observations that chromogranin A binds Ca2+ with low affinity. Considering the high concentration of Ca2+ in the secretory vesicle, the effect of Ca2+ on the secondary structure and self-association of chromogranin A was examined. Ca2+ induced a decrease of alpha-helicity of chromogranin A from 40 to 30% at pH 5.5. In contrast, at pH 7.5 the same amount of Ca2+ increased alpha-helicity of the protein from 25 to 40%. Boiling of the adrenal extract, a commonly used purification procedure for chromogranin A, resulted in the isolation of conformationally distinct chromogranin A molecule. Unlike secretory protein-I of the parathyroid gland (Gorr, S.-V., Dean, W. L., Radley, T. L., and Cohn, D. V. (1988) Bone Mineral 4, 17-25), chromogranin A aggregated rapidly in the presence of Ca2+. The extent and rate of aggregation were highly dependent on Ca2+ concentration. Although both the rate and extent of aggregation at pH 7.5 were much lower than those at pH 5.5, aggregation of chromogranin A proceeded at both pH's. In this respect, chromogranin A differs from human chromogranin C which was shown by Gerdes et al. (Gerdes, H.-H., Rosa, P., Phillips, E., Baeuerle, P. A., Frank, R., Argos, P., and Huttner, W. B. (1989) J. Biol. Chem. 264, 12009-12015) to aggregate at pH 5.2 but not at pH 7.4.     

Volume changes upon addition of Ca2+ to calmodulin: Ca2+-calmodulin conformational states

Measurement of the volume change by a rapid density method upon sequential addition of calcium ion to calmodulin showed relatively large, nonuniform increases for the first 4 moles Ca2+ per mole calmodulin. Substantially larger volume increases (approximately 15 ml/mol protein) were observed upon addition of the second and fourth moles Ca2+ relative to the first and third moles added per mole calmodulin. A total volume increase of approximately 170 ml/mol protein attended the addition of 4 moles Ca2+, as expected for multidentate carboxylate coordination to metal ion. Marginal changes in volume were observed upon further additions, the data showing a remarkably sharp transition after [Ca2+]/[calmodulin] = 4. The results are consistent with an ordered binding of Ca2+ in which pair-wise additions produce similar volume changes; the volume change behavior, however, does not indicate an absence of distinct conformational states for a Ca2+(1)-calmodulin and a Ca2+(3)-calmodulin complex as has been proposed on the basis of 1H-NMR evidences.     

The effects of Mg2+ on the Ca2+-binding properties and Ca2+-induced tyrosine-fluorescence changes of calmodulin isolated from rabbit skeletal muscle

Calmodulin from phosphorylase kinase (the delta subunit) was obtained as a homogeneous protein in a spectroscopically pure form, and its interaction with Ca2+ and Mg2+ was studied. 1. Determination of the binding of Ca2+ to calmodulin in a buffer of low ionic strength (0.001 M) show that it contained six binding sites for this divalent cation. 2. Employment of a buffer of high ionic strength (0.18 M) allowed two Ca2+/Mg2+-binding sites (KdCa2+ = 4.0 microM), which showed Ca2+ - Mg2+ competition (KdMg2+ = 0.75 mM), to be distinguished from two Ca2+-specific binding sites (KdCa2+ = 40 microM). The remaining two Ca2+-binding sites are not observed under these conditions and are probably Mg2+-specific binding sites. Thus, the binding sites on calmodulin are remarkably similar to those of the homologous Ca2+-binding protein, troponin C [Potter and Gergely (1975) J. Biol. Chem. 250, 4628, 4633]. 3. The conformational states of calmodulin are defined by Ca2+, Mg2+ and salt concentrations, which can be differentiated by their Ca2+ affinity and their relative tyrosine fluorescence intensity. In a buffer of high ionic strength, Mg2+ induces a conformation which enhances the apparent affinity for Ca2+. Addition of Ca2+ leads to an enhancement of the tyrosine fluorescence intensity, which remains enhanced even upon removal of Ca2+ by chelation with EGTA. Only additional chelation of Mg2+ with EDTA reduces the tyrosine fluorescence intensity. 4. Comparison of the Ca2+-binding parameters of phosphorylase kinase, which were previously determined under identical experimental conditions [Kilimann and Heilmeyer (1977) Eur. J. Biochem. 73, 191-197], with those reported here on calmodulin isolated from this enzyme, allows the conclusion that Ca2+ binding to the holoenzyme occurs by binding to the delta subunit exclusively. 5. Ca2+ binding and Ca2+ activation of phosphorylase kinase are compared and discussed in relation to the Ca2+ and Mg2+-induced conformation changes of calmodulin.     

Immuno-identification of Ca2+-induced conformational changes in human gelsolin and brevin

Gelsolin is a 90,000-mol-wt protein with two actin and two high affinity calcium-binding sites that can form complexes with Ca2+ ions and monomeric actin. These complexes will nucleate filament growth and cap the barbed end of filaments, but will not fragment F-actin. Uncomplexed gelsolin severs F-actin. (Bryan, J., and L. M. Coluccio, 1985, J. Cell Biol., 101:1236-1244). These associations with actin are modulated by Ca2+. We have purified and characterized monoclonal antibodies that recognize Ca2+-induced conformational changes in human platelet gelsolin (G) and human plasma brevin (B), a closely related protein. Two hybridomas, 8G5 and 4F8, were adapted to growth in serum-free medium. 8G5 was found to secrete an IgG; 4F8 secretes an IgA. On immunoblots, both antibodies gave a strong reaction if Ca2+ was present, but gave barely detectable reactions if EGTA was used. 8G5 IgG-Sepharose columns retained gelsolin (as GCa2) or brevin (as BCa2) in 0.1 mM CaCl2 containing buffers, but released these molecules when eluted with 4 mM EGTA. 8G5 IgG-Sepharose columns also retained gelsolin-actin-Ca2+ complexes, as GA1Ca2 or higher oligomers from platelet extracts containing 0.1 mM CaCl2. Elution with 4 mM EGTA released material that gel filtration showed to be the EGTA-stable 130,000-mol-wt gelsolin-actin complex, GA1Ca1. The results demonstrate that the 8G5 IgG recognizes a conformation of gelsolin or brevin induced by binding of an easily exchangeable Ca2+ ion. Actin is not required for this conformational change, and the antibody discriminates, for example, GCa2 from G and GCa1. A 4F8 IgA-Sepharose column retained brevin or gelsolin in 0.1 mM CaCl2-containing buffers, but, like the 8G5 IgG, released these molecules when eluted with 4 mM EGTA. The 4F8 IgA column also retained gelsolin or brevin-actin-Ca2+ complexes, for example, as BA1Ca2, or higher oligomers, in 0.1 mM CaCl2. No protein was recovered, however, upon elution with 4 mM EGTA, but elution with 0.1 M glycine-HCl, pH 2.8, released bound brevin or gelsolin and actin. Similarly, preformed brevin-actin-Ca2+ complex, equilibrated with EGTA, was retained by 4F8 IgA-Sepharose. The results demonstrate that the 4F8 IgA recognizes a conformation of gelsolin or brevin that is maintained and presumably induced by binding of a nonexchangeable Ca2+ ion that is trapped in the complex.     

Persistent Ca2(+)-induced activation of erythrocyte membrane Ca2(+)-ATPase unrelated to calpain proteolysis

Preincubation of human erythrocyte membranes with calcium in the submillimolar to millimolar concentration range resulted in an increase of the Ca2+ affinity and apparent maximum velocity of the Ca2(+)-stimulated Mg2(+)-dependent ATPase (Ca2(+)-ATPase). The activation was persistent, as it was not reversed when the Ca2(+)-preincubated membranes were washed with ethylene glycol bis(beta-aminoethyl ether) N,N'-tetraacetic acid-containing buffers. Magnesium was not required for the activation, whereas greater than 2 mM Mg2+ partially antagonized the activation by Ca2+. In some membrane preparations ATP was required in addition to Ca2+ for activation of the Ca2(+)-ATPase, but nonhydrolyzable analogs of ATP had the same effect. Calmodulin prevented the activation by Ca2+ over the same concentration range in which it interacts with the Ca2(+)-ATPase. Taken together the results obtained provided strong evidence that the Ca2+ activation of the enzyme was not due to proteolytic cleavage by endogenous calpain. Thus, activation by Ca2+ was not blocked by leupeptin (100-200 microM), did not require dithiothreitol, and occurred at Ca2+ concentrations greater than those required for activation of calpain I. Furthermore, Ca2+ activation did not result in change in the mobility the native 136-kDa species of the Ca2(+)-ATPase on SDS-gel electrophoresis. Moreover, solubilization of the Ca2(+)-pretreated membranes with Triton X-100 reversed the Ca2+ activation of the Ca2(+)-ATPase. On the other hand, Ca2(+)-pretreatment of the membranes modified the susceptibility of the Ca2(+)-ATPase to both cleavage and activation by exogenously added calpain I. We conclude that pretreatment of Ca2(+)-ATPase in erythrocyte membranes with millimolar Ca2+ activates the enzyme by inducing a persistent conformational change of the enzyme which is, however, subsequently reversed by detergent solubilization.     

Intra- and extraluminal sarcoplasmic reticulum membrane regulatory sites for Ca2(+)-induced Ca2+ release.

A heavy skeletal muscle sarcoplasmic reticulum (SR) fraction was actively loaded stepwise with calcium until Ca2(+)-induced Ca2+ release occurred. The total Ca2+ load, T1, at which release occurred is postulated to be regulated by an intraluminal, low-affinity receptor. After obtaining T1, the critical concentration of Ca2+ required extraluminally (T2) was determined. T1 averaged 58.6 +/- S.D., 6.9 nmol Ca2+/mg SR and T2 averaged 2.14 +/- S.D., 0.24 microM. Both T1 and T2 were increased by Mg2+ and decreased by caffeine. Ruthenium red increased T2 more than T1 while ryanodine had no effect on T1 but markedly increased T2. The results suggest that two Ca2+ regulatory sites may be functional for Ca2(+)-induced Ca2+ release from SR.     

Low-affinity Ca(2+)-binding sites versus Zn(2+)-binding sites in histidine-rich Ca(2+)-binding protein of skeletal muscle sarcoplasmic reticulum.

Histidine-rich Ca(2+)-binding protein (HRC) is a 170 kDa protein that can be identified in the isolated sarcoplasmic reticulum from rabbit skeletal muscle by its ability to bind [125I]low-density lipoprotein on blots after SDS-PAGE and that appears to be bound to the junctional membrane through calcium bridges. Molecular cDNA cloning of this protein predicts the existence of a Ca(2+)-binding domain and of a distinct heavy-metal binding domain at the cystein-rich COOH-terminus. Here we demonstrate, using radioactive ligand blot techniques, that HRC protein binds 45Ca at low affinity, as well as being able to bind 65Zn, but at different sites, that are largely inhibitable by prior reductive alkylation of the protein. In contrast to Ca(2+)-binding protein calsequestrin not having detectable 65Zn-binding sites, HRC protein bound selectively to immobilized Zn2+ on IDA-agarose affinity columns. Our results also indicate that rabbit and human 140 kDa HRC protein have common properties.     

Ca2+ and Mg2+-binding and a putative calmodulin type Ca2+-binding site in Synechococcus Photosystem II

Thylakoids and Photosystem II particles prepared from the cyanobacterium Synechococcus PCC 7942 washed with a HEPES/glycerol buffer exhibited low rates of light-induced oxygen evolution. Addition of either Ca²⁺ or Mg²⁺ to both thylakoids and Photosystem II particles increased oxygen evolution independently, maximal rates being obtained by addition of both ions. If either preparation was washed with NaCl, light induced O₂ evolution was completely inhibited, but re-activated in the same manner by Ca²⁺ and Mg²⁺ but to a lower level. In the presence of Mg²⁺, the reactivation of O₂ evolution by Ca²⁺ allowed sigmoid kinetics, implying co-operative binding. The results are interpreted as indicating that not only Ca²⁺, but also Mg²⁺, is essential for light-induced oxygen evolution in thylakoids and Photosystem II particles from Synechococcus PC 7942. The significance of the reactivation kinetics is discussed. Reactivation by Ca²⁺ was inhibited by antibodies to mammalian calmodulin, indicating that the binding site in Photosystem II may be analogous to that of this protein.Abbreviation HEPES n-2-Hydroxyethylpiperazine--2-ethane sulphonic acid     

Inhibition of Na(+)-independent H+ pump by Na(+)-induced changes in cell Ca2+

Apical membrane H+ extrusion in the renal outer medullary collecting duct, inner stripe, is mediated by a Na(+)-independent H+ pump. To examine the regulation of this transporter, cell pH and cell Ca2+ were measured microfluorometrically in in vitro perfused tubules using 2',7'-bis(carboxyethyl)-5(6)-carboxyfluorescein and fura-2, respectively. Apical membrane H+ pump activity, assayed as cell pH recovery from a series of acid loads (NH3/NH+4 prepulse) in the total absence of ambient Na+, initially occurred at a slow rate (0.06 +/- 0.02 pH units/min), which was not sufficient to account for physiologic rates of H+ extrusion. Over 15-20 min after the initial acid load, the rate of Na(+)-independent cell pH recovery increased to 0.63 +/- 0.09 pH units/min, associated with a steady-state cell pH greater than the initial pre-acid load cell pH. This pattern suggested an initial suppression followed by a delayed activation of the apical membrane H+ pump. Replacement of peritubular Na+ with choline or N-methyl-D-glucosamine resulted in an initial spike increase in cell Ca2+ followed by a sustained increase in cell Ca2+. The initial rate of Na(+)-independent cell pH recovery could be increased by elimination of the Na+ removal-induced sustained cell Ca2+ elevation by: (a) performing studies in the presence of 135 mM peritubular Na+ (1 mM peritubular amiloride used to inhibit basolateral membrane Na+/H+ antiport); (b) clamping cell Ca2+ low with dimethyl-BAPTA, an intracellular Ca2+ chelating agent; or (c) removal of extracellular Ca2+. Cell acidification induced a spike increase in cell Ca2+. The late acceleration of Na(+)-independent cell pH recovery was independent of Na+ removal and of the method used to acidify the cell, but was eliminated by prevention of the cell Ca2+ spike and markedly delayed by the microfilament-disrupting agent, cytochalasin B. This study demonstrates that peritubular Na+ removal results in a sustained elevation in cell Ca2+, which inhibits the apical membrane H+ pump. In addition, rapid cell acidification associated with a spike increase in cell Ca2+ leads to a delayed activation of the H+ pump. Thus, cell Ca2+ per se, or a Ca(2+)-activated pathway, can modulate H+ pump activity.     

Probing Ca2+-induced conformational changes in porcine calmodulin by H/D exchange and ESI-MS: effect of cations and ionic strength

We applied a new method, "protein-ligand interaction using mass spectrometry, titration, and H/D exchange" (PLIMSTEX) [Zhu, M. M. (2003) J. Am. Chem. Soc. 125, 5252-5253], to determine the conformational changes, binding stoichiometry, and binding constants for Ca(2+) interactions with calmodulin (CaM) under varying conditions of electrolyte identity and ionic strength. The outcome shows that CaM becomes less solvent-accessible and more compact upon Ca(2+)-binding, as revealed by the PLIMSTEX curve. The formation of CaM-4Ca species is the biggest contributor to the shape of the titration curve, indicating that the formation of this species accounts for the largest conformational change in the stepwise Ca(2+) binding. The Ca(2+)-binding constants, when comparisons permit, agree with those in the literature within a factor of 3. The binding is influenced by ionic strength and the presence of other cations, although many of these cations do not cause conformational change in apo-CaM. Furthermore, Ca(2+)-saturated CaM exhibits larger protection and higher Ca(2+) affinity in media of low rather than high ionic strength. Both Ca(2+) and Mg(2+) bind to CaM with different affinities, causing different conformational changes. K(+), if it does bind, causes no detectable conformational change, and interactions of Ca(2+) with CaM in the presence of Li(+), Na(+), and K(+) occur with similar affinities and associated changes in solvent accessibility. These metal ion effects point to nonspecific rather than competitive binding of alkali-metal ions. The rates of deuterium uptake by the various CaM-xCa species follow a three-group (fast, intermediate, slow), pseudo-first-order kinetics model. Calcium binding causes the number of amide hydrogens to shift from the fast to the slow group. The results taken together not only provide new insight into CaM but also indicate that both PLIMSTEX and kinetic modeling of H/D exchange data may become general methods for probing protein conformations and quantifying protein-ligand interactions.     

Ca2+-induced conformational changes of spin-labeled g2 chain bound to myosin and the effect of phosphorylation.

One of the low molecular weight components of myosin, g2, was isolated by alkali treatment of myosin and was chemically modified with a spin label reagent, 4-maleimido-2,2,6,6-tetramethylpiperidinooxyl. The label on g2 showed a rather weakly immobilized ESR spectrum and it was clearly affected by Ca2+; the half-maximal change was at around pCa 4. The spin-labeled g2 was incorporated into myosin by exchange with the intrinsic g2 of myosin in 0.6 M KSCN or 4 M LiC1. The label on g2 became strongly immobilized on association with myosin. Under the conditions used, ESR spectral change due to Ca2+ occurred at two different concentration ranges, which were as low as pCa 8 and at around pCa 4. Phosphorylated g2 was isolated from myosin after the protein kinase [EC 2.1.1.37]-catalyzed phosphorylation of myosin and it was also modified with the maleimide label. Dephosphorylation of the phosphorylated g2 was performed using E. coli alkaline phosphatase [EC 3.1.3.1]. The effects of Ca2+ on the ESR spectra of phosphorylated and dephosphorylated g2 were investigated on the state associated with myosin. A change in the ESR spectrum from strongly immobilized to weakly immobilized states was observed with both g2 chains on the addition of Ca2+. However, the effective concentration ranges of Ca2+ were quite different; around pCa 4 for the phosphorylated g2 and around pCa 8 for the dephosphorylated g2. The results indicate that g2 undergoes a conformational change at physiological levels of Ca2+ sufficient to saturate troponin, but it does not do so after phosphorylation.     

Kinetics of the conformational change of skeletal troponin C induced by Ca2+-Mg2+ exchange at the high-affinity Ca2+-binding sites

The rate constant of the conformational change of skeletal troponin C (TnC) induced by the Ca2+ binding reaction with the high-affinity Ca2+-binding sites was determined in the presence of Mg2+ by the fluorescence stopped-flow method in 0.1 M KCl, 50 mM Na-cacodylate-HCl pH 7.0 at 20 degrees C. The [MgCl2] dependence of the rate constants of the observed biphasic conformational change leveled off at the high [MgCl2] region: the rate constants were 60 +/- 9 s-1 and 8 +/- 2 s-1, respectively. These values are larger than the rate constants of the biphasic fluorescence intensity change of TnC induced by Mg2+ removal reaction at the high-affinity Ca2+-binding sites (37 +/- 7 s-1 and 3.0 +/- 0.6 s-1) under the same experimental conditions. These results suggest that the Ca2+-Mg2+ exchange reaction at the high-affinity Ca2+-binding sites is faster than the resultant conformational change accompanying the fluorescence intensity change. Based on these results, we also reexamine the molecular kinetic mechanism of the conformational change of the protein induced by the Mg2+ binding or removal reaction with the high affinity Ca2+-binding sites of skeletal TnC.     

Kinetic studies show that Ca2+ and Tb3+ have different binding preferences toward the four Ca2+-binding sites of calmodulin

The stepwise addition of Tb3+ to calmodulin yields a large tyrosine-sensitized Tb3+ luminescence enhancement as the third and fourth ions bind to the protein [Wang, C.-L. A., Aquaron, R. R., Leavis, P. C., & Gergely, J. (1982) Eur. J. Biochem. 124, 7-12]. Since the only tyrosine residues in calmodulin are located within binding sites III and IV, these results suggest that Tb3+ binds first to sites I and II. Recent NMR studies have provided evidence that Ca2+, on the other hand, binds preferentially to sites III and IV. Kinetic studies using a stopped-flow apparatus also show that the preferential binding of Ca2+ and lanthanide ions is different. Upon rapid mixing of 2Ca-calmodulin with two Tb3+ ions, there was a small and rapid tyrosine fluorescence change, but no Tb3+ luminescence was observed, indicating that Tb3+ binds to sites I and II but not sites III and IV. When two Tb3+ ions are mixed with 2Dy-calmodulin, Tb3+ luminescence rises rapidly as Tb3+ binds to the empty sites III and IV, followed by a more gradual decrease (k = 0.4 s-1 as the ions redistribute themselves over the four sites. These results indicate that (i) both Tb3+ and Dy3+ prefer binding to sites I and II of calmodulin and (ii) the binding of Tb3+ to calmodulin is not impeded by the presence of two Ca2+ ions initially bound to the protein. Thus, the Ca2+ and lanthanide ions must exhibit opposite preferences for the four sites of calmodulin: sites III and IV are the high-affinity sites for Ca2+, whereas Tb3+ and Dy3+ prefer sites I and II.