Cooperativity of the calcium switch of regulated rabbit actomyosin system

Summary The concentration range required for calcium activation of skeletal myofibrillar ATPase activity has previously been attributed to simultaneous binding of two calcium ions to each troponin. We present data representative of the majority of myofibrillar preparations and data with acto subfragment-1 (S-1) whose calcium activation of ATPase activity occurs over a much too narrow range of calcium concentrations to be so explained. S-1 binding significantly broadened the range of Ca²⁺ concentrations over which activation occurred but not to the extent that is associated with simultaneous binding of 2 calcium ions.     

Calcium sensitive binding of troponin to actin-tropomyosin: a two-site model for troponin action

Troponin reconstituted from the inhibitory component (troponin-I) and calcium binding protein (troponin-C) binds readily to actin-tropomyosin in 0.1 mm-EGTA but only poorly in 0.01 mm-CaCl₂ or 0.1 mm-Ca-EGTA. Troponin prepared by extraction of myofibrils with mersalyl, an organic mercurial, contains only these two components and also shows this calcium-sensitive binding and is deficient in its ability to bind to tropomyosin. Troponin-I + C is unable to confer calcium sensitivity on the Mg²⁺ activated actomyosin ATPase in concentrations at which native troponin is fully effective and the ATPase activity remains high in the absence of calcium. Addition of the tropomyosin binding component (troponin-T) to the other two components restores their ability to remain associated with actin-tropomyosin in the presence of calcium as does native troponin; calcium sensitivity is also regained. The results of these experiments have been interpreted in terms of a two-site mechanism of troponin action.     

A molecular dynamics study of an L-type calcium channel model

In this work, we propose a molecular model of the L-type calcium channel pore from the human cardiac alpha1 subunit. Four glutamic acid residues, the EEEE locus, located at highly conserved P loops (also called SS1-SS2 segments) of the alpha1 subunit, molecularly express the calcium channel selectivity. The proposed alpha-helix structure for the SS1 segment, analyzed through molecular dynamics simulations in aqueous-phase, was validated by the plotting of Ramachandran diagrams for the averaged structures and by the analysis of i and i + 4 helical hydrogen bonding between the amino acid residues. The results of the simulation of the calcium channel model with one and two Ca2+ ions at the binding site are in accordance with mutation studies which suggest that the EEEE locus in the L-type calcium channel must form a single high-affinity binding site. These results suggest that the Ca2+ permeation through the channel would be derived from competition between two ions for the only high-affinity binding site. Furthermore, the experimentally observed blocking of the Na+ flux at micromolar Ca2+ concentrations, probably due to the occupancy of the single high-affinity binding site for one Ca2+, was also reproduced by our model.     

Simulations of calcium channel block by trivalent cations: Gd competes with permeant ions for the selectivity filter

Current through L-type calcium channels (Ca_V1.2 or dihydropyridine receptor) can be blocked by micromolar concentrations of trivalent cations like the lanthanide gadolinium (Gd³⁺). It has been proposed that trivalent block is due to ions competing for a binding site in both the open and closed configuration, but possibly with different trivalent affinities. Here, we corroborate this general view of trivalent block by computing conductance of a model L-type calcium channel. The model qualitatively reproduces the Gd³⁺ concentration dependence and the effect that substantially more Gd³⁺ is required to produce similar block in the presence of Sr²⁺ (compared to Ba²⁺) and even more in the presence of Ca²⁺. Trivalent block is explained in this model by cations binding in the selectivity filter with the charge/space competition mechanism. This is the same mechanism that in the model channel governs other selectivity properties. Specifically, selectivity is determined by the combination of ions that most effectively screen the negative glutamates of the protein while finding space in the midst of the closely packed carboxylate groups of the glutamate residues.     

Calcium binding of troponin C. I. A potentiometric titration study.

Structural changes of troponin C on calcium binding were studied by hydrogen ion titration, circular dichroism, and fluorescence measurements. The potentiometric titration curves in the carboxyl region are shifted towards lower pH with calcium binding. The intrinsic pK of the carboxyl groups at the calcium binding sites decreases by 0.8 pK unit on calcium binding; on the other hand, magnesium ions have little effect on the intrinsic pK of the carboxyl groups. The intrinsic pK of the imidazole group is not affected by calcium binding. The value of w, an electrostatic interaction factor, is identical for calcium-free and calcium-bound troponin C and is about half of the value calculated assuming a compact sphere. The results of difference titration on the calcium binding indicate that the pH of troponin C solution increases on addition of CaCl2 up to 2 mol of Ca2+ per mol of troponin C and then decreases on further addition of CaCl2. The pH increase is depressed in the presence of MgCl2, in the low pH region, or at high ionic strength. The pH increase is also observed on addition of MgCl2. The ellipticity at 222 nm was measured under the same conditions as the difference titration measurements, and the relation between the pH change and the conformational change of troponin C on calcium binding is discussed based on the results obtained. The number of calcium binding sites and the binding constants estimated by analysis of these difference titration curves were in agreement with the results of Potter and Gergely (22). No magnesium binding site was observed. The tyrosine fluorescence measurements indicated that the binding site near tyrosine-109 is one of the high affinity sites.     

Affinity and stoichiometry of calcium binding by arsenazo III

Arsenazo III forms a 1:1 complex with calcium. The affinity constant of arsenazo III for calcium (pK_Ca) has been determined by titrating purified arsenazo III with standard calcium solutions. The method of evaluation used allows one to determine correct pK_Ca values even in the presence of micromolar amounts of contaminating calcium. The pK_Ca is influenced by the following factors: (a) in the neutral pH range the apparent pK_Ca increases strongly with pH; (b) alkali ions bind weakly to arsenazo III and millimolar concentrations cause a decrease in the apparent pK_Ca; (c) the magnesium affinity of arsenazo III, although much lower than the calcium affinity, increases strongly with pH in the neutral range (at pH 7.0 the calcium affinity of arsenazo III is not appreciably altered by up to 2 mm magnesium); (d) strontium and barium form weaker complexes with arsenazo III than calcium, but much stronger complexes than magnesium; (e) the apparent pK_Ca decreases with increasing buffer concentration in the millimolar range. The pK_Ca of arsenazo III is so high that, unless the arsenazo III concentration greatly exceeds the calcium concentration, a considerable fraction of the total arsenazo III is in the calcium complexed form. Because of this, arsenazo III responds nonlinearly to all but the lowest calcium concentrations; however, quantitation of the calcium concentration can readily be done from the mass action law provided that the pK_Ca is determined under the actual experimental conditions. Arsenazo III is a reliable calcium indicator if the experimental conditions, particularly pH, are well controlled.     

A synthetic 33-residue analogue of bovine brain calmodulin calcium binding site III: synthesis, purification, and calcium binding

The sequential solid-phase synthesis of a peptide analogue of bovine brain calmodulin calcium binding site III covering residues 81-113 of the natural sequence is described. Methionine-109 is replaced by a leucine residue to avoid complications in the synthesis and purification. In an attempt to relate the structure of the calcium binding sites in the naturally occurring calcium binding protein to the calcium affinity of these sites, the synthetic analogue is examined for calcium binding by circular dichroism spectroscopy. The calcium binding characteristics are compared to those of a synthetic analogue of the homologous calcium binding site III in rabbit skeletal troponin C. The Kd of the calmodulin site III fragment for Ca2+ is determined as 878 microM whereas the Kd of the troponin C fragment is 30 times smaller at 28 microM. Structural changes induced in the peptides by Ca2+ and trifluoroethanol are similar. This study supports our contention that the single synthetic calcium binding site is a reasonable model for the study of the structure-activity relationships of the calcium binding sites in calcium-regulated proteins such as calmodulin and troponin C.     

The calcium sensitizer drug MCI-154 binds the structural C-terminal domain of cardiac troponin C

The compound MCI-154 was previously shown to increase the calcium sensitivity of cardiac muscle contraction. Using solution NMR spectroscopy, we demonstrate that MCI-154 interacts with the calcium-sensing subunit of the cardiac troponin complex, cardiac troponin C (cTnC). Surprisingly, however, it binds only to the structural C-terminal domain of cTnC (cCTnC), and not to the regulatory N-terminal domain (cNTnC) that determines the calcium sensitivity of cardiac muscle.Physiologically, cTnC is always bound to cardiac troponin I (cTnI), so we examined its interaction with MCI-154 in the presence of two soluble constructs, cTnI_1–77 and cTnI_135–209, which contain all of the segments of cTnI known to interact with cTnC. Neither the cTnC-cTnI_1–77 complex nor the cTnC-cTnI_135–209 complex binds to MCI-154. Since residues 39–60 of cTnI are known to bind tightly to the cCTnC domain to form a structured core that is invariant throughout the cardiac cycle, we conclude that MCI-154 does not bind to cTnC when it is part of the intact cardiac troponin complex. Thus, MCI-154 likely exerts its calcium sensitizing effect by interacting with a target other than cardiac troponin.     

Calcium and cadmium binding to troponin C. Evidence for cooperativity

Proton NMR is used to compare the structural changes induced in bovine cardiac troponin C on binding of cadmium and calcium ions. The same spectral changes are observed for both ion species. The rate of the conformational changes associated with cadmium binding to the two high-affinity sites is slow, that associated with cadmium ions binding to the low-affinity site is high. 113Cd-NMR spectra of cardiac troponin C feature two signals interpreted as due to cadmium ions bound to the strong sites. Strong arguments are given in favour of cooperativity in binding of the first two cadmium or calcium ions to cardiac and skeletal muscle troponin C.     

Rapid kinetic studies of calmodulin interactions with calcium and troponin I as monitored by anthroylcholine fluorescence

Anthroylcholine was utilized as an extrinsic fluorescent probe in rapid kinetic studies of calcium dissociation from calmodulin (k_off = 10 S^?1) and the calmodulin-troponin I complex (k_off = 6 S^?1). At concentrations lower than 70 μM, the mechanism of dye binding agreed with the simple kinetic scheme in which the dye binds exclusively to the respective calcium complexes of calmodulin and calmodulin-troponin I. The sensitivity of anthroylcholine also made possible the estimation of values for the association (1.0 ± 0.8) × 10⁸$\text{M}{}^{\mathrm{?1}}$ S^?1) and dissociation rate constants (2 ± 170 S^?1) for troponin I binding to the calcium₄-calmodulin complex.     

The predicted structure of the calcium-binding component of troponin.

The structure prediction of the calcium binding component of troponin (TN-C) incorporates the following assumptions: (1) TN-C contains four regions homologous to the calcium binding "EF hand" of parvalbumin. (2) The four EF hands are arranged in two pairs with overall symmetry, 222. (3) The regions of the calcium binding component of troponin which are not in the four EF hands connect the hands within each pair, one to two and three to four, and connect the pairs, region two to region three. In the resulting model there is a well-defined hydrophobic core made from side chains of all eight helical regions and of the four calcium binding loops. The Ca2+ within pairs are separated by 11 A; while the pairs of Ca2+ are separated from one another by over 30 A. Cys-98 and Tyr-109 are suggested to be sensitive spectroscopic probes. Calcium(1) is suggested to be solvent accessible and most readily replaced by a lanthanide. Because of the overall symmetry of the calcium binding component of troponin, one can anticipate that the inhibitory- and the tropomyosin binding components of troponin are similar to one another.     

Exocytosis reconstituted from the sea urchin egg is unaffected by calcium pretreatment of granules and plasma membrane

Micromolar calcium ion concentrations stimulate exocytosis in a reconstituted system made by recombining in the plasma membrane and cortical secretory granules of the sea urchin egg. The isolated cortical granules are unaffected by calcium concentrations up to 1 mM, nor do granule aggregates undergo any mutual fusion at this concentration. Both isolated plasma membrane and cortical granules can be pretreated with 1 mM Ca before reconstitution without affecting the subsequent exocytosis of the reconstituted system in response to micromolar calcium concentrations. On reconstitution, aggregated cortical granules will fuse with one another in response to micromolar calcium provided that one of their number is in contact with the plasma membrane. If exocytosis involves the generation of lipid fusogens, then these results suggest that the calcium-stimulated production of a fusogen can occur only when contiguity exists between cortical granules and plasma membrane. They also suggest that a substance involved in exocytosis can diffuse and cause piggy-back fusion of secretory granules that are in contact with the plasma membrane. Our results are also consistent with a scheme in which calcium ions cause a reversible, allosteric activation of an exocytotic protein.     

Channel formation in model membranes by the adenylate cyclase toxin of Bordetella pertussis: effect of calcium

Calmodulin-dependent adenylate cyclase toxin (ACT or CyaA) of Bordetella pertussis requires calcium ions for target cell binding, formation of hemolytic channels, and delivery of its enzyme component into cells. We examined the effect of calcium and calmodulin on toxin interaction with planar lipid bilayers. While calmodulin binding did not affect the properties of CyaA channels, addition of calcium ions and toxin to the same side of the membrane caused a steep increase of the channel-forming capacity of CyaA. The calcium effect was highly specific, since among other divalent cations only strontium caused some CyaA activity enhancement. The minimal stimulatory concentration of calcium ions ranged from 0.6 to 0.8 mM, depending on the ionic strength of the aqueous phase. Half-maximal channel activity of CyaA was observed at 2-4 mM, and saturation was reached at 10 mM calcium concentration, respectively. The unit size of single CyaA channels, assessed as single-channel conductance, was not affected by calcium ions, while the frequency of CyaA channel formation strongly depended on calcium concentration. The calcium effect was abrogated upon deletion of the RTX repeats of the toxin, suggesting that binding of calcium ions to the repeats modulates the propensity of CyaA to form membrane channels.     

Interaction of calcium ions with peptide hormones of the gastrin family

The interactions of Des-Trp¹-Nle¹²-minigastrin I (Nle¹¹-HG-13) and Nle¹⁵-little gastrin I (Nle¹⁵-HG-17) with calcium ions have been investigated in water and in trifluoroethanol solution using uv and CD absorption techniques. Both hormones strongly interact with Ca²⁺ in the organic medium. In the case of Nle¹¹-HG-13, the near-uv chiroptical properties (dominated by the transitions of the Trp residue in the C-terminal tetrapeptide sequence) indicate that three metal ions per mole of hormone are involved in the binding process. From the different response of near-uv and far-uv CD properties to the addition of calcium and from the change of the CD spectra in the aromatic absorption region, it is concluded that the biologically important C-terminal sequence is directly involved in the interaction with calcium. Elongation of the peptide chain from Nle¹¹-HG-13 to Nle¹⁵-HG-17 (Nle¹⁵-little gastrin I) does not provide any additional binding site for calcium ions. The change of the CD properties in the near- and far-uv indicates that three metal ions per mole of hormone are involved in the binding process. The dichroic absorption in the aromatic region indicates that only one of the two Trp residues of the little gastrin analog is sensitive to the presence of calcium. On the assumption that the variation of the CD properties is proportional to the extent of calcium binding, the binding constants K₁, K₂, and K₃ have been estimated roughly. Two similar sets of binding constants have been found, with K₁ ≥ 10⁶M^?1 and K₃ of the order of 10⁵M^?1, indicating similar binding sites in the two hormones with high affinity for calcium ions.     

The interaction of calcium with gangliosides in bilayer membranes

We studied the binding of calcium to bilayer membranes formed from mixtures of phosphatidylcholine and mono-, di-, or trisialoganglioside by measuring its effect on the electrophoretic mobility of multilamellar vesicles and the conductance of planar bilayers. In 0.001 M monovalent salt solutions the surface potential of the membranes is large and micromolar concentrations of calcium have a significant effect on the mobility and conductance. In 0.1 M monovalent salt solutions the surface potential is small and millimolar concentrations of calcium are required to affect these parameters. The strong apparent binding of calcium we observed at low ionic strength could be due to the nonspecific accumulation of calcium in the electrical diffuse double layer. To distinguish between this nonspecific effect and binding of calcium to the membrane, we substituted dimethonium for calcium. Dimethonium is a divalent cation that screens negative charges but does not bind to lipids. We also examined the effect of replacing phosphatidylcholine by monoolein: calcium binds to phosphatidylcholine but not to monoolein. We describe our electrophoretic mobility results by combining the Poisson-Boltzmann and Navier-Stokes equations with the Langmuir adsorption isotherm. We conclude that calcium binds weakly to gangliosides with an intrinsic association constant of less than 100 M-1, which is similar to the association constant of calcium with phospholipids.     

An investigation on calcium taurodeoxycholate micellar aggregates

Abstract

The formation of micellar aggregates in the presence of calcium(II) ions in solutions containing sodium and taurodeoxycholate ions and their composition at 25°C and in 0.5 mol dm^?3 N(CH₃)₄Cl as constant ionic medium was studied. The study was carried out by means of two different procedures. In the first one, solid calcium oxalate was equilibrated with taurodeoxycholate, sodium and hydrogen ions and the free concentration of sodium and hydrogen ions was determined. After filtration, the calcium(II) (by atomic absorption spectrophotometry) and oxalate concentration were also determined. In the second approach, hydrogen and sodium ions free concentrations were obtained by electromotive force measurements carried out in solutions containing taurodeoxycholate. The results of both procedures could be explained by assuming the presence of aggregates of different composition with the participation of sodium, calcium(II) and taurodeoxycholate ions, depending on the concentration of the reagents. Protonated species were even present in appreciable concentrations. All the found species have taurodeoxycholate aggregation numbers in multiples of three. A mechanism for the micellar aggregates containing calcium and sodium is proposed. Sodium taurodeoxycholate in the presence of calcium(II) forms larger aggregates than does taurocholate in the presence of calcium(II); the building block of the former is a trimer whereas the latter system has lower aggregation numbers and its building block is a dimer or an octamer.     

High-Affinity Cannabinoid Binding Site: Regulation by Ions, Ascorbic Acid, and Nucleotides

The high-affinity cannabinoid site in rat brain is an integral component of brain membranes that recognizes cannabinoids with inhibitory constants (Ki) in the nanomolar range. To clarify its physiological role, we studied the regulation of [3H]5'-trimethylammonium delta 8-tetrahydrocannabinol ([3H]TMA) binding. The site is inhibited by heavy metal ions, such as La3+, at low micromolar concentrations; divalent cations, such as Ca2+ and Mg2+, inhibit [3H]TMA binding, though at somewhat higher concentrations. In contrast, [3H]TMA binding is stimulated by Fe2+, Cu2+, and Hg2+ ions. Ascorbic acid and its analogs are also stimulators of cannabinoid binding at low micromolar concentrations. Stimulation of [3H]TMA binding by ascorbate or ions is dependent upon molecular oxygen, but is not inhibited by metabolic poisons. Metabolically stable nucleoside triphosphate analogs enhance [3H]TMA binding by different mechanisms, with hydrolysis of a high-energy phosphate bond apparently requisite for these influences. These results suggest that the cannabinoid binding site is associated with a nucleotide-utilizing protein possessing multiple regulatory subsites.     

In vitro promotion by auxins of divalent ion release from soybean membranes

Release of divalent ions from membrane pellets of soybean hypocotyls was promoted by the natural auxin, indole-3-acetic acid, and the synthetic auxin, 2,4-dichlorophenoxyacetic acid. The calcium release occurred at auxin concentrations as low as 1 nanomolar, and maximum release was observed at 1 micromolar. Hormone concentrations greater than 1 micromolar showed reduced effectiveness in releasing membrane-associated calcium. 2,3-Dichlorophenoxyacetic acid, a weak-auxin analog of 2,4-dichlorophenoxyacetic acid, did not promote calcium release. In some experiments, the analog actually promoted calcium association with the membranes. Red blood cells treated in a similar manner to soybean hypocotyl membranes did not release calcium in response to indole-3-acetic acid. The release phenomenon was hormone specific but not ion specific. Auxin released manganese from membranes in a manner similar to that of calcium. The calcium release, following auxin treatment, is accompanied by a decrease in membrane-associated sites for calcium binding.