Spectral studies of the Ca2+-dependent interaction of trifluoperazine with S100b

S100b is a calcium-binding protein that will bind to many calmodulin target molecules in a Ca²⁺-dependent manner. In order to study the Ca²⁺-dependent binding properties of S100b, its interaction with a calmodulin antagonist, trifluoperazine (TFP), was investigated using [¹⁹F]- and [¹H]-NMR and UV-difference spectroscopy. It was estimated from [¹⁹F]-NMR that in the absence of Ca²⁺, thek _1/2 value of TFP was 130 µM, while itsk _1/2 value decreased to 28 µM in the presence of Ca²⁺. The addition of KCl was not antagonistic to the Ca²⁺-dependent interaction of TFP to S100b. The chemical exchange rate of TFP with Ca²⁺-bound S100b was estimated to be 9×10² sec^–1. By comparison with TFP-calmodulin exchange rates, it is suggested that the TFP-binding site on S100b is structurally different from its binding sites on calmodulin. Proton NMR resonance broadening in the range 6.8–7.2 ppm, corresponding to phenylalanine nuclei of S100b, indicates that these residues may be involved in TFP binding. Addition of Ca²⁺ to a 1:1 mixture of S100b and TFP resulted in a red-shifted UV-difference spectrum, while no significant difference spectrum was detected when Mg²⁺ was added to a S100b-TFP solution. Thus, we suggest that Ca²⁺ induces the exposure of a hydrophobic domain on S100b containing one or more phenylalanine residues that will bind TFP but that this domain is different from the hydrophobic domain on calmodulin.     

Investigation of the Ca2+-dependent interaction of trifluoperazine with S100a: A19F NMR and circular dichroism study

S100a is a heterodimeric, acidic calcium-binding protein that interacts with calmodulin antagonists in a Ca²⁺-dependent manner. In order to study the behavior of the hydrophobic domain on S100a when bound to Ca²⁺, its interaction with trifluoperazine (TFP) was investigated using¹⁶F nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. The dissociation constant (K _d) values of TFP, as estimated from the chemical shifts of¹⁹F NMR, were 191 and 29 μm in the absence and presence of Ca²⁺, respectively, and were similar to those previously reported for S100b. However, the TFP linewidth in the presence of Ca²⁺-bound S100a was 65 Hz greater than in the presence of Ca²⁺-bound S100b. This suggests a slower TFP exchange rate for S100a than for S100b. Thus, the TFP linewidths observed for each isoform may reflect differences in structural and modulatory properties of the Ca²⁺-dependent hydrophobic domains on S100a and S100b. Additionally, the presence of magnesium had no effect on the observed Ca²⁺-induced TFP spectral changes in S100a solutions. Circular dichroism studies indicate that Ca²⁺ induces a small transition from α-helix to random coil in S100a; in contrast, the opposite transition is reported for calmodulin (Hennesseyet al., 1987). However, TFP did not significantly alter the secondary structure of Ca²⁺-bound S100a; this observation is similar to the effect of TFP on Ca²⁺-bound calmodulin and troponin C (Shimizu and Hatano, 1984; Gariépy and Hodges, 1983). It is, therefore, proposed that TFP binds to a hydrophobic domain on S100a in a fashion similar to other calcium-modulated proteins.     

Investigation of the Ca2+-dependent interaction of trifluoperazine with S100a: A19F NMR and circular dichroism study

S100a is a heterodimeric, acidic calcium-binding protein that interacts with calmodulin antagonists in a Ca²⁺-dependent manner. In order to study the behavior of the hydrophobic domain on S100a when bound to Ca²⁺, its interaction with trifluoperazine (TFP) was investigated using¹⁶F nuclear magnetic resonance (NMR) and circular dichroism (CD) spectroscopy. The dissociation constant (K _d) values of TFP, as estimated from the chemical shifts of¹⁹F NMR, were 191 and 29 m in the absence and presence of Ca²⁺, respectively, and were similar to those previously reported for S100b. However, the TFP linewidth in the presence of Ca²⁺-bound S100a was 65 Hz greater than in the presence of Ca²⁺-bound S100b. This suggests a slower TFP exchange rate for S100a than for S100b. Thus, the TFP linewidths observed for each isoform may reflect differences in structural and modulatory properties of the Ca²⁺-dependent hydrophobic domains on S100a and S100b. Additionally, the presence of magnesium had no effect on the observed Ca²⁺-induced TFP spectral changes in S100a solutions. Circular dichroism studies indicate that Ca²⁺ induces a small transition from -helix to random coil in S100a; in contrast, the opposite transition is reported for calmodulin (Hennesseyet al., 1987). However, TFP did not significantly alter the secondary structure of Ca²⁺-bound S100a; this observation is similar to the effect of TFP on Ca²⁺-bound calmodulin and troponin C (Shimizu and Hatano, 1984; Gariépy and Hodges, 1983). It is, therefore, proposed that TFP binds to a hydrophobic domain on S100a in a fashion similar to other calcium-modulated proteins.     

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

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

Trifluoperazine enhancement of Ca2+-dependent inactivation of L-type Ca2+ currents inHelix aspersa neurons

The effects of trifluoperazine hydrochloride (TFP), a calmodulin antagonist, on L-type Ca²⁺ currents (L-type ICa²⁺) and their Ca²⁺-dependent inactivation, were studied in identifiedHelix aspersa neurons, using two microelectrode voltage clamp. Changes in [Ca²⁺]_i were measured in unclamped fura-2 loaded neurons. Bath applied TFP produced a reversible and dose-dependent reduction in amplitude of L-type ICa²⁺ (IC₅₀=28 μM). Using a double-pulse protocol, we found that TFP enhances the efficacy of Ca²⁺-dependent inactivation of L-type ICa²⁺. Trifluoperazine sulfoxide (50 μM), a TFP derivative with low calmodulin-antagonist activity, did not have any effects on either amplitude or inactivation of L-type ICa²⁺. TFP (20 μM) increased basal [Ca²⁺]_i from 147±37 nM to 650±40nM (N=7). The increase in [Ca²⁺]_i was prevented by removal of external Ca²⁺ and curtailed by depletion of caffeine-sensitive intracellular Ca²⁺ stores. Since TFP may also block protein kinase C (PKC), we tested the effect of a PKC activator (12-O-tetradecanoyl-phorbol-13-acetate) on L-type Ca²⁺ currents. This compound produced an increase in L-type ICa²⁺ without enhancing Ca²⁺-dependent inactivation. The results show that 1) TFP reduces L-type ICa²⁺ while enhancing the efficacy of Ca²⁺-dependent inactivation. 2) TFP produces an increase in basal [Ca²⁺]_i which may contribute to the enhancement of Ca²⁺-dependent inactivation. 3) PKC up-regulates L-type ICa²⁺ without altering the efficacy of Ca²⁺ dependent inactivation. 4) The TFP effects cannot be attributed to its action as PKC blocker.     

Structural Basis of Ribosomal S6 Kinase 1 (RSK1) Inhibition by S100B Protein: MODULATION OF THE EXTRACELLULAR SIGNAL-REGULATED KINASE (ERK) SIGNALING CASCADE IN A CALCIUM-DEPENDENT WAY*?

Mitogen-activated protein kinases (MAPK) promote MAPK-activated protein kinase activation. In the MAPK pathway responsible for cell growth, ERK2 initiates the first phosphorylation event on RSK1, which is inhibited by Ca²⁺-binding S100 proteins in malignant melanomas. Here, we present a detailed in vitro biochemical and structural characterization of the S100B-RSK1 interaction. The Ca²⁺-dependent binding of S100B to the calcium/calmodulin-dependent protein kinase (CaMK)-type domain of RSK1 is reminiscent of the better known binding of calmodulin to CaMKII. Although S100B-RSK1 and the calmodulin-CAMKII system are clearly distinct functionally, they demonstrate how unrelated intracellular Ca²⁺-binding proteins could influence the activity of the CaMK domain-containing protein kinases. Our crystallographic, small angle x-ray scattering, and NMR analysis revealed that S100B forms a “fuzzy” complex with RSK1 peptide ligands. Based on fast-kinetics experiments, we conclude that the binding involves both conformation selection and induced fit steps. Knowledge of the structural basis of this interaction could facilitate therapeutic targeting of melanomas.     

Allosteric effects of the antipsychotic drug trifluoperazine on the energetics of calcium binding by calmodulin

Trifluoperazine (TFP; Stelazine?) is an antagonist of calmodulin (CaM), an essential regulator of calcium‐dependent signal transduction. Reports differ regarding whether, or where, TFP binds to apo CaM. Three crystallographic structures (1CTR, 1A29, and 1LIN) show TFP bound to (Ca²⁺)₄‐CaM in ratios of 1, 2, or 4 TFP per CaM. In all of these, CaM domains adopt the “open” conformation seen in CaM‐kinase complexes having increased calcium affinity. Most reports suggest TFP also increases calcium affinity of CaM. To compare TFP binding to apo CaM and (Ca²⁺)₄‐CaM and explore differential effects on the N‐ and C‐domains of CaM, stoichiometric TFP titrations of CaM were monitored by ¹⁵N‐HSQC NMR. Two TFP bound to apo CaM, whereas four bound to (Ca²⁺)₄‐CaM. In both cases, the preferred site was in the C‐domain. During the titrations, biphasic responses for some resonances suggested intersite interactions. TFP‐binding sites in apo CaM appeared distinct from those in (Ca²⁺)₄‐CaM. In equilibrium calcium titrations at defined ratios of TFP:CaM, TFP reduced calcium affinity at most levels tested; this is similar to the effect of many IQ‐motifs on CaM. However, at the highest level tested, TFP raised the calcium affinity of the N‐domain of CaM. A model of conformational switching is proposed to explain how TFP can exert opposing allosteric effects on calcium affinity by binding to different sites in the “closed,” “semi‐open,” and “open” domains of CaM. In physiological processes, apo CaM, as well as (Ca²⁺)₄‐CaM, needs to be considered a potential target of drug action. Proteins 2010. © 2010 Wiley‐Liss, Inc.     

Studies on the mechanism of regulation of the red-cell Ca2+ pump by calmodulin and ATP

(1) The effects of calmodulin binding on the rates of Ca²⁺-dependent phosphorylation and dephosphorylation of the red-cell Ca²⁺ pump, have been tested in membranes stripped of endogenous calmodulin or recombined with purified calmodulin. (2) In Mg²⁺-containing media, phosphorylation and dephosphorylation rates are accelerated by a large factor (at 0°C), but the steady-state level of phosphoenzyme is unaffected by calmodulin binding (at 0°C and 37°C). In Mg²⁺-free media, slower rates of phosphoenzyme formation and hydrolysis are observed, but both rates and the steady-state phosphoenzyme level are raised following calmodulin binding. (3) At 37°C and 0°C, the rate of (Ca²⁺ + Mg²⁺)-ATPase activity is stimulated maximally by 6–7-fold, following calmodulin binding. At 37°C the apparent Ca²⁺ affinity for sustaining ATP hydrolysis is raised at least 20-fold, K_m(Ca) ? 10 μM (—calmodulin) and K_m(Ca) < 0.5 μM (+ calmodulin), but at 0°C the apparent Ca²⁺ affinity is very high in calmodulin-stripped membranes and little or no effect of calmodulin is observed (K_m(Ca) ? 3–4 · 10^-8 M). (Ca²⁺ + Mg²⁺)-ATPase activity in calmodulin activated membranes and at saturating ATP levels, is sharply inhibited by addition of calcium in the range 50–2000 μM. (4) A systematic study of the effects of the nucleotide species MgATP, CaATP and free ATP on (Ca²⁺ + Mg²⁺)-ATPase activity in calmodulin-activated membranes reveals: (a) In the 1–10 μmolar concentration range MgATP, CaATP and free ATP appear to sustain (Ca²⁺ + Mg²⁺)-ATPase activity equally effectively. (b) In the range 100–2000 μM, MgATP accelerates ATP hydrolysis (K_m(MgATP) ? 360 μM), and CaATP is an inhibitor (K_i(CaATP) ? 165 μM), probably competing with MgATP fo the regulatory site. (5) The results suggest that calmodulin binding alters the conformational state of the Ca²⁺- pump active site, producing a high (Ca²⁺ + Mg²⁺)-ATPase activity, high Ca²⁺ affinity and regulation of activity by MgATP.     

A rapid separation of bovine brain S-100a and S-100b proteins and related conformation studies

S-100 protein absorbs to the calmodulin antagonist W-7 coupled to epoxy-activated Sepharose 6B in the presence of Ca²⁺ and is eluted by ethylene glycol bis(β-aminoethyl ether)-N,N′-tetraacetic acid buffer. S-100a and S-100b were separated and isolated by Ca²⁺-dependent affinity chromatography on W-7 Sepharose. The Ca²⁺-induced conformational changes of S-100a and S-100b were examined using circular dichroism, ultraviolet difference spectra, and a fluorescence probe. Differences in Ca²⁺-dependent conformational changes between S-100a and S-100b became apparent. Circular dichroism studies revealed that both S-100a and S-100b undergo a conformational change upon binding of Ca²⁺ in the aromatic and far-uv range. In the presence or absence of Ca²⁺, the aromatic CD spectrum of S-100a differed completely from that of S-100b, possibly due to the single tryptophan residue of S-100a. Far-uv studies indicate that α-helical contents of both S-100a and S-100b decreased with addition of Ca²⁺. Ca²⁺-induced conformational changes of S-100a and S-100b were also detected by uv difference spectra. The spectrum of S-100a also differed from that of S-100b. Fluorescence studies using 2-p-toluidinylnaphthalene-6-sulfonate (TNS), a hydrophobic probe for protein, revealed a slight difference in conformational changes of these two components. The interaction of TNS and S-100b was observed with concentrations above 3 μm Ca²⁺; on the other hand, S-100a required concentrations above 8 μm. This finding was supported by the difference in the binding affinities of S-100a and S-100b to the W-7 (N-(6-aminohexyl)-5-chloro-1-naphthalenesulfonamide)-Sepharose column; both S-100a and S-100b bound the column in the presence of Ca²⁺ but S-100a was eluted prior to S-100b. These results suggest that S-100a and S-100b differ in their dependence on Ca²⁺ and that the affinity-chromatographic separation of S-100a from S-100b on the W-7-Sepharose column makes feasible a rapid purification of these two components.     

PtdIns(4,5)P2 interacts with CaM binding domains on TRPM3 N-terminus

TRPM3 has been reported to play an important role in Ca²⁺ homeostasis, but its gating mechanisms and regulation via Ca²⁺ are unknown. Ca²⁺ binding proteins such as calmodulin (CaM) could be probable modulators of this ion channel. We have shown that this protein binds to two independent domains, A35-K124 and H291-G382 on the TRPM3 N-terminus, which contain conserved hydrophobic as well as positively charged residues in specific positions, and that these residues have a crucial impact on its binding. We also showed that another Ca²⁺ binding protein, S100A1, is able to bind to these regions and that CaM and S100A1 compete for these binding sites on the TRPM3 N-terminus. Moreover, our results suggest that another very important TRP channel activity modulator, PtdIns(4,5)P₂, interacts with the CaM/S100A1 binding sites on the TRPM3 N-terminus with high affinity.     

Role of calcium and calmodulin antagonist in photosynthesis and salinity tolerance inChlorella vulgaris

To cast light upon the role of Ca¹⁺ and calmodulin on photosynthetic rate (P_n), dark respiration (R_D) and amino acid and protein contents in salinity stressed and non-stressedChlorella cultures, the Ca²⁺ chelator EGTA [ethylene glycol-bis-(2-aminoethyl ether)-N,N- tetraacetate] and the calmodulin antagonist TFP (trifluperazine) were used. TFP markedly inhibited P_N while EGTA exerted a slight, if any, effect on P_N. NaCl tolerance, on the other side, was markedly abolished by TFP that inhibited P_N and lowered rate of proline accumulation. Calmodulin might be involved in osmoregulation and salt tolerance ofChlorella. R_D, however, was markedly enhanced by EGTA and Ca²⁺-free medium and hence the Ca²⁺ deprivation increased stress severity exerted by NaCl. Combinations of Na⁺ and Ca²⁺ enhanced P_N, decreased R_D and proline content in comparison with an osmotically equivalent reference culture containing only NaCl. Addition of Ca²⁺ to TFP treated cultures failed to reactivate calmodulin for proline synthesis. However, when Ca²⁺ was added to EGTA-treated cultures, only relatively reduced proline contents were recorded.     

Calretinin Regulates Ca2+-dependent Inactivation and Facilitation of Cav2.1 Ca2+ Channels through a Direct Interaction with the α12.1 Subunit

Voltage-gated Ca_v2.1 Ca²⁺ channels undergo dual modulation by Ca²⁺, Ca²⁺-dependent inactivation (CDI), and Ca²⁺-dependent facilitation (CDF), which can influence synaptic plasticity in the nervous system. Although the molecular determinants controlling CDI and CDF have been the focus of intense research, little is known about the factors regulating these processes in neurons. Here, we show that calretinin (CR), a Ca²⁺-binding protein highly expressed in subpopulations of neurons in the brain, inhibits CDI and enhances CDF by binding directly to α₁2.1. Screening of a phage display library with CR as bait revealed a highly basic CR-binding domain (CRB) present in multiple copies in the cytoplasmic linker between domains II and III of α₁2.1. In pulldown assays, CR binding to fusion proteins containing these CRBs was largely Ca²⁺-dependent. α₁2.1 coimmunoprecipitated with CR antibodies from transfected cells and mouse cerebellum, which confirmed the existence of CR-Ca_v2.1 complexes in vitro and in vivo. In HEK293T cells, CR significantly decreased Ca_v2.1 CDI and increased CDF. CR binding to α₁2.1 was required for these effects, because they were not observed upon substitution of the II-III linker of α₁2.1 with that from the Ca_v1.2 α₁ subunit (α₁1.2), which lacks the CRBs. In addition, coexpression of a protein containing the CRBs blocked the modulatory action of CR, most likely by competing with CR for interactions with α₁2.1. Our findings highlight an unexpected role for CR in directly modulating effectors such as Ca_v2.1, which may have major consequences for Ca²⁺ signaling and neuronal excitability.     

43Ca NMR studies of Ca2+-Tetrahymena calmodulin complexes

⁴³Ca NMR spectra of Ca²⁺-Tetrahymena calmodulin(Tet. CaM.) complexes have been observed under various conditions. Off-rate of Ca²⁺ from Tet. CaM. is estimated to be approx. 2.7 × 10³ s^?1 under a certain assumption. Relaxation rates of ⁴³Ca NMR of Ca²⁺-Tet. CaM. are remarkably increased(by one order in magnitude) by adding trifluoperazine(TFP), a potent calmodulin antagonist. Relaxation parameters estimated suggest that Ca²⁺ mobility is reduced by the TFP binding. A stoichiometry of TFP is two moles per Tet. CaM. molecule. The relaxation rates of ⁴³Ca NMR signals are increased by adding excessive Mg²⁺ to the Ca²⁺-Tet. CaM. solutions. The addition of Mg²⁺ to the Ca²⁺-Tet. CaM. complex decreases apparent pKa value of the complex as well.     

Calcium Fluxes across the Plasma Membrane of Commelina communis L. Assayed in a Cell-Free System

The inside-out fraction of plasma membrane-rich vesicles prepared from leaves of Commelina communis L. by aqueous twophase partitioning was loaded with ⁴⁵Ca²⁺ through the action of the plasma membrane Ca²⁺-ATPase. While the Ca²⁺-loaded vesicles were tightly sealed, trifluoperazine (TFP) (effective concentration giving 50% of maximum effect [EC₅₀] = 70 micromolar) and W-7 (EC₅₀ = 100 micromolar), but to a much lesser extent, W-5 (EC₅₀ = 500 micromolar) led to a rapid efflux of ⁴⁵Ca²⁺ from the vesicles. This efflux could be blocked efficiently with low (<1 millimolar) concentrations of La³⁺, but it remained unaffected by the addition of calmodulin (CM). Further experiments with vesicles incubated in ⁴⁵Ca²⁺ in the absence of ATP, as well as experiments performed with control liposomes and nonloaded as well as Ca²⁺-loaded plasma membrane vesicles using the indicator dye arsenazo III showed, that TFP and W-7 and, again to a lesser extent, W-5 mobilized a pool of membrane-bound Ca²⁺ from the vesicles. No indications for a detergent effect of TFP and W-7 were obtained. The EC₅₀-values of these compounds for mobilizing membrane-associated Ca²⁺ (TFP = 100 micromolar, W-7 = 100 micromolar, W-5 = 500 micromolar) or for the triggering of Ca²⁺ release from Ca²⁺-loaded vesicles (see above) were very similar, suggesting a common basis of antagonist action on both processes. Our results suggest the presence of a Ca²⁺ channel in the plasma membrane of C. communis. The channel is obtained in a Ca²⁺-inactivated state after preparation and Ca²⁺-loading of the vesicles. The inactivation is removed by TFP or W-7, presumably due to the Ca²⁺-mobilizing effect of these compounds. The activated Ca²⁺ channel is La³⁺ sensitive and, in the cell, would allow for passage of Ca²⁺ into the cell. The possibility that TFP or W-7 act independent of CM, or through CM tightly associated with the plasma membrane, is discussed. The system described allows a cell free analysis of Ca²⁺ influx, displaying channel properties, in a higher plant.     

Calmodulin binding to platelet plasma membranes

Calmodulin copurifies with platelet plasma membranes isolated by glycerol-induced lysis and density gradient centrifugation. These membranes also bind ¹²⁵I-labeled calmodulin in vitro in the presence of Ca²⁺. Binding is largely reduced by replacing Ca²⁺ by Mg²⁺ or by addition of an excess unlabeled calmodulin. The specific component of binding is saturable, with an apparent K_d of 27 nM and a maximum of 15.9 pmol binding sites per mg of membrane protein. This is equivalent to approx. 4100 binding sites per platelet. Binding was inhibited by addition of phenothiazines, a group of calmodulin antagonists. Half-maximal inhibition was attained with approx. 20 μM trifluoperazine or 50 μM chlorpromazine. In contrast, chlorpromazine-sulfoxide which is inactive towards calmodulin, did not affect the binding. Calmodulin binding polypeptides of the plasma membrane were identified by a gel-overlay technique. A major calmodulin-binding component of molecular weight 149 000 was detected. Binding to this band was Ca²⁺-dependent and inhibited by chlorpromazine. The molecular weight of this polypeptide is similar to that of glycoprotein I and also that of the red cell (Ca²⁺ + Mg²⁺)-stimulated ATPase, which is known to bind calmodulin. The possible role of calmodulin in platelet activation is analysed.     

S100A1 and calmodulin regulation of ryanodine receptor in striated muscle

The release of Ca²⁺ ions from the sarcoplasmic reticulum through ryanodine receptor calcium release channels represents the critical step linking electrical excitation to muscular contraction in the heart and skeletal muscle (excitation–contraction coupling). Two small Ca²⁺ binding proteins, S100A1 and calmodulin, have been demonstrated to bind and regulate ryanodine receptor in vitro. This review focuses on recent work that has revealed new information about the endogenous roles of S100A1 and calmodulin in regulating skeletal muscle excitation–contraction coupling. S100A1 and calmodulin bind to an overlapping domain on the ryanodine receptor type 1 to tune the Ca²⁺ release process, and thereby regulate skeletal muscle function. We also discuss past, current and future work surrounding the regulation of ryanodine receptors by calmodulin and S100A1 in both cardiac and skeletal muscle, and the implications for excitation–contraction coupling.     

Divalent metal ion complexes of S100B in the absence and presence of pentamidine

As part of an effort to inhibit S100B, structures of pentamidine (Pnt) bound to Ca²⁺-loaded and Zn²⁺,Ca²⁺-loaded S100B were determined by X-ray crystallography at 2.15 Å (R_free = 0.266) and 1.85 Å (R_free = 0.243) resolution, respectively. These data were compared to X-ray structures solved in the absence of Pnt, including Ca²⁺-loaded S100B and Zn²⁺,Ca²⁺-loaded S100B determined here (1.88 Å; R_free = 0.267). In the presence and absence of Zn²⁺, electron density corresponding to two Pnt molecules per S100B subunit was mapped for both drug-bound structures. One Pnt binding site (site 1) was adjacent to a p53 peptide binding site on S100B (± Zn²⁺), and the second Pnt molecule was mapped to the dimer interface (site 2; ± Zn²⁺) and in a pocket near residues that define the Zn²⁺ binding site on S100B. In addition, a conformational change in S100B was observed upon the addition of Zn²⁺ to Ca²⁺-S100B, which changed the conformation and orientation of Pnt bound to sites 1 and 2 of Pnt-Zn²⁺,Ca²⁺-S100B when compared to Pnt-Ca²⁺-S100B. That Pnt can adapt to this Zn²⁺-dependent conformational change was unexpected and provides a new mode for S100B inhibition by this drug. These data will be useful for developing novel inhibitors of both Ca²⁺- and Ca²⁺,Zn²⁺-bound S100B.     

Ca2+-dependent regulation and binding of calmodulin to multiple sites of Transient Receptor Potential Melastatin 3 (TRPM3) ion channels

TRPM3 proteins assemble to Ca²⁺-permeable cation channels in the plasma membrane, which act as nociceptors of noxious heat and mediators of insulin and cytokine release. Here we show that TRPM3 channel activity is strongly dependent on intracellular Ca²⁺. Conceivably, this effect is attributed to the Ca²⁺ binding protein calmodulin, which binds to TRPM3 in a Ca²⁺-dependent manner. We identified five calmodulin binding sites within the amino terminus of TRPM3, which displayed different binding affinities in dependence of Ca²⁺. Mutations of lysine residues in calmodulin binding site 2 strongly reduced calmodulin binding and TRPM3 activity indicating the importance of this domain for TRPM3-mediated Ca²⁺ signaling. Our data show that TRPM3 channels are regulated by intracellular Ca²⁺ and provide the basis for a mechanistic understanding of the regulation of TRPM3 by calmodulin.     

Calmodulin Mediates the Ca-Dependent Regulation of Cx44 Gap Junctions

We have shown previously that the Ca²⁺-dependent inhibition of lens epithelial cell-to-cell communication is mediated in part by the direct association of calmodulin (CaM) with connexin43 (Cx43), the major connexin in these cells. We now show that elevation of [Ca²⁺]_i in HeLa cells transfected with the lens fiber cell gap junction protein sheep Cx44 also results in the inhibition of cell-to-cell dye transfer. A peptide comprising the putative CaM binding domain (aa 129-150) of the intracellular loop region of this connexin exhibited a high affinity, stoichiometric interaction with Ca²⁺-CaM. NMR studies indicate that the binding of Cx44 peptide to CaM reflects a classical embracing mode of interaction. The interaction is an exothermic event that is both enthalpically and entropically driven in which electrostatic interactions play an important role. The binding of the Cx44 peptide to CaM increases the CaM intradomain cooperativity and enhances the Ca²⁺-binding affinities of the C-domain of CaM more than twofold by slowing the rate of Ca²⁺ release from the complex. Our data suggest a common mechanism by which the Ca²⁺-dependent inhibition of the α-class of gap junction proteins is mediated by the direct association of an intracellular loop region of these proteins with Ca²⁺-CaM.     

Decalmodulation of Cav1 channels by CaBPs

Ca²⁺-dependent inactivation (CDI) is a negative feedback regulation of voltage-gated Ca_v1 and Ca_v2 channels that is mediated by the Ca²⁺ sensing protein, calmodulin (CaM), binding to the pore-forming Ca_v α₁ subunit. David Yue and his colleagues made seminal contributions to our understanding of this process, as well as factors that regulate CDI. Important in this regard are members of a family of Ca²⁺ binding proteins (CaBPs) that are related to calmodulin. CaBPs are expressed mainly in neural tissues and can antagonize CaM-dependent CDI for Ca_v1 L-type channels. This review will focus on the roles of CaBPs as Ca_v1-interacting proteins, and the significance of these interactions for vision, hearing, and neuronal Ca²⁺ signaling events.