Ca2+-dependent potentiation of the nonselective cation channel TRPV4 is mediated by a C-terminal calmodulin binding site

Most Ca2+-permeable ion channels are inhibited by increases in the intracellular Ca2+ concentration ([Ca2+]i), thus preventing potentially deleterious rises in [Ca2+]i. In this study, we demonstrate that currents through the osmo-, heat- and phorbol ester-sensitive, Ca2+-permeable nonselective cation channel TRPV4 are potentiated by intracellular Ca2+. Spontaneous TRPV4 currents and currents stimulated by hypotonic solutions or phorbol esters were reduced strongly at all potentials in the absence of extracellular Ca2+. The other permeant divalent cations Ba2+ and Sr2+ were less effective than Ca2+ in supporting channel activity. An intracellular site of Ca2+ action was supported by the parallel decrease in spontaneous currents and [Ca2+]i on removal of extracellular Ca2+ and the ability of Ca2+ release from intracellular stores to restore TRPV4 activity in the absence of extracellular Ca2+. During TRPV4 activation by hypotonic solutions or phorbol esters, Ca2+ entry through the channel increased the rate and extent of channel activation. Currents were also potentiated by ionomycin in the presence of extracellular Ca2+. Ca2+-dependent potentiation of TRPV4 was often followed by inhibition. By mutagenesis, we localized the structural determinant of Ca2+-dependent potentiation to an intracellular, C-terminal calmodulin binding domain. This domain binds calmodulin in a Ca2+-dependent manner. TRPV4 mutants that did not bind calmodulin lacked Ca2+-dependent potentiation. We conclude that TRPV4 activity is tightly controlled by intracellular Ca2+. Ca2+ entry increases both the rate and extent of channel activation by a calmodulin-dependent mechanism. Excessive increases in [Ca2+]i via TRPV4 are prevented by a Ca2+-dependent negative feedback mechanism.     

In vivo Paramecium mutants show that calmodulin orchestrates membrane responses to stimuli.

Paramecium generates a Ca2+ action potential and can be considered a one-cell animal. Rises in internal [Ca2+] open membrane channels that specifically pass K+, or Na+. Mutational and patch-clamp studies showed that these channels, like enzymes, are activated by Ca(2+)-calmodulin. Viable CaM mutants of Paramecium have altered transmembrane currents and easily recognizable eccentricities in their swimming behavior, i.e. in their responses to ionic, chemical, heat, or touch stimuli. Their CaMs have amino-acid substitutions in either C- or N-terminal lobes but not the central helix. Surprisingly, these mutations naturally fall into two classes: C-lobe mutants (S101F, I136T, M145V) have little or no Ca(2+)-dependent K+ currents and thus over-react to stimuli. N-lobe mutants (E54K, G40E+D50N, V35I+D50N) have little or no Ca(2+)-dependent Na+ current and thus under-react to certain stimuli. Each mutation also has pleiotropic effects on other ion currents. These results suggest a bipartite separation of CaM functions, a separation consistent with the recent studies of Ca(2+)-ATPase by Kosk-Kosicka et al. [41, 55]. It appears that a major function of Ca(2+)-calmodulin in vivo is to orchestrate enzymes and channels, at or near the plasma membrane. The orchestrated actions of these effectors are not for vegetative growth at steady state but for transient responses to stimuli epitomized by those of electrically excitable cells.     

Calcineurin,a Type 2B Protein Phosphatase,Modulates the Ca2+-Permeable Slow Vacuolar Ion Channel of Stomatal Guard Cells

The slowly activating vacuolar (SV) channel of plant vacuoles is gated open by cytosolic free Ca2+ and by cytosol-positive potentials. Using vacuoles isolated from broad bean guard cell protoplasts, SV-mediated currents could be measured in the whole-vacuole configuration of a patch clamp as the time-dependent increase in current at cytosol-positive voltages. Time-dependent deactivation of the SV currents when changing from activating to nonactivating voltages (tail currents) was used to calculate the selectivity of the channel to Ca2+ and Cl- with respect to K+. Changing the equilibrium potential for each permeant ion (Ca2+, Cl-, and K+) at least once for individual vacuoles allowed the relative permeabilities (P) of each of these ions to be calculated in a single experiment. The resulting Pca:Pcl:Pk ratio was close to 3:0.1:1. In accord with its characterization as a weakly selective Ca2+ channel, the SV-mediated current density decreased with increasing Ca2+ activity in the vacuole lumen. SV currents were potently modulated by the Ca2+-dependent, calmodulin-stimulated protein phosphatase 2B (calcineurin). At low concentrations ([less than or equal to]0.4 units per mL), calcineurin stimulated SV currents by ~60%, whereas at higher concentrations the phosphatase was inhibitory, reaching ~90% inhibition at 3 units per mL. Bovine calmodulin had no direct effect on SV-mediated currents, although calcineurin stimulated by exogenous calmodulin inhibited SV currents at all concentrations tested with half-maximal inhibition for calcineurin at 0.16 units per mL. The inhibitory effect of calcineurin could be blocked by the pyrethroid deltamethrin, indicating inhibition of SV channels by calcineurin via dephosphorylation. A model is discussed in which vacuolar Ca2+ release through SV channels is subject to both positive feedforward and negative feedback control through cytosolic Ca2+ and dephosphorylation, respectively.     

Ca2(+)-dependent regulation of the spectrin/actin interaction by calmodulin and protein 4.1

The Ca2(+)-dependent regulation of the erythroid membrane cytoskeleton was investigated. The low-salt extract of erythroid membranes, which is mainly composed of spectrin, protein 4.1, and actin, confers a Ca2+ sensitivity on its interaction with F-actin. This Ca2+ sensitivity is fortified by calmodulin and antagonized by trifluoperazine, a potent calmodulin inhibitor. Additionally, calmodulin is detected in the low-salt extract. These results suggest that calmodulin is the sole Ca2(+)-sensitive factor in the low-salt extract. The main target of calmodulin in the erythroid membrane cytoskeleton was further examined. Under native conditions, calmodulin forms a stable and equivalent complex with protein 4.1 as determined by calmodulin affinity chromatography, cross-linking experiments, and fluorescence binding assays with an apparent Kd of 5.5 x 10(-7) M irrespective of the free Ca2+ concentration. Domain mapping with chymotryptic digestion reveals that the calmodulin-binding site resides within the N-terminal 30-kDa fragment of protein 4.1. In contrast, the interaction of calmodulin with spectrin is unexpectedly weak (Kd = 1.2 x 10(-4) M). Given the content of calmodulin in erythrocytes (2-5 microM), these results imply that the major target for calmodulin in the erythroid membrane cytoskeleton is protein 4.1. Low- and high-shear viscometry and binding assays reveal that an equivalent complex of calmodulin with protein 4.1 regulates the spectrin/actin interaction in a Ca2(+)-dependent manner. At a low Ca2+ concentration, protein 4.1 potentiates the actin cross-linking and the actin binding activities of spectrin. At a high Ca2+ concentration, the protein 4.1-potentiated actin cross-linking activity but not the actin binding activity of spectrin is suppressed by Ca2+/calmodulin. The Ca2(+)-dependent regulation of the spectrin/protein 4.1/calmodulin/actin interaction is discussed.     

A long-lasting potentiation of calmodulin-mediated chloride channel activity without a mediation of protein kinase C in Xenopus oocytes injected with rat brain mRNA.

When Xenopus oocytes injected with rat brain poly(A)+RNA were voltage-clamped in a recording solution containing Ca2+, a depolarization pulse induced a transient current, ICl(Ca), which reflects calmodulin-mediated opening of endogenous Cl- channels in response to a Ca2+ influx through Ca2+ channels of brain origin. ICl(Ca) could be repetitively observed with a steady amplitude over 1 h, whereas the response was greatly potentiated for more than 30 min after a brief stimulation of muscarinic or other Ca2(+)-mobilizing receptors. The enhancement of ICl(Ca) was mimicked by an injection of inositol-1,4,5-trisphosphate or by a treatment with A23187, but not affected by treatments that stimulate or inhibit protein kinase C activity. Isolated Ba2+ current flowing through voltage-sensitive Ca2+ channels was not augmented during the facilitation of ICl(Ca). These observations indicate that the endogenous calmodulin/Cl- channel system may memorize an over-threshold increase in the intracellular Ca2+ concentration and potentiate the Ca2(+)-sensitiveness of the Cl- channel. A long-lasting autoregulation of Ca2(+)-dependent ion channel activity is suggested.     

A calmodulin dependent Ca2+-activated K+ channel in the adipocyte plasma membrane

Increased membrane permeability (conductance) that is specific for K+ and directly activated by Ca2+ ions, has been identified in isolated adipocyte plasma membranes using the K+ analogue, 86Rb+. Activation of these K+ conductance pathways (channels) by free Ca2+ was concentration dependent with a half-maximal effect occurring at 32 +/- 4 nM free Ca2+ (n = 7). Addition of calmodulin further enhanced the Ca2+ activating effect on 86Rb+ uptake (K+ channel activity). Ca2+-dependent 86Rb+ uptake was inhibited by tetraethylammonium ion and low pH. It is concluded that the adipocyte plasma membrane possesses K+ channels that are activated by Ca2+ and amplified by calmodulin.     

New Mutants of Paramecium Tetraurelia Defective in a Calcium Control Mechanism: Genetic and Behavioral Characterizations

The k-shy mutants of Paramecium tetraurelia are altered in several Ca2+-dependent functions which regulate ciliary motility. The isolation, genetics, and phenotypes of these mutants are described. Of six independent isolates, all contained recessive single-factor mutations and comprise two unlinked loci, ksA and ksB. All k-shy strains showed prolonged backward swimming responses to depolarizing stimuli, but gave infrequent responses to some stimuli. At least four k-shy strains displayed temperature sensitivity. Neither ksA nor ksB was allelic or linked to dancer, a mutation causing weak Ca2+ current inactivation and prolonged backward swimming. Analysis of ks+; Dn double mutants revealed synergism between the two mutations. The ksA mutant survived Ba2+ solutions longer than wild type, but was more sensitive to K+. Together with previous studies, these results are consistent with a defect in reducing intracellular Ca2+ causing both prolonged ciliary reversal and reduced Ca2+ channel activity due to more active Ca2+-dependent feedback mechanisms. The integration of the Ca2+-dependent stimulatory and inhibitory functions is therefore dependent on ks+ gene functions. The ksA mutant was rescued by microinjection of wild-type cytoplasm, suggesting a possible behavioral assay for factors related to the ksA+ gene product.     

Fluorescence spectroscopic analysis of calpain II interactions with calcium and calmodulin antagonists

1. The intrinsic fluorescence of epoxysuccinyl-inhibited calpain II undergoes a Ca2(+)-dependent decrease which contrasts with the increase observed for calmodulin. 2. Calpain II was inhibited by the calmodulin antagonist toluidinylnaphthalenesulfonate (TNS), and a Ca2(+)-dependent increase in TNS fluorescence intensity was observed for epoxysuccinyl-inhibited calpain II. 3. The calmodulin antagonists calmidazolium CDZ and felodipine both caused decreases in the intrinsic fluorescence of epoxysuccinyl-inhibited calpain II. 4. Increasing concentrations of Ca2+ caused an increase in the fluorescence intensity of the inhibited enzyme in the presence of (CDZ), and a decrease in the presence of felodipine. 5. It is concluded from these studies that Ca2+ and calmodulin antagonists induce conformational changes in calpain II, and that changes occur in regions other than the Ca2(+)-binding domains.     

Mathematical model of oscillations in mammalian erythrocytes. The role of calmodulin-dependent Ca-activated Ca-pump

A kinetic model of ionophore-induced oscillation of ion fluxes in mammalian erythrocytes is proposed. The model is based on the regulation by Ca2(+)-ions and calmodulin of (Ca2(+) + Mg2+)-dependent ATPase of erythrocytes. The results obtained are in a good agreement with the experimental data available.     

Mutational analysis of the phototransduction pathway of Chlamydomonas reinhardtii

Chlamydomonas has two photobehavioral responses, phototaxis and photoshock. Rhodopsin is the photoreceptor for these responses and the signal transduction process involves transmembrane Ca2+ fluxes. This causes transient changes in flagellar beating, ultimately resulting in phototaxis or photoshock. To identify components that make up this signal transduction pathway, we generated nonphototactic strains by insertional mutagenesis. Seven new phototaxis genes were identified (ptx2-ptx8); alleles of six of these are tagged by the transforming DNA and therefore should be easily cloned. To order the mutants in the pathway, we characterized them electrophysiologically, behaviorally, and structurally, ptx5, ptx6, and ptx7 have normal light-induced photoreceptor currents (PRC) and flagellar currents (FC) but their pattern of swimming does not change in the normal manner when the intraflagellar Ca2+ concentration is decreased, suggesting that they have defects in the ability of their axonemes to respond to changes in Ca2+ concentration. ptx2 and ptx8 lack the FC but have normal PRCs, suggesting that they are defective in the flagellar Ca2+ channel or some factor that regulates it. ptx4 mutants have multiple eye-spots. ptx3 mutants are defective in a component essential for phototaxis but bypassed during photoshock; this component appears to be located downstream of the PRC but upstream of the axoneme.     

Vasoactive intestinal peptide activates Ca2(+)-dependent K+ channels through a cAMP pathway in mouse lacrimal cells

The action of vasoactive intestinal peptide (VIP) on Ca2(+)-dependent K+ currents, in dissociated mouse lacrimal cells, was investigated using patch clamp techniques. In whole cell recordings, VIP (10-100 pM) increased the magnitude of the Ca2(+)-dependent K+ current. In single channel recordings, VIP increased the fraction of time the large charybdotoxin-sensitive Ca2(+)-activated K+ channel spent in the open state. The activity of this channel was also increased by adding forskolin or 8-bromo cAMP to the bath. Additionally, application of either cAMP or catalytic subunit of cAMP-dependent protein kinase directly to the cytoplasmic surface of excised inside out patches reversibly lengthened the time Ca2(+)-activated K+ channels spent in the open state. These data suggest that VIP stimulates Ca2(+)-activated K+ channels by a cAMP-dependent pathway in mouse lacrimal acinar cells.     

Voltage-dependent ionic conductances in the human malignant astrocytoma cell line U87-MG

Although the human malignant astrocytoma cell line U87-MG has been used in numerous studies, few findings are available on the properties of its membrane ion conductances. Characterization of the ion channels expressed in these cells will make it possible to study membrane ion conductance changes when a receptor is activated by its ligand. This will help to elucidate the functional properties of these receptors and their signal-transduction pathways in pathophysiological events. This work studied the voltage-dependent ionic conductances of U87-MG cells using the Whole-Cell Recording patch-clamp technique. Six types of voltage-dependent ionic currents were identified: (i) a TEA-, 4-AP- and CTX-sensitive Ca2+-dependent K+ current, (ii) a transient K+ current inhibited by 4-AP, (iii) an inwardly rectifying K+ current blocked by Ba2+ and 4-AP, (iv) a DIDS- and SITS-sensitive Cl- current, (v) a TTX-sensitive Na+ conductance and (vi) a L-type Ca2+ conductance activated by BayK-8644 and inhibited by Ni and the L-type Ca2+ channel inhibitor, nifedipine. In addition, electrical depolarizations elicited inward currents due to voltage-independent, Ca2+-dependent K+ influx against the electrochemical gradient, probably via an ouabain-sensitive Na+-K+ pump.     

Activation of potassium and chloride channels by tumor necrosis factor alpha. Role in liver cell death

Despite abundant evidence for changes in mitochondrial membrane permeability in tumor necrosis factor (TNF)-mediated cell death, the role of plasma membrane ion channels in this process remains unclear. These studies examine the influence of TNF on ion channel opening and death in a model rat liver cell line (HTC). TNF (25 ng/ml) elicited a 2- and 5-fold increase in K(+) and Cl(-) currents, respectively, in HTC cells. These increases occurred within 5-10 min after TNF exposure and were inhibited either by K(+) or Cl(-) substitution or by K(+) channel blockers (Ba(2+), quinine, 0.1 mm each) or Cl(-) channel blockers (10 microm 5-nitro-2-(3-phenylpropylamino)benzoic acid and 0.1 mm N-phenylanthranilic acid), respectively. TNF-mediated increases in K(+) and Cl(-) currents were each inhibited by intracellular Ca(2+) chelation (5 mm EGTA), ATP depletion (4 units/ml apyrase), and the protein kinase C (PKC) inhibitors chelerythrine (10 micrometer) or PKC 19-36 peptide (1 micrometer). In contrast, currents were not attenuated by the calmodulin kinase II 281-309 peptide (10 micrometer), an inhibitor of calmodulin kinase II. In the presence of actinomycin D (1 micrometer), each of the above ion channel blockers significantly delayed the progression to TNF-mediated cell death. Collectively, these data suggest that activation of K(+) and Cl(-) channels is an early response to TNF signaling and that channel opening is Ca(2+)- and PKC-dependent. Our findings further suggest that K(+) and Cl(-) channels participate in pathways leading to TNF-mediated cell death and thus represent potential therapeutic targets to attenuate liver injury from TNF.     

Calmodulin defects cause the loss of Ca2+-dependent K+ currents in two pantophobiac mutants ofParamecium tetraurelia

Summary Two behavioral mutants ofParamecium tetraurelia, pantophobiacs A¹ and A², have single amino acid defects in the structure of calmodulin. The mutants exhibit several major ion current defects under voltage clamp: (i) the Ca²⁺-dependent K⁺ current activated upon depolarization ofParamecium is greatly reduced or missing in both mutants, (ii) both mutants lack a Ca²⁺-dependent K⁺ current activated upon hyperpolarization, and (iii) the Ca²⁺-dependent Na⁺ current is significantly smaller in pantophobiac A¹ compared with the wild type, whereas this current is slightly increased in pantophobiac A².Other, minor defects include a reduction in peak amplitude of the depolarization-activated Ca²⁺ current in pantophobiac A², increased rates of voltage-dependent inactivation of this Ca²⁺ current in both pantophobiac A¹ and pantophobiac A², and an increase in the time required for the hyperpolarization-activated Ca²⁺ current to recover from inactivation in the pantophobiacs.The diversity of the pantophobiac mutations' effects on ion current function may indicate specific associations of calmodulin with a variety of Ca²⁺-related ion channel species inParamecium.     

Ca2+ modulation of Ca2+ release-activated Ca2+ channels is responsible for the inactivation of its monovalent cation current

The Ca(2+) release-activated Ca(2+) (CRAC) channel is the most well documented of the store-operated ion channels that are widely expressed and are involved in many important biological processes. However, the regulation of the CRAC channel by intracellular or extracellular messengers as well as its molecular identity is largely unknown. Specifically, in the absence of extracellular divalent cations it becomes permeable to monovalent cations with a larger conductance, however this monovalent cation current inactivates rapidly by an unknown mechanism. Here we found that Ca(2+) dissociation from a site on the extracellular side of the CRAC channel is responsible for the inactivation of its Na(+) current, and Ca(2+) occupancy of this site otherwise potentiates its Ca(2+) as well as Na(+) currents. This Ca(2+)-dependent potentiation is required for the normal functioning of CRAC channels.     

Effects of ruthenium red on activation of Ca2(+)-dependent cyclic nucleotide phosphodiesterase.

Ruthenium red inhibited Ca2(+)-dependent phosphodiesterase (Ca2(+)-PDE) selectively with an IC50 value of 15 microM. Increasing calmodulin concentration in the presence of both 100 microM and 4000 microM Ca2+ completely reversed the inhibition of Ca2(+)-PDE activity by ruthenium red. Ruthenium red-induced inhibition of Ca2(+)-PDE activity was also overcome by increasing the concentration of Ca2+ in the presence of both 200 ng and 2000 ng calmodulin, in sharp contrast to fluphenazine-induced inhibition of Ca2(+)-PDE. These results indicate that ruthenium red has distinct inhibitory mechanism which differs from that of calmodulin antagonists previously reported.     

Molecular mechanisms of calmodulin action on TRPV5 and modulation by parathyroid hormone

The epithelial Ca(2+) channel transient receptor potential vanilloid 5 (TRPV5) constitutes the apical entry gate for active Ca(2+) reabsorption in the kidney. Ca(2+) influx through TRPV5 induces rapid channel inactivation, preventing excessive Ca(2+) influx. This inactivation is mediated by the last ～30 residues of the carboxy (C) terminus of the channel. Since the Ca(2+)-sensing protein calmodulin has been implicated in Ca(2+)-dependent regulation of several TRP channels, the potential role of calmodulin in TRPV5 function was investigated. High-resolution nuclear magnetic resonance (NMR) spectroscopy revealed a Ca(2+)-dependent interaction between calmodulin and a C-terminal fragment of TRPV5 (residues 696 to 729) in which one calmodulin binds two TRPV5 C termini. The TRPV5 residues involved in calmodulin binding were mutated to study the functional consequence of releasing calmodulin from the C terminus. The point mutants TRPV5-W702A and TRPV5-R706E, lacking calmodulin binding, displayed a strongly diminished Ca(2+)-dependent inactivation compared to wild-type TRPV5, as demonstrated by patch clamp analysis. Finally, parathyroid hormone (PTH) induced protein kinase A (PKA)-dependent phosphorylation of residue T709, which diminished calmodulin binding to TRPV5 and thereby enhanced channel open probability. The TRPV5-W702A mutant exhibited a significantly increased channel open probability and was not further stimulated by PTH. Thus, calmodulin negatively modulates TRPV5 activity, which is reversed by PTH-mediated channel phosphorylation.     

Genetic Analysis of Mutants with a Reduced Ca2+-Dependent K+ Current in PARAMECIUM TETRAURELIA

Two mutants of Paramecium tetraurelia with greatly reduced Ca2+-dependent K+ currents have been isolated and genetically analyzed. These mutants, designated pantophobiac, give much stronger behavioral responses to all stimuli than do wild-type cells. Under voltage clamp, the Ca2+-dependent K+ current is almost completely eliminated in these mutants, whereas the Ca2+ current is normal. The two mutants, pntA and pntB, are recessive and unlinked to each other. pntA is not allelic to several other ion-channel mutants of P. tetraurelia. The microinjection of a high-speed supernatant fraction of wild-type cytoplasm into either pantophobiac mutant caused a temporary restoration to the wild-type phenotype.     

Identification of a peptide inhibitor of the cardiac sarcolemmal Na(+)-Ca2+ exchanger

The deduced amino acid sequence of the cardiac sarcolemmal Na(+)-Ca2+ exchanger has a region which could represent a calmodulin binding site. As calmodulin binding regions of proteins often have an autoinhibitory role, a synthetic peptide with this sequence was tested for functional effects on Na(+)-Ca2+ exchange activity. The peptide inhibits the Na(+)-dependent Ca2+ uptake (KI approximately 1.5 microM) and the Nao(+)-dependent Ca2+ efflux of sarcolemmal vesicles in a noncompetitive manner with respect to both Na+ and Ca2+. The peptide is also a potent inhibitor (KI approximately 0.1 microM) of the Na(+)-Ca2+ exchange current of excised sarcolemmal patches. The binding site for the peptide on the exchanger is on the cytoplasmic surface of the membrane. The exchanger inhibitory peptide binds calmodulin with a moderately high affinity. From the characteristics of the inhibition of the exchange of sarcolemmal vesicles, we deduce that only inside-out sarcolemmal vesicles participate in the usual Na(+)-Ca2+ exchange assay. This contrasts with the common assumption that both inside-out and right-side-out vesicles exhibit exchange activity.