Modulation of the voltage sensor of L-type Ca2+ channels by intracellular Ca2+

Both intracellular calcium and transmembrane voltage cause inactivation, or spontaneous closure, of L-type (CaV1.2) calcium channels. Here we show that long-lasting elevations of intracellular calcium to the concentrations that are expected to be near an open channel (>/=100 microM) completely and reversibly blocked calcium current through L-type channels. Although charge movements associated with the opening (ON) motion of the channel's voltage sensor were not altered by high calcium, the closing (OFF) transition was impeded. In two-pulse experiments, the blockade of calcium current and the reduction of gating charge movements available for the second pulse developed in parallel during calcium load. The effect depended steeply on voltage and occurred only after a third of the total gating charge had moved. Based on that, we conclude that the calcium binding site is located either in the channel's central cavity behind the voltage-dependent gate, or it is formed de novo during depolarization through voltage-dependent rearrangements just preceding the opening of the gate. The reduction of the OFF charge was due to the negative shift in the voltage dependence of charge movement, as previously observed for voltage-dependent inactivation. Elevation of intracellular calcium concentration from approximately 0.1 to 100-300 microM sped up the conversion of the gating charge into the negatively distributed mode 10-100-fold. Since the "IQ-AA" mutant with disabled calcium/calmodulin regulation of inactivation was affected by intracellular calcium similarly to the wild-type, calcium/calmodulin binding to the "IQ" motif apparently is not involved in the observed changes of voltage-dependent gating. Although calcium influx through the wild-type open channels does not cause a detectable negative shift in the voltage dependence of their charge movement, the shift was readily observable in the Delta1733 carboxyl terminus deletion mutant, which produces fewer nonconducting channels. We propose that the opening movement of the voltage sensor exposes a novel calcium binding site that mediates inactivation.     

心肌兴奋收缩耦联过程中的钙调控

联系以膜电位变化为特征的细胞兴奋和以肌丝滑行为基础的肌肉收缩的中介过程通常称为兴奋收缩耦联。在所有参与调控心肌收缩功能的离子中,钙离子被认为是最重要的介导因子,因此验明钙离子参与介导心肌兴奋收缩耦联的方式和途径等特征无疑有益于更好地理解心脏的生理功能。     

The L-type voltage-gated Ca2+ channel is the Ca2+ sensor protein of stimulus-secretion coupling in pancreatic beta cells

L-type voltage-gated Ca2+ channels (Cav1.2) mediate a major part of insulin secretion from pancreatic beta-cells. Cav1.2, like other voltage-gated Ca2+ channels, is functionally and physically coupled to synaptic proteins. The tight temporal coupling between channel activation and secretion leads to the prediction that rearrangements within the channel can be directly transmitted to the synaptic proteins, subsequently triggering release. La3+, which binds to the polyglutamate motif (EEEE) comprising the selectivity filter, is excluded from entry into the cells and has been previously shown to support depolarization-evoked catecholamine release from chromaffin and PC12 cells. Hence, voltage-dependent trigger of release relies on Ca2+ ions bound at the EEEE motif and not on cytosolic Ca2+ elevation. We show that glucose-induced insulin release in rat pancreatic islets and ATP release in INS-1E cells are supported by La3+ in nominally Ca2+-free solution. The release is inhibited by nifedipine. Fura 2 imaging of dispersed islet cells exposed to high glucose and La3+ in Ca2+-free solution detected no change in fluorescence; thus, La3+ is excluded from entry, and Ca2+ is not significantly released from intracellular stores. La3+ by interacting extracellularlly with the EEEE motif is sufficient to support glucose-induced insulin secretion. Voltage-driven conformational changes that engage the ion/EEEE interface are relayed to the exocytotic machinery prior to ion influx, allowing for a fast and tightly regulated process of release. These results confirm that the Ca2+ channel is a constituent of the exocytotic complex [Wiser et al. (1999) PNAS 96, 248-253] and the putative Ca2+-sensor protein of release.     

The voltage sensor of excitation-contraction coupling in skeletal muscle. Ion dependence and selectivity

Manifestations of excitation-contraction (EC) coupling of skeletal muscle were studied in the presence of metal ions of the alkaline and alkaline-earth groups in the extracellular medium. Single cut fibers of frog skeletal muscle were voltage clamped in a double Vaseline gap apparatus, and intramembrane charge movement and myoplasmic Ca2+ transients were simultaneously measured. In metal-free extracellular media both charge movement of the charge 1 type and Ca transients were suppressed. Under metal-free conditions the nonlinear charge distribution was the same in depolarized (holding potential of 0 mV) and normally polarized fibers (holding potentials between -80 and -90 mV). The manifestations of EC coupling recovered when ions of groups Ia and IIa of the periodic table were included in the extracellular solution; the extent of recovery depended on the ion species. These results are consistent with the idea that the voltage sensor of EC coupling has a binding site for metal cations--the "priming" site--that is essential for function. A state model of the voltage sensor in which metal ligands bind preferentially to the priming site when the sensor is in noninactivated states accounts for the results. This theory was used to derive the relative affinities of the various ions for the priming site from the magnitude of the EC coupling response. The selectivity sequence thus constructed is: Ca greater than Sr greater than Mg greater than Ba for group IIa cations and Li greater than Na greater than K greater than Rb greater than Cs for group Ia. Ca2+, the most effective of all ions tested, was 1,500-fold more effective than Na+. This selectivity sequence is qualitatively and quantitatively similar to that of the intrapore binding sites of the L-type cardiac Ca channel. This provides further evidence of molecular similarity between the voltage sensor and Ca channels.     

Open channel block by Ca2+ underlies the voltage dependence of drosophila TRPL channel

The light-activated channels of Drosophila photoreceptors transient receptor potential (TRP) and TRP-like (TRPL) show voltage-dependent conductance during illumination. Recent studies implied that mammalian members of the TRP family, which belong to the TRPV and TRPM subfamilies, are intrinsically voltage-gated channels. However, it is unclear whether the Drosophila TRPs, which belong to the TRPC subfamily, share the same voltage-dependent gating mechanism. Exploring the voltage dependence of Drosophila TRPL expressed in S2 cells, we found that the voltage dependence of this channel is not an intrinsic property since it became linear upon removal of divalent cations. We further found that Ca(2+) blocked TRPL in a voltage-dependent manner by an open channel block mechanism, which determines the frequency of channel openings and constitutes the sole parameter that underlies its voltage dependence. Whole cell recordings from a Drosophila mutant expressing only TRPL indicated that Ca(2+) block also accounts for the voltage dependence of the native TRPL channels. The open channel block by Ca(2+) that we characterized is a useful mechanism to improve the signal to noise ratio of the response to intense light when virtually all the large conductance TRPL channels are blocked and only the low conductance TRP channels with lower Ca(2+) affinity are active.     

Subtype specificity of the ryanodine receptor for Ca2+ signal amplification in excitation-contraction coupling.

In excitable cells membrane depolarization is translated into intracellular Ca2+ signals. The ryanodine receptor (RyR) amplifies the Ca2+ signal by releasing Ca2+ from the intracellular Ca2+ store upon receipt of a message from the dihydropyridine receptor (DHPR) on the plasma membrane in striated muscle. There are two distinct mechanisms for the amplification of Ca2+ signalling. In cardiac cells depolarization-dependent Ca2+ influx through DHPR triggers Ca2+-induced Ca2+ release via RyR, while in skeletal muscle cells a voltage-induced change in DHPR is thought to be mechanically transmitted, without a requirement for Ca2+ influx, to RyR to cause it to open. In expression experiments using mutant skeletal myocytes lacking an intrinsic subtype of RyR (RyR-1), we demonstrate that RyR-1, but not the cardiac subtype (RyR-2), is capable of supporting skeletal muscle-type coupling. Furthermore, when RyR-2 was expressed in skeletal myocytes, we observed depolarization-independent spontaneous Ca2+ waves and oscillations, which suggests that RyR-2 is prone to regenerative Ca2+ release responses. These results demonstrate functional diversity among RyR subtypes and indicate that the subtype of RyR is the key to Ca2+ signal amplification.     

Large conductance Ca2+-activated K+ (BK) channel: activation by Ca2+ and voltage

Large conductance Ca2+-activated K+ (BK) channels belong to the S4 superfamily of K+ channels that include voltage-dependent K+ (Kv) channels characterized by having six (S1-S6) transmembrane domains and a positively charged S4 domain. As Kv channels, BK channels contain a S4 domain, but they have an extra (S0) transmembrane domain that leads to an external NH2-terminus. The BK channel is activated by internal Ca2+, and using chimeric channels and mutagenesis, three distinct Ca2+-dependent regulatory mechanisms with different divalent cation selectivity have been identified in its large COOH-terminus. Two of these putative Ca2+-binding domains activate the BK channel when cytoplasmic Ca2+ reaches micromolar concentrations, and a low Ca2+ affinity mechanism may be involved in the physiological regulation by Mg2+. The presence in the BK channel of multiple Ca2+-binding sites explains the huge Ca2+ concentration range (0.1 microM-100 microM) in which the divalent cation influences channel gating. BK channels are also voltage-dependent, and all the experimental evidence points toward the S4 domain as the domain in charge of sensing the voltage. Calcium can open BK channels when all the voltage sensors are in their resting configuration, and voltage is able to activate channels in the complete absence of Ca2+. Therefore, Ca2+ and voltage act independently to enhance channel opening, and this behavior can be explained using a two-tiered allosteric gating mechanism.     

Involvement of Ca2+ waves in excitation-contraction coupling of rat atrial cardiomyocytes

Two-dimensional and line-scan analyses of the early phase Ca2+ transients in rat cardiomyocytes were performed with a rapid-scanning laser confocal microscope and fluo-3 to elucidate the mechanism of activation of Ca2+ release from the sarcoplasmic reticulum in atrial myocytes which lack a well developed T-tubular network. On electrical stimulation of ventricular myocytes, Ca2+ concentration began to rise earliest at the Z-line level and became uniform throughout the cytoplasm within about 10 msec. In contrast, on stimulation of atrial myocytes, the earliest rise in Ca2+ occurred at the cell periphery and then spread to the cell interior; cytoplasmic Ca2+ became uniform after more than 30msec. The velocity of the propagation of rise in Ca2+ was 112 +/- 5.1 microm/sec (n = 10), which was similar to that of spontaneous Ca2+ waves observed in atrial and ventricular myocytes. No difference in frequency, amplitude and kinetics of spontaneous Ca2+ sparks was observed between the subsarcolemmal and central regions of atrial myocytes. Ryanodine concentration-dependently decreased the contractile force of isolated rat atrial and ventricular tissue preparations; the sensitivity was higher in atrial myocytes. The present study visualized the involvement of a propagated Ca2+-induced-Ca+ release mechanism in atrial but not ventricular myocytes. This difference may underlie some of the atrioventricular difference in response to physiological and pharmacological stimuli.     

The voltage-gated Ca2+ channel is the Ca2+ sensor of fast neurotransmitter release

Previously it demonstrated that in the absence of Ca²⁺ entry, evoked secretion occurs neither by membrane depolarization, induction of [Ca²⁺] _i rise, nor by both combined (Ashery, U., Weiss, C., Sela, D., Spira, M. E., and Atlas, D. (1993). Receptors Channels 1:217–220.). These studies designate Ca²⁺ entry as opposed to [Ca²⁺] _i rise, essential for exocytosis. It led us to propose that the channel acts as the Ca²⁺ sensor and modulates secretion through a physical and functional contact with the synaptic proteins. This view was supported by protein–protein interactions reconstituted in the Xenopus oocytes expression system and release experiments in pancreatic cells (Barg, S., Ma, X., Elliasson, L., Galvanovskis, J., Gopel, S. O., Obermuller, S., Platzer, J., Renstrom, E., Trus, M., Atlas, D., Streissnig, G., and Rorsman, P. (2001). Biophys. J.; Wiser, O., Bennett, M. K., and Atlas, D. (1996). EMBO J. 15:4100–4110; Wiser, O., Trus, M., Hernandez, A., Renström, E., Barg, S., Rorsman, P., and Atlas, D. (1999). Proc. Natl. Acad. Sci. U.S.A. 96:248–253). The kinetics of Ca_v1.2 (Lc-type) and Ca_v2.2 (N-type) Ca²⁺ channels were modified in oocytes injected with cRNA encoding syntaxin 1A and SNAP-25. Conserved cysteines (Cys271, Cys272) within the syntaxin 1A transmembrane domain are essential. Synaptotagmin I, a vesicle-associated protein, accelerated the activation kinetics indicating Ca_v2.2 coupling to the vesicle. The unique modifications of Ca_v1.2 and Ca_v2.2 kinetics by syntaxin 1A, SNAP-25, and synaptotagmin combined implied excitosome formation, a primed fusion complex of the channel with synaptic proteins. The Ca_v1.2 cytosolic domain Lc_753–893, acted as a dominant negative modulator, competitively inhibiting insulin release of channel-associated vesicles (CAV), the readily releasable pool of vesicles (RRP) in islet cells. A molecular mechanism is offered to explain fast secretion of vesicles tethered to SNAREs-associated Ca²⁺ channel. The tight arrangement facilitates the propagation of conformational changes induced during depolarization and Ca²⁺-binding at the channel, to the SNAREs to trigger secretion. The results imply a rapid Ca²⁺-dependent CAV (RRP) release, initiated by the binding of Ca²⁺ to the channel, upstream to intracellular Ca²⁺ sensor thus establishing the Ca²⁺ channel as the Ca²⁺ sensor of neurotransmitter release.     

Modulation of L-type Ca2+ channels in neonatal rat heart by a novel Ca2+ channel agonist

L-type Ca2+ channels are essential in triggering the intracellular Ca2+ release and contraction in heart cells. In this study, we used patch clamp technique to compare the effect of two pure enantiomers of L-type Ca2+ channel agonists: (+)-CGP 48506 and the dihydropyridine (+)-SDZ-202 791 in cardiomyocytes from rats 2-5 days old. The predominant Ca2+ current activated by standard step pulses in these myocytes was L-type Ca2+ current. The dihydropyridine antagonist (+)-PN200-110 (5 microM) blocked over 90% of Ca2+ currents in most cells tested. CGP 48506 lead to a maximum of 200% increase in currents. The threshold concentration for the CGP effect was at 1 microM and the maximum was reached at 20 microM. SDZ-202 791 had effects in nanomolar concentrations and a maximum effect at about 2 microM. The maximal effect of (+)-SDZ-202 791 was a 400% increase in the amplitude of Ca2+ currents and was accompanied by a 10-15 mV leftward shift in the voltage dependence of activation. CGP 48506 increased the currents equally at all voltages tested. Both compounds slowed the deactivation of tail currents and lead to the appearance of slowly activating and slowly deactivating current components. However, SDZ-202 791 had larger effects on deactivation and CGP 48506 had larger effect on the rate of Ca2+ current activation. The effect of SDZ-202 791 was fully additive to that of CGP 48506 even after maximum concentrations of CGP. This observation suggests that the two Ca2+ channel agonists may act at two different sites on the L-type Ca2+ channel. We suggest that CGP 48506 would be a potential cardiotonic agent without the deleterious proarrhythmic effects attributable to the dihydropyridine agonists.     

Interaction of ATP sensor, cAMP sensor, Ca2+ sensor, and voltage-dependent Ca2+ channel in insulin granule exocytosis

ATP, cAMP, and Ca(2+) are the major signals in the regulation of insulin granule exocytosis in pancreatic beta cells. The sensors and regulators of these signals have been characterized individually. The ATP-sensitive K(+) channel, acting as the ATP sensor, couples cell metabolism to membrane potential. cAMP-GEFII, acting as a cAMP sensor, mediates cAMP-dependent, protein kinase A-independent exocytosis, which requires interaction with both Piccolo as a Ca(2+) sensor and Rim2 as a Rab3 effector. l-type voltage-dependent Ca(2+) channels (VDCCs) regulate Ca(2+) influx. In the present study, we demonstrate interactions of these molecules. Sulfonylurea receptor 1, a subunit of ATP-sensitive K(+) channels, interacts specifically with cAMP-GEFII through nucleotide-binding fold 1, and the interaction is decreased by a high concentration of cAMP. Localization of cAMP-GEFII overlaps with that of Rim2 in plasma membrane of insulin-secreting MIN6 cells. Localization of Rab3 co-incides with that of Rim2. Rim2 mutant lacking the Rab3 binding region, when overexpressed in MIN6 cells, is localized exclusively in cytoplasm, and impairs cAMP-dependent exocytosis in MIN6 cells. In addition, Rim2 and Piccolo bind directly to the alpha(1)1.2-subunit of VDCC. These results indicate that ATP sensor, cAMP sensor, Ca(2+) sensor, and VDCC interact with each other, which further suggests that ATP, cAMP, and Ca(2+) signals in insulin granule exocytosis are integrated in a specialized domain of pancreatic beta cells to facilitate stimulus-secretion coupling.     

Modulation of the epithelial calcium channel, ECaC, by intracellular Ca2+

We have studied the modulation by intracellular Ca2+ of the epithelial Ca2+ channel, ECaC, heterologously expressed in HEK 293 cells. Whole-cell and inside-out patch clamp current recordings were combined with FuraII-Ca2+ measurements:1. Currents through ECaC were dramatically inhibited if Ca2+ was the charge carrier. This inhibition was dependent on the extracellular Ca2+ concentration and occurred also in cells buffered intracellularly with 10 mM BAPTA.2. Application of 30 mM [Ca(2)]e induced in non-Ca2+] buffered HEK 293 cells at -80 m V an increase in intracellular Ca2+([Ca2]i) with a maximum rate of rise of 241 +/-15nM/s (n= 18 cells) and a peak value of 891 +/- 106 nM. The peak of the concomitant current with a density of 12.3 +/- 2.6 pA/pF was closely correlated with the peak of the first-time derivative of the Ca2+ transient, as expected if the Ca2+ transient is due to influx of Ca2+. Consequently, no Ca2+] signal was observed in cells transfected with the Ca2+ impermeable ECaC mutant, D542A, in which an aspartate in the pore region was neutralized.3. Increasing [Ca2+]i by dialyzing the cell with pipette solutions containing various Ca2+] concentrations, all buffered with 10 mM BAPTA, inhibited currents through ECaC carried by either Na+ or Ca2+] ions. Half maximal inhibition of Ca(2+)currents in the absence of monovalent cations occurred at 67 nM (n between 6 and 8), whereas Na+ currents in the absence of Ca2+] and Mg2+ were inhibited with an IC50 of 89 nM (n between 6 and 10). Currents through ECaC in the presence of 1 mM Ca2+ and Na+, which are mainly carried by Ca2+, are inhibited by [Ca2]i with an IC50of 82 nM (n between 6 and 8). Monovalent cation currents through the Ca2+impermeable D542A ECaC mutant were also inhibited by an elevation of [Ca2]i (IC50 = 123 nM, n between 7 and 18). 4. The sensitivity of ECaC currents in inside-out patches for [Ca2]i was slightly shifted to higher concentrations as compared with whole cell measurements. Half-maximal inhibition occurred at 169 nM if Na+ was the charge carrier (n between 4 and 11) and 228 nM at 1 mM [Ca2]e (n between 4 and 8).5. Recovery from inhibition upon washout of extracellular Ca2+ (whole-cell configuration) or removal of Ca2+ from the inner side of the channel (inside-out patches) was slow in both conditions. Half-maximal recovery was reached after 96 +/- 34 s (n= 15) in whole-cell mode and after 135 +/- 23 s (n = 17) in inside-out patches.6. We conclude that influx of Ca2+ through ECaC and [Ca2]i induce feedback inhibition of ECaC currents, which is controlled by the concentration of Ca2+ in a micro domain near the inner mouth of the channel. Slow recovery seems to depend on dissociation of Ca( 2+ from an internal Ca2+ binding site at ECaC.     

Differential regulation of skeletal muscle L-type Ca2+ current and excitation-contraction coupling by the dihydropyridine receptor beta subunit

The dihydropyridine receptor (DHPR) of skeletal muscle functions as a Ca2+ channel and is required for excitation-contraction (EC) coupling. Here we show that the DHPR beta subunit is involved in the regulation of these two functions. Experiments were performed in skeletal mouse myotubes selectively lacking a functional DHPR beta subunit. These beta-null cells have a low-density L-type current, a low density of charge movements, and lack EC coupling. Transfection of beta-null cells with cDNAs encoding for either the homologous beta1a subunit or the cardiac- and brain-specific beta2a subunit fully restored the L-type Ca2+ current (161 +/- 17 pS/pF and 139 +/- 9 pS/pF, respectively, in 10 mM Ca2+). We compared the Boltzmann parameters of the Ca2+ conductance restored by beta1a and beta2a, the kinetics of activation of the Ca2+ current, and the single channel parameters estimated by ensemble variance analysis and found them to be indistinguishable. In contrast, the maximum density of charge movements in cells expressing beta2a was significantly lower than in cells expressing beta1a (2.7 +/- 0.2 nC/microF and 6.7 +/- 0. 4 nC/microF, respectively). Furthermore, the amplitude of Ca2+ transient measured by confocal line-scans of fluo-3 fluorescence in voltage-clamped cells were 3- to 5-fold lower in myotubes expressing beta2a. In summary, DHPR complexes that included beta2a or beta1a restored L-type Ca2+ channels. However, a DHPR complex with beta1a was required for complete restoration of charge movements and skeletal-type EC coupling. These results suggest that the beta1a subunit participates in key regulatory events required for the EC coupling function of the DHPR.     

Cell culture modifies Ca2+ signaling during excitation-contraction coupling in neonate cardiac myocytes

In heart, the excitation-contraction coupling (ECC) mechanism changes during development. Primary cell culture has been used to study Ca(2+) signaling in newborn (NB) rat heart. In this work, the effects of cell culture on the action potential (AP) and ECC Ca(2+) signaling during development were investigated. Specifically, AP, Ca(2+) currents (I(Ca)), and ryanodine receptor (RyR) properties (i.e. density, distribution, and contribution to Ca(2+) transients and Ca(2+) sparks) were defined in cultured myocytes (CM) from 0-day-old NB rat at different times in culture (1-4 days). Compared with acutely dissociated myocytes (ADM) from NB of equivalent ages (1-4 days), CM showed lower RyR density (50% at 1 day, 25% at 4 days), but larger RyR contribution to the Ca(2+) transient (25% at 1 day, 57% at 4 days). Additionally, Ca(2+) sparks were larger, longer, wider, and more frequent in CM than in ADM. RyR cellular distribution also showed different arrangement. While in CM, RyRs were located peripherally, in ADM of equivalent ages a sarcomeric arrangement was predominant. Finally, CM showed a two-fold increase in sarcolemmal Ca(2+) entry during the AP. These results indicated that primary culture is a feasible model to study Ca(2+) signaling in heart; however, it does not precisely reproduce what occurs in ECC during development.     

Mechanistic insights into store-operated Ca2+ entry during excitation-contraction coupling in skeletal muscle

Skeletal muscle fibres support store-operated Ca²⁺-entry (SOCE) across the t-tubular membrane upon exhaustive depletion of Ca²⁺ from the sarcoplasmic reticulum (SR). Recently we demonstrated the presence of a novel mode of SOCE activated under conditions of maintained [Ca²⁺]_SR. This phasic SOCE manifested in a fast and transient manner in synchrony with excitation contraction (EC)-coupling mediated SR Ca²⁺-release (Communications Biology 1:31, doi: https://doi.org/10.1038/s42003-018-0033-7). Stromal interaction molecule 1 (STIM1) and calcium release-activated calcium channel 1 (ORAI1), positioned at the SR and t-system membranes, respectively, are the considered molecular correlate of SOCE. The evidence suggests that at the triads, where the terminal cisternae of the SR sandwich a t-tubule, STIM1 and ORAI1 proteins pre-position to allow for enhanced SOCE transduction.Here we show that phasic SOCE is not only shaped by global [Ca²⁺]_SR but provide evidence for a local activation within nanodomains at the terminal cisternae of the SR. This feature may allow SOCE to modulate [Ca²⁺]_SR during EC coupling. We define SOCE to occur on the same timescale as EC coupling and determine the temporal coherence of SOCE activation to SR Ca²⁺ release. We derive a delay of 0.3 ms reflecting diffusive Ca²⁺-equilibration at the luminal ryanodine receptor 1 (RyR1) channel mouth upon SR Ca²⁺-release. Numerical simulations of Ca²⁺-calsequestrin binding estimates a characteristic diffusion length and confines an upper limit for the spatial distance between STIM1 and RyR1. Experimental evidence for a 4- fold change in t-system Ca²⁺-permeability upon prolonged electrical stimulation in conjunction with numerical simulations of Ca²⁺-STIM1 binding suggests a Ca²⁺ dissociation constant of STIM1 below 0.35 mM. Our results show that phasic SOCE is intimately linked with RyR opening and closing, with only μs delays, because [Ca²⁺] in the terminal cisternae is just above the threshold for Ca²⁺ dissociation from STIM1 under physiological resting conditions.This article is part of a Special Issue entitled: ECS Meeting edited by Claus Heizmann, Joachim Krebs and Jacques Haiech.