Local Ca2+ influx through CRAC channels activates temporally and spatially distinct cellular responses.

Ca(2+) entry through store-operated Ca(2+) release-activated Ca(2+) (CRAC) channels controls a disparate array of key cellular responses. In this review, recent work will be described that shows local Ca(2+) influx through CRAC channels has important spatial and temporal consequences on cell function. A localized Ca(2+) rise below the plasma membrane activates, within tens of seconds, catabolic enzymes resulting in the generation of the intracellular messenger arachidonic acid and the paracrine pro-inflammatory molecule LTC(4). In addition, local Ca(2+) entry can activate gene expression, which develops over tens of minutes. Local Ca(2+) influx through CRAC channels therefore has far-reaching consequences on intra- and intercellular communication.

Permeation through store-operated CRAC channels in divalent-free solution: potential problems and implications for putative CRAC channel genes.

CRAC channels are key calcium conduits in both physiological and pathological states. Understanding how these channels are controlled is important as this will not only provide insight into a novel signal transduction pathway coupling intracellular stores to the channels in the plasma membrane, but might also be of clinical relevance. Determining the molecular identity of the CRAC channels will certainly be a major step forward. Like all Ca(2+)-selective channels, CRAC channels lose their selectivity in divalent-free external solution to support large monovalent Na(+) currents. This approach has provided new insight into channel permeation and selectivity, and identifies some interesting differences between CRAC channels and voltage-operated calcium channels (VOCCs). Studies in divalent-free solution are a double-edged sword, however. Electrophysiologists need to be wary because some of the conditions used to study I(CRAC) in divalent-free external solution, notably omission of Mg(2+)/Mg-ATP from the recording pipette solution, activates an additional current permeating through Mg(2+)-nucleotide-regulated metal ion current (MagNuM; TRPM7) channels. This channel underlies the large single-channel events that have been attributed to CRAC channels in the past and which have been used to as a tool to identify store-operated channels in native cells and recombinant expression systems.Are we any closer to identifying the elusive CRAC channel gene(s)? TRPV6 seemed a very attractive candidate, but one of the main arguments supporting it was a single-channel conductance in divalent-free solution similar to that for CRAC reported under conditions where MagNuM is active. We now know that the conductance of TRPV6 is approximately 200-fold larger than that of CRAC in native tissue. Moreover, it is unclear if TRPV6 is store-operated. Further work on TRPV6, particularly whether its single-channel conductance is still high under conditions where it apparently forms multimers with endogenous store-operated channels, and whether it is activated by a variety of store depletion protocols, will be helpful in finally resolving this issue.

Effects of phosphatidylinositol kinase inhibitors on the activation of the store-operated calcium current ICRAC in RBL-1 cells.

In electrically non-excitable cells, Ca2+ entry is mediated predominantly through the store-operated Ca2+ influx pathway, which is activated by emptying the intracellular Ca2+ stores following an increase in the levels of the second messenger inositol 1,4,5-trisphophate (InsP3). InsP3 is generated from the membrane phospholipid phosphatidylinositol 4,5-bisphosphate (PIP2). Recently, roles for other phosphoinositides (PIs) in store-operated Ca2+ influx have been suggested because inhibitors of PI kinases reduce Ca2+ influx when the latter is triggered independent of PIP2 hydrolysis. Using the whole-cell patch-clamp technique to record the store-operated Ca2+ current ICRAC in RBL-1 cells, we examined whether PIs are involved in linking store depletion to activation of CRAC channels. Of several structurally distinct PI kinase inhibitors, only one (LY294002) was able to reduce partially the extent of activation of ICRAC although this could not be reversed by exogenous phosphatidylinositol 3,4,5-trisphosphate (PIP3). Our findings suggest that, if a PI kinase is involved in activation of ICRAC in RBL-1 cells, it has a unique pharmacological profile. Alternative explanations for the results are discussed.

Energized mitochondria increase the dynamic range over which inositol 1,4,5-trisphosphate activates store-operated calcium influx.

In eukaryotic cells, activation of cell surface receptors that couple to the phosphoinositide pathway evokes a biphasic increase in intracellular free Ca2+ concentration: an initial transient phase reflecting Ca2+ release from intracellular stores, followed by a plateau phase due to Ca2+ influx. A major component of this Ca2+ influx is store-dependent and often can be measured directly as the Ca2+ release-activated Ca2+ current (I(CRAC)). Under physiological conditions of weak intracellular Ca2+ buffering, respiring mitochondria play a central role in store-operated Ca2+ influx. They determine whether macroscopic I(CRAC) activates or not, to what extent and for how long. Here we describe an additional role for energized mitochondria: they reduce the amount of inositol 1,4,5-trisphosphate (InsP3) that is required to activate I(CRAC). By increasing the sensitivity of store-operated influx to InsP3, respiring mitochondria will determine whether modest levels of stimulation are capable of evoking Ca2+ entry or not. Mitochondrial Ca2+ buffering therefore increases the dynamic range of concentrations over which the InsP3 is able to function as the physiological messenger that triggers the activation of store-operated Ca2+ influx.

An examination of the secretion-like coupling model for the activation of the Ca2+ release-activated Ca2+ current I(CRAC) in RBL-1 cells.

One popular model for the activation of store-operated Ca2+ influx is the secretion-like coupling mechanism, in which peripheral endoplasmic reticulum moves to the plasma membrane upon store depletion thereby enabling inositol 1,4,5-trisphosphate (InsP3) receptors on the stores to bind to, and thus activate, store-operated Ca2+ channels. This movement is regulated by the underlying cytoskeleton. We have examined the validity of this mechanism for the activation of I(CRAC), the most widely distributed and best characterised store-operated Ca2+ current, in a model system, the RBL-1 rat basophilic cell line. Stabilisation of the peripheral cytoskeleton, disassembly of actin microfilaments and disaggregation of microtubules all consistently failed to alter the rate or extent of activation of I(CRAC). Rhodamine-phalloidin labelling was used wherever possible, and revealed that the cytoskeleton had been significantly modified by drug treatment. Interference with the cytoskeleton also failed to affect the intracellular calcium signal that occurred when external calcium was re-admitted to cells in which the calcium stores had been previously depleted by exposure to thapsigargin/ionomycin in calcium-free external solution. Application of positive pressure through the patch pipette separated the plasma membrane from underlying structures (cell ballooning). However, I(CRAC) was unaffected irrespective of whether cell ballooning occurred before or after depletion of stores. Pre-treatment with the membrane-permeable InsP3 receptor antagonist 2-APB blocked the activation of I(CRAC). However, intracellular dialysis with 2-APB failed to prevent I(CRAC) from activating, even at higher concentrations than those used extracellularly to achieve full block. Local application of 2-APB, once I(CRAC) had been activated, resulted in a rapid loss of the current at a rate similar to that seen with the rapid channel blocker La3+. Studies with the more conventional InsP3 receptor antagonist heparin revealed that occupation of the intracellular InsP3-sensitive receptors was not necessary for the activation or maintenance of I(CRAC). Similarly, the InsP3 receptor inhibitor caffeine failed to alter the rate or extent of activation of I(CRAC). Exposure to Li+, which reduces InsP3 levels by interfering with inositol monophosphatase, also failed to alter I(CRAC). Caffeine and Li+ did not affect the size of the intracellular Ca2+ signal that arose when external Ca2+ was re-admitted to cells which had been pre-exposed to thapsigargin/ionomycin in Ca2+-free external solution. Our findings demonstrate that the cytoskeleton does not seem to regulate calcium influx and that functional InsP3 receptors are not required for activation of I(CRAC). If the secretion-like coupling model indeed accounts for the activation of I(CRAC) in RBL-1 cells, then it needs to be revised significantly. Possible modifications to the model are discussed.

Sarcoplasmic/endoplasmic-reticulum-Ca2+-ATPase-mediated Ca2+ reuptake, and not Ins(1,4,5)P3 receptor inactivation, prevents the activation of macroscopic Ca2+ release-activated Ca2+ current in the presence of physiological Ca2+ buffer in rat basophilic leukaemia-1 cells.

Whole-cell patch-clamp experiments were performed to examine the mechanism underlying the inability of intracellular Ins(1,4,5)P(3) to activate the Ca(2+) release-activated Ca(2+) current (I(CRAC)) in rat basophilic leukaemia (RBL)-1 cells under conditions of weak cytoplasmic Ca(2+) buffering. Dialysis with Ins(1,4,5)P(3) in weak Ca(2+) buffer did not activate any macroscopic I(CRAC) even after precautions had been taken to minimize the extent of Ca(2+) entry during the experiment. Following intracellular dialysis with Ins(1,4,5)P(3) for >150 s in weak buffer, external application of the sarcoplasmic/endoplasmic-reticulum Ca(2+)-ATPase (SERCA) pump blocker thapsigargin activated I(CRAC), and the current developed much more quickly than when thapsigargin was applied in the absence of Ins(1,4,5)P(3). This indicates that the Ins(1,4,5)P(3) receptors had not inactivated much over this timecourse. When external Ca(2+) was replaced by Ba(2+), Ins(1,4,5)P(3) still failed to generate any detectable I(CRAC) even though Ba(2+) permeates CRAC channels and is not taken up into the intracellular Ca(2+) stores. In strong Ca(2+) buffer, I(CRAC) could be activated by muscarinic-receptor stimulation, provided protein kinase C (PKC) was blocked. In weak buffer, however, as with Ins(1,4,5)P(3), stimulation of these receptors with carbachol did not activate I(CRAC) even after inhibition of PKC. The inability of Ins(1,4,5)P(3) to activate macroscopic I(CRAC) in weak Ca(2+) buffer was not altered by inhibition of Ca(2+)-dependent phosphorylation/dephosphorylation reactions. Our results suggest that the inability of Ins(1,4,5)P(3) to activate I(CRAC) under conditions of weak intracellular Ca(2+) buffering is not due to strong inactivation of the Ins(1,4,5)P(3) receptors. Instead, a futile Ca(2+) cycle across the stores seems to be occurring and SERCA pumps resequester sufficient Ca(2+) to ensure that the threshold for activation of macroscopic I(CRAC) has not been exceeded.

Respiring mitochondria determine the pattern of activation and inactivation of the store-operated Ca(2+) current I(CRAC).

In eukaryotic cells, hormones and neurotransmitters that engage the phosphoinositide pathway evoke a biphasic increase in intracellular free Ca(2+) concentration: an initial transient release of Ca(2+) from intracellular stores is followed by a sustained phase of Ca(2+) influx. This influx is generally store dependent. Most attention has focused on the link between the endoplasmic reticulum and store-operated Ca(2+) channels in the plasma membrane. Here, we describe that respiring mitochondria are also essential for the activation of macroscopic store-operated Ca(2+) currents under physiological conditions of weak intracellular Ca(2+) buffering. We further show that Ca(2+)-dependent slow inactivation of Ca(2+) influx, a widespread but poorly understood phenomenon, is regulated by mitochondrial buffering of cytosolic Ca(2+). Thus, by enabling macroscopic store-operated Ca(2+) current to activate, and then by controlling its extent and duration, mitochondria play a crucial role in all stages of store-operated Ca(2+) influx. Store-operated Ca(2+) entry reflects a dynamic interplay between endoplasmic reticulum, mitochondria and plasma membrane.

Voltage-dependent conductance changes in the store-operated Ca2+ current ICRAC in rat basophilic leukaemia cells.

Tight-seal whole-cell patch-clamp experiments were carried out in order to investigate the effects of different holding potentials on the rate of development and amplitude of the Ca2+ release-activated Ca2+ current ICRAC in rat basophilic leukaemia (RBL-1) cells. ICRAC was monitored at -80 mV from fast voltage ramps, spanning 200 mV in 50 ms. At hyperpolarised potentials, the macroscopic CRAC conductance was lower than that seen at depolarised potentials. The conductance increased almost 5-fold over the voltage range -60 to +40 mV and was seen when the stores were depleted either by the combination of IP3 and thapsigargin in high Ca2+ buffer, or passively with 10 mM EGTA or BAPTA. The voltage-dependent conductance of the CRAC channels could not be fully accounted for by Ca2+-dependent fast inactivation, nor by other slower inhibitory mechanisms. It also did not seem to involve intracellular Mg2+ or the polycations spermine and spermidine. Voltage step relaxation experiments revealed that the voltage-dependent conductance changes developed and reversed slowly, with a time constant of several seconds at -60 mV. In the presence of physiological levels of intracellular Ca2+ buffers, ICRAC was barely detectable when cells were clamped at -60 mV and dialysed with IP3 and thapsigargin, but at 0 mV the current in low Ca2+ buffer was as large as that seen in high Ca2+ buffer. Our results suggest that CRAC channels exhibit slow voltage-dependent conductance changes which can triple the current amplitude over the physiological range of voltages normally encountered by these cells. The role of this conductance change and possible underlying mechanisms are discussed.

Comparison of the activation of the Ca2+ release-activated Ca2+ current ICRAC to InsP3 in Jurkat T-lymphocytes, pulmonary artery endothelia and RBL-1 cells.

In many electrically non-excitable cells, Ca2+ entry is mediated predominantly by the store-operated Ca2+ influx pathway. The best-characterised store-operated Ca2+ current is the Ca2+ release-activated Ca2+ current (ICRAC). It is generally believed that high concentrations of intracellular Ca2+ buffer are required to measure ICRAC, due to Ca2+-dependent inactivation of the channels. Recently, we have recorded robust ICRAC in rat basophilic leukaemia (RBL-1) cells at physiological levels of Ca2+ buffering when stores were depleted by inhibition of the sarcoplasmic/ endoplasmic reticulum Ca2+-activated adenosine triphosphatase (SERCA) pumps. However, the second messenger inositol 1,4,5-trisphosphate (InsP3) was not able to evoke the current under such conditions, despite inducing substantial Ca2+ release. We have therefore suggested that a threshold exists within the Ca2+ stores which has to be overcome for macroscopic ICRAC to activate. To establish whether this is a specific feature of ICRAC in RBL-1 cells or whether it is a more general phenomenon, we investigated whether a threshold is also seen in other cell-types used to study store-operated Ca2+ entry. In Jurkat-T lymphocytes, ICRAC is activated weakly by InsP3 in the presence of low concentrations of Ca2+ buffer, whereas the current is large when SERCA pumps are blocked simultaneously, as in RBL-1 cells. Although the electrophysiological properties of ICRAC in the Jurkat cell are very similar to those of RBL-1 cells, the Na+ conductance in the absence of external divalent cations is quite different. Unexpectedly, we failed consistently to record any store-operated Ca2+ current in macrovascular pulmonary artery endothelia whereas robust ICRAC was seen under the same conditions in RBL-1 cells. Our results show that ICRAC has a similar profile of activation in the presence of physiological levels of Ca2+ buffering for Jurkat T-lymphocytes and RBL-1 cells, indicating that the threshold mechanism may be a general feature of ICRAC activation. Because ICRAC in pulmonary artery endothelia is, at best, very small, additional Ca2+ influx pathways may also contribute to agonist-induced Ca2+ entry.

Ca2+ store dynamics determines the pattern of activation of the store-operated Ca2+ current I(CRAC) in response to InsP3 in rat basophilic leukaemia cells.

1. The relationship between the amplitude of the store-operated Ca2+ ICR AC and intracellular inositol 1,4,5-triphosphate (InsP3) concentration is complex. In rat basophilic leukaemia (RBL-1) cells dialysed with high intracellular Ca2+ buffer, the relationship is supra-linear with a Hill coefficient of 12 and resembles an apparent 'all-or-none' phenomenon. The non-linearity seems to arise from InsP3 metabolism. However, it is not clear which InsP3-metabolising pathway engenders the non-linear behaviour nor whether ICRAC is always activated to its maximal extent by InsP3. 2. Using the whole-cell patch clamp technique, we dialysed RBL-1 cells with different concentrations of the InsP3 analogue InsP3-F. InsP3-F is broken down by Ins(1,4,5)P3 5-phosphatase but is not a substrate for Ins(1,4,5)P3 3-kinase. The relationship between InsP3-F and ICRAC amplitude was supra-linear and very similar to that with InsP3 but was distinct from the graded relationship seen with the non-metabolisable analogue Ins2,4,5P3. 3. In the presence of high intracellular Ca2+ buffer, InsP3-F activated ICRAC to its maximal extent. With moderate Ca2+ buffer, however, sub-maximal ICRAC could be obtained to a maximal InsP3-F concentration. Nevertheless, the relationship between the amplitude of ICRAC and InsP3-F concentration was still supra-linear. 4. Submaximal ICRAC in response to InsP3-F in the presence of moderate Ca2+ buffer was due to partial depletion of the stores, because the size of the current could be increased by thapsigargin. 5. The data suggest that first Ins(1,4,5)P3 5-phosphatase is an important factor which contributes to the non-linear relationship between InsP3 concentration and the amplitude of ICRAC and second, InsP3 does not always activate ICRAC to its maximal extent. At moderate buffer strengths, submaximal ICRAC is evoked by maximal InsP3. However, the supra-linear relationship between InsP3 concentration and amplitude of the current still holds.

Substantial depletion of the intracellular Ca2+ stores is required for macroscopic activation of the Ca2+ release-activated Ca2+ current in rat basophilic leukaemia cells.

1. Tight-seal whole-cell patch clamp experiments were performed to examine the ability of different intracellular Ca2+ mobilising agents to activate the Ca2+ release-activated Ca2+ current (ICRAC) in rat basophilic leukaemia (RBL-1) cells under conditions of weak cytoplasmic Ca2+ buffering. 2. Dialysis with a maximal concentration of inositol 1,4,5-trisphosphate (IP3) routinely failed to activate macroscopic ICRAC in low buffer (0.mM EGTA, BAPTA or dimethyl BAPTA), whereas it activated the current to its maximal extent in high buffer (10 mM EGTA). Dialysis with a poorly metabolisable analogue of IP3, with ionomycin, or with IP3 and ionomycin all failed to generate macroscopic ICRAC in low Ca2+ buffering conditions. 3. Dialysis with the sarco/endoplasmic reticulum Ca2+-ATPase (SERCA) pump blocker thapsigargin was able to activate ICRAC even in the presence of low cytoplasmic Ca2+ buffering, albeit at a slow rate. Exposure to IP3 together with the SERCA blockers thapsigargin, thapsigargicin or cyclopiazonic acid rapidly activated ICRAC in low buffer. 4. Following activation of ICRAC by intracellular dialysis with IP3 and thapsigargin in low buffer, the current was very selective for Ca2+ (apparent KD of 1 mM) Sr2+ and Ba2+ were less effective charge carriers and Na+ was not conducted to any appreciable extent. The ionic selectivity of ICRAC was very similar in low or high intracellular Ca2+ buffer. 5. Fast Ca2+-dependent inactivation of ICRAC occurred at a similar rate and to a similar extent in low or high Ca2+ buffer. Ca2+-dependent inactivation is not the reason why macroscopic ICRAC cannot be seen under conditions of low cytoplasmic Ca2+ buffering. 6. ICRAC could be activated by combining IP3 with thapsigargin, even in the presence of 100 microM Ca2+ and the absence of any exogenous Ca2+ chelator, where ATP and glutamate represented the only Ca2+ buffers in the pipette solution. 7. Our results suggest that a threshold exists within the IP3-sensitive Ca2+ store, below which intraluminal Ca2+ needs to fall before ICRAC activates. Possible models to explain the results are discussed.

On the characterisation of the mechanism underlying passive activation of the Ca2+ release-activated Ca2+ current ICRAC in rat basophilic leukaemia cells.

1. Tight-seal whole-cell patch clamp experiments were performed to investigate the mechanism whereby passive depletion of stores activates the Ca2+ release-activated Ca2+ current (ICRAC) in rat basophilic leukaemia (RBL) cells. 2. Passive depletion of stores was achieved by dialysing cells with different concentrations of Ca2+ chelators. Low concentrations generally evoked a submaximal ICRAC, which developed slowly and monophasically. Higher concentrations resulted in a biphasic current in which the initial slow monophasic component developed into a faster and bigger second phase. 3. The kinetics of ICRAC as well as its final amplitude were not affected by Ca2+ chelators that had different affinities or speeds of binding. 4. Exogenous Ca2+ binding ratios > or = 16,670 were necessary to fully activate ICRAC. Because the Ca2+ binding ratio within the stores is presumably low, this indicates that other factors like Ca2+ transport across the stores membrane are rate limiting for passive store depletion. 5. Heparin and Ruthenium Red both failed to affect passive Ca2+ leak from the intracellular stores. 6. Treatment with sarco/endoplasmic reticulum Ca2+-ATPase (SERCA) pump blockers dramatically altered the kinetics of activation of biphasic currents, and increased the amplitude of monophasic ones. 7. Our results suggest that SERCA pumps are very effective in preventing ICRAC from activating passively, and are responsible for the phasic nature of the current, its time course of development and its overall extent.

Fast calcium-dependent inactivation of calcium release-activated calcium current (CRAC) in RBL-1 cells.

Fast inactivation of the Ca2+ release-activated Ca2+ current (ICRAC) was studied using whole cell patch-clamp recordings in rat basophilic leukemia (RBL-1) cells. Application of hyperpolarizing voltage steps from the holding potential of 0 mV revealed that ICRAC declined in amplitude over tens of milliseconds during steps more negative than -40 mV. This fast inactivation was predominantly Ca2+-dependent because first, it could be more effectively suppressed when BAPTA was included in the recording pipette instead of EGTA and second, replacing external Ca2+ with Sr2+ resulted in less inactivation. Recovery from inactivation was faster in the presence of BAPTA than EGTA. The extent of fast inactivation was independent of the whole cell ICRAC amplitude, compatible with the notion that the inactivation arose from a local feedback inhibition by permeating Ca2+ ions only on the channel it permeated. Ca2+ release from stores did not affect fast inactivation, nor did FCepsilonRI receptor stimulation. Current clamp recordings showed that the majority of RBL cells had a membrane potential close to -90 mV following stimulation of FCepsilonRI receptors. Hence fast inactivation is likely to impact on the extent of Ca2+ influx through CRAC channels under physiological conditions and appears to be an important negative feedback process that limits Ca2+ increases.

The effects of interfering with GTP-binding proteins on the activation mechanism of calcium release-activated calcium current.

In electrically non-excitable cells, Ca2+ entry is mediated predominantly by the store-operated Ca2+ influx pathway, which is activated by emptying the intracellular Ca2+ stores. Just how the Ca2+ content of the stores is communicated to the activity of store-operated Ca2+ channels in the plasma membrane is unclear. It has been suggested that, in some cell types, the link is accomplished by either a small or a heterotrimeric GTP-binding protein, which is inhibited by guanosine 5'-O-(3-thiotriphosphate) (GTP[gamma-S]) and, in some cases, pertussis toxin. Using the whole-cell patch-clamp technique to directly measure the store-operated Ca2+ current ICRAC (Ca2+-release-activated Ca2+ current) in RBL cells, we report that manipulations designed to interfere with GTP-binding protein activity (dialysis with GTP[gamma-S], exposure to pertussis toxin) routinely fail to affect the activation of ICRAC. However, these agents alter the activity of a K+ current in the same cells, demonstrating biological activity. Furthermore, activation of ICRAC does not seem to require the presence of a pre-existing diffusible messenger in the cytoplasm to any appreciable extent because the current reaches the same amplitude irrespective of the whole-cell dialysis time. We conclude that neither a mobile pre-existing molecule nor a GTP-dependent step is necessary for the activation of ICRAC in RBL-1 cells.

An examination of the role of intracellular ATP in the activation of store-operated Ca2+ influx and Ca2+-dependent capacitance increases in rat basophilic leukaemia cells.

The role of ATP in both the activation of store-operated Ca2+ current ICRAC and in Ca2+-dependent vesicular fusion was examined in a study of rat basophilic leukaemia (RBL) cells using the whole-cell patch-clamp technique. Fusion was monitored via changes in plasma membrane capacitance. Following a decrease in the levels of intracellular ATP, achieved using the mitochondrial poison antimycin and the ATP synthase inhibitor oligomycin, as well as a reduction of glycolysis by removal of external glucose, ICRAC activated in a manner similar to control cells when stores are depleted by dialysis with a pipette solution containing either inositol 1,4, 5-trisphosphate (InsP3) or ionomycin together with a high concentration of EGTA. Dialysis of cells for 150 s with the non-hydrolysable ATP analogue 5'-adenylylimidodiphosphate (AMP-PNP) (2 mM) in addition to the mitochondrial inhibitors also failed to prevent activation of ICRAC following external application of ionomycin and thapsigargin, when compared with control recordings obtained with 2 mM ATP instead. Ca2+-dependent vesicular fusion was triggered by dialysing cells with 10 microM Ca2+ and guanosine-5'-O-(3-thiotriphosphate (GTP[gamma-S]). The capacitance increase was unaffected by inhibition of glycolysis, mitochondrial inhibitors or dialysis with either AMP-PNP or adenosine 5'-O-(3-thiotriphosphate) (ATP[gamma-S]) instead of ATP. We conclude that ATP hydrolysis does not seem to be necessary for the activation of ICRAC or for the capacitance increases elicited by high concentrations of intracellular Ca2+.

Ca2+-dependent capacitance increases in rat basophilic leukemia cells following activation of store-operated Ca2+ entry and dialysis with high-Ca2+-containing intracellular solution.

Ca2+-dependent vesicular fusion was studied in single whole-cell patch-clamped rat basophilic leukemia (RBL) cells using the capacitance technique. Dialysis of the cells with 10 microM free Ca2+ and 300 microM guanosine 5'-O-(3-thiotriphosphate) (GTP[gamma-S]) resulted in prominent capacitance increases. However, dialysis with either Ca2+ (225 nM to 10 microM) or GTP[gamma-S] alone failed to induce a capacitance change. Under conditions of weak Ca2+ buffering (0.1 mM EGTA), activation of Ca2+-release-activated Ca2+ (CRAC) channels by dialysis with inositol 1,4,5-trisphosphate (InsP3) failed to induce a capacitance increase even in the presence of GTP[gamma-S]. However, when Ca2+ATPases were inhibited by thapsigargin, InsP3 and GTP[gamma-S] led to a pronounced elevation in membrane capacitance. This increase was dependent on a rise in intracellular Ca2+ because it was abolished when cells were dialysed with a high level of EGTA (10 mM) in the recording pipette. The increase was also dependent on Ca2+ influx because it was effectively suppressed when external Ca2+ was removed. Our results demonstrate that ICRAC represents an important source of Ca2+ for triggering a secretory response.

Voltage-dependent conductance changes in a nonvoltage-activated sodium current from a mast cell line.

Nonexcitable cells do not express voltage-activated Na+ channels. Instead, selective Na+ influx is accomplished through GTP-activated Na+ channels, the best characterized of which are found in renal epithelia. We have described recently a GTP-dependent Na+ current in rat basophilic leukemia (RBL) cells that differs from previous reported Na+ channels in several ways including selectivity, pharmacology and mechanism of activation. In this report, we have investigated the biophysical properties of the RBL cell Na+ current using the whole cell patch-clamp technique. Following activation by 250-500 microM GTP gamma S, hyperpolarizing steps to a fixed potential (-100 mV) from a holding potential of 0 mV evoked transient inward Na+ currents that declined during the pulse. If the holding potential was made more positive (range 0 to +100 mV), then the amplitude of the transient inward current evoked by the hyperpolarization increased steeply, demonstrating that the conductance of the channels was voltage-dependent. Using a paired pulse protocol (500 msec pulses to -100 mV from a holding potential of 0 mV), it was found that the peak amplitude of the current during the second pulse became larger as the interpulse potential became more positive. In addition, increasing the time at which the cells were held at positive potentials also resulted in larger currents, indicating a time-dependent conductance change. With symmetrical Na+ solutions, outward currents were recorded at positive potentials and these demonstrated both a time- and voltage-dependent increase in conductance. The results show that a nonvoltage activated Na+ channel in an electrically nonexcitable cell undergoes prominent voltage-dependent transitions. Possible mechanisms underlying this voltage dependency are discussed.

Slow feedback inhibition of calcium release-activated calcium current by calcium entry.

In many nonexcitable cells, depletion of the inositol 1,4, 5-trisphosphate-sensitive store activates Ca2+ influx, a process termed store-operated Ca2+ entry. In rat basophilic leukemia cells, emptying of the stores activates a highly selective Ca2+ release-activated Ca2+ current (CRAC), ICRAC. We have recently found that ICRAC activates in an essentially all-or-none manner when the current is evoked by receptor stimulation, dialysis with inositol 1, 4,5-trisphosphate via the patch pipette, or through the Ca2+ATPase inhibitor thapsigargin (Parekh, A. B., Fleig, A., and Penner, R. (1997) Cell 89, 973-980). Regulatory mechanisms must therefore operate to control the overall amount of Ca2+ that enters through CRAC channels. Such mechanisms include membrane potential and protein kinase C. In the present study, we have investigated additional inhibitory pathways that serve to determine just how much Ca2+ can enter through ICRAC. We have directly measured the current using the whole cell patch clamp technique. We report the presence of a slow Ca2+-dependent inactivation mechanism that curtails Ca2+ entry through CRAC channels. This inactivation mechanism is switched on by Ca2+ entering through CRAC channels, and therefore constitutes a slow negative feedback process. Although it requires a rise in intracellular Ca2+ for activation, it maintains CRAC channels inactive even under conditions that lower intracellular Ca2+ levels. The inactivation mechanism does not involve store refilling, protein phosphorylation, G proteins, nor Ca2+-dependent enzymes. It accounts for up to 70% of the total inactivation of ICRAC, and therefore appears to be a dominant inhibitory mechanism. It is likely to be an important factor that shapes the profile of the Ca2+ signal in these nonexcitable cells.

Store depletion and calcium influx.

Calcium influx in nonexcitable cells regulates such diverse processes as exocytosis, contraction, enzyme control, gene regulation, cell proliferation, and apoptosis. The dominant Ca2+ entry pathway in these cells is the store-operated one, in which Ca2+ entry is governed by the Ca2+ content of the agonist-sensitive intracellular Ca2+ stores. Only recently has a Ca2+ current been described that is activated by store depletion. The properties of this new current, called Ca2+ release-activated Ca2+ current (ICRAC), have been investigated in detail using the patch-clamp technique. Despite intense research, the nature of the signal that couples Ca2+ store content to the Ca2+ channels in the plasma membrane has remained elusive. Although ICRAC appears to be the most effective and widespread influx pathway, other store-operated currents have also been observed. Although the Ca2+ release-activated Ca2+ channel has not yet been cloned, evidence continues to accumulate that the Drosophila trp gene might encode a store-operated Ca2+ channel. In this review, we describe the historical development of the field of Ca2+ signaling and the discovery of store-operated Ca2+ currents. We focus on the electrophysiological properties of the prototype store-operated current ICRAC, discuss the regulatory mechanisms that control it, and finally consider recent advances toward the identification of molecular mechanisms involved in this ubiquitous and important Ca2+ entry pathway.