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.     

电压门控钙通道钙依赖性易化和失活的分子机制

电压门控钙通道受钙依赖性易化和失活两种相互对立的反馈机制调节.不同浓度的钙离子,通过作为钙感受器的钙调蛋白的介导,主要与钙通道α1亚基羧基端的多个不连续片段发生复杂的相互作用,分别引发钙依赖性易化和失活.钙/钙调蛋白依赖性蛋白激酶Ⅱ及其它钙结合蛋白等也参与此调节过程.新近研究表明,钙通道的钙依赖性调节机制失衡与心律失常等的发病机制密切相关.     

Regulation of Ca2+ release-activated Ca2+ channels by INAD and Ca2+ influx factor

Thecoupling mechanism between depletion of Ca²⁺ stores in theendoplasmic reticulum and plasma membrane store-operated ion channelsis fundamental to Ca²⁺ signaling in many cell types and hasyet to be completely elucidated. Using Ca²⁺release-activated Ca²⁺ (CRAC) channels in RBL-2H3 cells asa model system, we have shown that CRAC channels are maintained in theclosed state by an inhibitory factor rather than being opened by theinositol 1,4,5-trisphosphate receptor. This inhibitory role can befulfilled by the Drosophila protein INAD (inactivation-noafter potential D). The action of INAD requires Ca²⁺ andcan be reversed by a diffusible Ca²⁺ influx factor. Thusthe coupling between the depletion of Ca²⁺ stores and theactivation of CRAC channels may involve a mammalian homologue of INADand a low-molecular-weight, diffusible store-depletion signal.

     

Tetrandrine inhibits Ca2+ release-activated Ca2+ channels in vascular endothelial cells

The effects of tetrandrine (TET), a Ca2+ antagonist of bis-benzylisoquinoline alkaloid origin, on cultured single bovine pulmonary artery endothelial cells were examined using fluorescence ratio imaging and whole-cell attached patch-clamp techniques. Thapsigargin (TSG, 100 nM), a selective endoplasmic reticulum Ca2+-ATPase pump inhibitor known to induce the release of nitric oxide (NO) from vascular endothelial cells via a Ca2+-dependent manner, caused a rapid elevation of cytosolic Ca2+ concentration, which was inhibited by 30 microM TET. In whole-cell patch-clamp study using the same vascular endothelial cells, addition of 100 nM TSG caused a significant enhancement of depolarization-evoked Ca2+-dependent, outward K+ currents, which could also be abolished by 30 microM TET. The present results demonstrate directly that TET, in addition to its known inhibitory effects on vascular smooth muscle by virtue of its Ca2+ antagonistic actions, also inhibits NO production by the endothelial cells through blockade of Ca2+ release-activated Ca2+ channels.     

Stable activation of single Ca2+ release-activated Ca2+ channels in divalent cation-free solutions

The regulation of store-operated, calcium-selective channels in the plasma membrane of rat basophilic leukemia cells (RBL-2H3 m1), an immortalized mucosal mast cell line, was studied at the single-channel level with the patch clamp technique by removing divalent cations from both sides of the membrane. The activity of the single channels in excised patches could be modulated by Ca(2+), Mg(2+), and pH. The maximal activation of these channels by divalent cation-free conditions occurred independently of depletion of intracellular Ca(2+) stores, whether in excised patches or in whole cell mode. Yet, a number of points of evidence establish these single-channel openings as amplified store-operated channel events. Specifically, (i) the single channels are exquisitely sensitive to inhibition by intracellular Ca(2+), and (ii) both the store-operated current and the single-channel openings are completely blocked by the capacitative calcium entry blocker, 2-aminoethoxydiphenyl borane. In addition, in Jurkat T cells single-channel openings with lower open probability have been observed in the whole cell mode with intracellular Mg(2+) present (Kerschbaum, H. H., and Cahalan, M. D. (1999) Science 283, 836-839), and in RBL-2H3 m1 cells a current with similar properties is activated by store depletion.     

Murine ORAI2 splice variants form functional Ca2+ release-activated Ca2+ (CRAC) channels

The stimulation of membrane receptors coupled to the phopholipase C pathway leads to activation of the Ca(2+) release-activated Ca(2+) (CRAC) channels. Recent evidence indicates that ORAI1 is an essential pore subunit of CRAC channels. STIM1 is additionally required for CRAC channel activation. The present study focuses on the genomic organization, tissue expression pattern, and functional properties of the murine ORAI2. Additionally, we report the cloning of the murine ORAI1, ORAI3, and STIM1. Two chromosomal loci were identified for the murine orai2 gene, one containing an intronless gene and a second locus that gives rise to the splice variants ORAI2 long (ORAI2L) and ORAI2 short (ORAI2S). Northern blots revealed a prominent expression of the ORAI2 variants in the brain, lung, spleen, and intestine, while ORAI1, ORAI3, and STIM1 appeared to be near ubiquitously expressed in mice tissues. Specific antibodies detected ORAI2 in RBL 2H3 but not in HEK 293 cells, whereas both cell lines appeared to express ORAI1 and STIM1 proteins. Co-expression experiments with STIM1 and either ORAI1 or ORAI2 variants showed that ORAI2L and ORAI2S enhanced substantially CRAC current densities in HEK 293 but were ineffective in RBL 2H3 cells, whereas ORAI1 strongly amplified CRAC currents in both cell lines. Thus, the capability of ORAI2 variants to form CRAC channels depends strongly on the cell background. Additionally, CRAC channels formed by ORAI2S were strongly sensitive to inactivation by internal Ca(2+). When co-expressed with STIM1 and ORAI1, ORAI2S apparently plays a negative dominant role in the formation of CRAC channels.     

Ca2+-calmodulin-dependent protein kinase II potentiates store-operated Ca2+ current

A rise in intracellular Ca2+ (Ca2+i) mediates various cellular functions ranging from fertilization to gene expression. A ubiquitous Ca2+ influx pathway that contributes significantly to the generation of Ca2+i signals, especially in non-excitable cells, is store-operated Ca2+ entry (SOCE). Consequently, the modulation of SOCE current affects Ca2+i dynamics and thus the ensuing cellular response. Therefore, it is important to define the mechanisms that regulate SOCE. Here we show that a rise in Ca2+i potentiates SOCE. This potentiation is mediated by Ca2+-calmodulin-dependent protein kinase II (CaMKII), because inhibition of endogenous CaMKII activity abrogates Ca2+i-mediated SOCE potentiation and expression of constitutively active CaMKII potentiates SOCE current independently of Ca2+i. Moreover, we present evidence that CaMKII potentiates SOCE by altering SOCE channel gating. The regulation of SOCE by CaMKII defines a novel modulatory mechanism of SOCE with important physiological consequences.     

Divergence of Ca2+ selectivity and equilibrium Ca2+ blockade in a Ca2+ release-activated Ca2+ channel

Prevailing models postulate that high Ca²⁺ selectivity of Ca²⁺ release-activated Ca²⁺ (CRAC) channels arises from tight Ca²⁺ binding to a high affinity site within the pore, thereby blocking monovalent ion flux. Here, we examined the contribution of high affinity Ca²⁺ binding for Ca²⁺ selectivity in recombinant Orai3 channels, which function as highly Ca²⁺-selective channels when gated by the endoplasmic reticulum Ca²⁺ sensor STIM1 or as poorly Ca²⁺-selective channels when activated by the small molecule 2-aminoethoxydiphenyl borate (2-APB). Extracellular Ca²⁺ blocked Na⁺ currents in both gating modes with a similar inhibition constant (K_i; ∼25 µM). Thus, equilibrium binding as set by the K_i of Ca²⁺ blockade cannot explain the differing Ca²⁺ selectivity of the two gating modes. Unlike STIM1-gated channels, Ca²⁺ blockade in 2-APB–gated channels depended on the extracellular Na⁺ concentration and exhibited an anomalously steep voltage dependence, consistent with enhanced Na⁺ pore occupancy. Moreover, the second-order rate constants of Ca²⁺ blockade were eightfold faster in 2-APB–gated channels than in STIM1-gated channels. A four-barrier, three–binding site Eyring model indicated that lowering the entry and exit energy barriers for Ca²⁺ and Na⁺ to simulate the faster rate constants of 2-APB–gated channels qualitatively reproduces their low Ca²⁺ selectivity, suggesting that ion entry and exit rates strongly affect Ca²⁺ selectivity. Noise analysis indicated that the unitary Na⁺ conductance of 2-APB–gated channels is fourfold larger than that of STIM1-gated channels, but both modes of gating show a high open probability (P_o; ∼0.7). The increase in current noise during channel activation was consistent with stepwise recruitment of closed channels to a high P_o state in both cases, suggesting that the underlying gating mechanisms are operationally similar in the two gating modes. These results suggest that both high affinity Ca²⁺ binding and kinetic factors contribute to high Ca²⁺ selectivity in CRAC channels.     

Close functional coupling between Ca2+ release-activated Ca2+ channels, arachidonic acid release, and leukotriene C4 secretion

In non-excitable cells, one major route for Ca2+ influx is through store-operated Ca2+ channels in the plasma membrane. These channels are activated by the emptying of intracellular Ca2+ stores, and in some cell types, particularly of hemopoietic origin, store-operated influx occurs through Ca2+ release-activated Ca2+ (CRAC) channels. However, little is known about the downstream consequences of CRAC channel activation. Here, we report that Ca2+ entry through CRAC channels stimulates arachidonic acid production, whereas Ca2+ release from the stores is ineffective even though the latter evokes a robust intracellular Ca2+ signal. We find that arachidonic acid released by Ca2+ entering through CRAC channels is used to synthesize the potent paracrine proinflammatory signal leukotriene C4 (LTC4). Both pharmacological inhibitors of CRAC channels and mitochondrial depolarization, which impairs CRAC channel activity, suppress arachidonic acid release and LTC4 secretion. Thus, arachidonic acid release is preferentially stimulated by elevated subplasmalemmal Ca2+ levels due to open CRAC channels, suggesting that the enzyme is located close to the CRAC channels. Our results also identify a novel role for CRAC channels, namely the activation of a downstream signal transduction pathway resulting in the secretion of LTC4. Finally, mitochondria are key determinants of the generation of both intracellular (arachidonic acid) and paracrine (LTC4) signals through their effects on CRAC channel activity.     

Regulation of CRAC channels by Ca2+-dependent inactivation

CRAC channels are a major route for Ca²⁺ influx in eukaryotic cells. The channels show prominent Ca²⁺-dependent inactivation through two spatially and temporally distinct mechanisms: fast inactivation, which develops over milliseconds and is triggered by Ca²⁺ near the mouth of the channel and slow inactivation, which arises over tens of seconds and requires a rise in global cytosolic Ca²⁺. Slow inactivation is controlled physiologically by Ca²⁺ uptake into mitochondria through the MCU. Site-directed mutagenesis studies on STIM1 and Orai1 have led to new molecular insight into how fast inactivation occurs. This review describes properties and molecular mechanisms that contribute to these important Ca²⁺-dependent inhibitory pathways.     

Local Ca2+ influx through Ca2+ release-activated Ca2+ (CRAC) channels stimulates production of an intracellular messenger and an intercellular pro-inflammatory signal

Ca2+ entry through store-operated Ca2+ channels drives the production of the pro-inflammatory molecule leukotriene C4 (LTC4) from mast cells through a pathway involving Ca2+-dependent protein kinase C, mitogen-activated protein kinases ERK1/2, phospholipase A2, and 5-lipoxygenase. Here we examine whether local Ca2+ influx through store-operated Ca2+ release-activated Ca2+ (CRAC) channels in the plasma membrane stimulates this signaling pathway. Manipulating the amplitude and spatial extent of Ca2+ entry by altering chemical and electrical gradients for Ca2+ influx or changing the Ca2+ buffering of the cytoplasm all impacted on protein kinase C and ERK activation, generation of arachidonic acid and LTC4 secretion, with little change in the bulk cytoplasmic Ca2+ rise. Similar bulk cytoplasmic Ca2+ concentrations were achieved when CRAC channels were activated in 0.25 mm external Ca2+ versus 2 mm Ca2+ and 100 nm La3+, an inhibitor of CRAC channels. However, despite similar bulk cytoplasmic Ca2+, protein kinase C activation and LTC4 secretion were larger in 2 mm Ca2+ and La3+ than in 0.25 mm Ca2+, consistent with the central involvement of a subplasmalemmal Ca2+ rise. The nonreceptor tyrosine kinase Syk coupled CRAC channel opening to protein kinase C and ERK activation. Recombinant TRPC3 channels also activated protein kinase C, suggesting that subplasmalemmal Ca2+ rather than a microdomain exclusive to CRAC channels is the trigger. Hence a subplasmalemmal Ca2+ increase in mast cells is highly versatile in that it triggers cytoplasmic responses through generation of intracellular messengers as well as long distance changes through increased secretion of paracrine signals.     

Sustained activation of the tyrosine kinase Syk by antigen in mast cells requires local Ca2+ influx through Ca2+ release-activated Ca2+ channels

Mast cell activation involves cross-linking of IgE receptors followed by phosphorylation of the non-receptor tyrosine kinase Syk. This results in activation of the plasma membrane-bound enzyme phospholipase Cgamma1, which hydrolyzes the minor membrane phospholipid phosphatidylinositol 4,5-bisphosphate to generate diacylglycerol and inositol trisphosphate. Inositol trisphosphate raises cytoplasmic Ca2+ concentration by releasing Ca2+ from intracellular stores. This Ca2+ release phase is accompanied by sustained Ca2+ influx through store-operated Ca2+ release-activated Ca2+ (CRAC) channels. Here, we find that engagement of IgE receptors activates Syk, and this leads to Ca2+ release from stores followed by Ca2+ influx. The Ca2+ influx phase then sustains Syk activity. The Ca2+ influx pathway activated by these receptors was identified as the CRAC channel, because pharmacological block of the channels with either a low concentration of Gd3+ or exposure to the novel CRAC channel blocker 3-fluoropyridine-4-carboxylic acid (2',5'-dimethoxybiphenyl-4-yl)amide or RNA interference knockdown of Orai1, which encodes the CRAC channel pore, all prevented the increase in Syk activity triggered by Ca2+ entry. CRAC channels and Syk are spatially close together, because increasing cytoplasmic Ca2+ buffering with the fast Ca2+ chelator 1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid tetrakis failed to prevent activation of Syk by Ca2+ entry. Our results reveal a positive feedback step in mast cell activation where receptor-triggered Syk activation and subsequent Ca2+ release opens CRAC channels, and the ensuing local Ca2+ entry then maintains Syk activity. Ca2+ entry through CRAC channels therefore provides a means whereby the Ca2+ and tyrosine kinase signaling pathways can interact with one another.     

Endogenous and exogenous Ca2+ buffers differentially modulate Ca2+-dependent inactivation of Ca(v)2.1 Ca2+ channels

Voltage-gated Ca2+ channels undergo a negative feedback regulation by Ca2+ ions, Ca2+-dependent inactivation, which is important for restricting Ca2+ signals in nerve and muscle. Although the molecular details underlying Ca2+-dependent inactivation have been characterized, little is known about how this process might be modulated in excitable cells. Based on previous findings that Ca2+-dependent inactivation of Ca(v)2.1 (P/Q-type) Ca2+ channels is suppressed by strong cytoplasmic Ca2+ buffering, we investigated how factors that regulate cellular Ca2+ levels affect inactivation of Ca(v)2.1 Ca2+ currents in transfected 293T cells. We found that inactivation of Ca(v)2.1 Ca2+ currents increased exponentially with current amplitude with low intracellular concentrations of the slow buffer EGTA (0.5 mm), but not with high concentrations of the fast Ca2+ buffer BAPTA (10 mm). However, when the concentration of BAPTA was reduced to 0.5 mm, inactivation of Ca2+ currents was significantly greater than with an equivalent concentration of EGTA, indicating the importance of buffer kinetics in modulating Ca2+-dependent inactivation of Ca(v)2.1. Cotransfection of Ca(v)2.1 with the EF-hand Ca2+-binding proteins, parvalbumin and calbindin, significantly altered the relationship between Ca2+ current amplitude and inactivation in ways that were unexpected from behavior as passive Ca2+ buffers. We conclude that Ca2+-dependent inactivation of Ca(v)2.1 depends on a subplasmalemmal Ca2+ microdomain that is affected by the amplitude of the Ca2+ current and differentially modulated by distinct Ca2+ buffers.     

Automated patch-clamp technique: increased throughput in functional characterization and in pharmacological screening of small-conductance Ca2+ release-activated Ca2+ channels

The suitability of an automated patch clamp for the characterization and pharmacological screening of calcium release-activated calcium (CRAC) channels endogenously expressed in RBL-2H3 cells was explored with the QPatch system. CRAC currents (I( CRAC)) are small, and thus precise recordings require high signal-to-noise ratios obtained by high seal resistances. Automated whole-cell establishment resulted in membrane resistances of 1728 +/- 226 MOmega (n = 44). CRAC channels were activated by a number of methods that raise intracellular calcium concentration, including EGTA, ionomycin, Ins(1,4,5)P(3), and thapsigargin. I(CRAC) whole-cell currents ranged from 30 to 120 pA with rise times of 40 to 150 s. An initial delay in current activation was observed in particular when I(CRAC) was activated by passive store depletion using EGTA. Apparent rundown of I(CRAC) was commonly observed, and the current could be reactivated by subsequent addition of thapsigargin. I(CRAC) was blocked by SKF-96365 and 2-APB with IC(50) values of 4.7 +/- 1.1 microM (n = 9) and 7.5 +/- 0.7 (n = 9) microM, respectively. The potencies of these blockers were similar to values reported for I(CRAC) in similar conventional patch-clamp experiments. The study demonstrates that CRAC channels can be rapidly and efficiently targeted with automated patch-clamp techniques for characterization of physiological and pharmacological properties.     

Dynamics of Ca2+-calmodulin-dependent inhibition of rod cyclic nucleotide-gated channels measured by patch-clamp fluorometry

Cyclic nucleotide-gated (CNG) ion channels mediate cellular responses to sensory stimuli. In vertebrate photoreceptors, CNG channels respond to the light-induced decrease in cGMP by closing an ion-conducting pore that is permeable to cations, including Ca(2+) ions. Rod CNG channels are directly inhibited by Ca(2+)-calmodulin (Ca(2+)/CaM), but the physiological role of this modulation is unknown. Native rod CNG channels comprise three CNGA1 subunits and one CNGB1 subunit. The single CNGB1 subunit confers several key properties on heteromeric channels, including Ca(2+)/CaM-dependent modulation. The molecular basis for Ca(2+)/CaM inhibition of rod CNG channels has been proposed to involve the binding of Ca(2+)/CaM to a site in the NH(2)-terminal region of the CNGB1 subunit, which disrupts an interaction between the NH(2)-terminal region of CNGB1 and the COOH-terminal region of CNGA1. Here, we test this mechanism for Ca(2+)/CaM-dependent inhibition of CNGA1/CNGB1 channels by simultaneously monitoring protein interactions with fluorescence spectroscopy and channel function with patch-clamp recording. Our results show that Ca(2+)/CaM binds directly to CNG channels, and that binding is the rate-limiting step for channel inhibition. Further, we show that the NH(2)- and COOH-terminal regions of CNGB1 and CNGA1 subunits, respectively, are in close proximity, and that Ca(2+)/CaM binding causes a relative rearrangement or separation of these regions. This motion occurs with the same time course as channel inhibition, consistent with the notion that rearrangement of the NH(2)- and COOH-terminal regions underlies Ca(2+)/CaM-dependent inhibition.     

Analysis of the modal hypothesis of Ca2+-dependent inactivation of L-type Ca2+ channels

A kinetic model of Ca2+-dependent inactivation (CDI) of L-type Ca2+ channels was developed. The model is based on the hypothesis that postulates the existence of four short-lived modes with lifetimes of a few hundreds of milliseconds. Our findings suggest that the transitions between the modes is primarily determined by the binding of Ca2+ to two intracellular allosteric sites located in different motifs of the CI region, which have greatly differing binding rates for Ca2+ (different k(on)). The slow-binding site is controlled by local Ca2+ near a single open channel that is consistent with the "domain" CDI model, and Ca2+ binding to the fast-binding site(s) depends on Ca2+ arising from distant sources that is consistent with the "shell" CDI model. The model helps to explain numerous experimental findings that are poorly understood so far.     

Calmodulin is the Ca2+ sensor for Ca2+ -dependent inactivation of L-type calcium channels

Elevated intracellular Ca2+ triggers inactivation of L-type calcium channels, providing negative Ca2+ feedback in many cells. Ca2+ binding to the main alpha1c channel subunit has been widely proposed to initiate such Ca2+ -dependent inactivation. Here, we find that overexpression of mutant, Ca2+ -insensitive calmodulin (CaM) ablates Ca2+ -dependent inactivation in a "dominant-negative" manner. This result demonstrates that CaM is the actual Ca2+ sensor for inactivation and suggests that CaM is constitutively tethered to the channel complex. Inactivation is likely to occur via Ca2+ -dependent interaction of tethered CaM with an IQ-like motif on the carboxyl tail of alpha1c. CaM also binds to analogous IQ regions of N-, P/Q-, and R-type calcium channels, suggesting that CaM-mediated effects may be widespread in the calcium channel family.