A store-operated nonselective cation channel in lymphocytes is activated directly by Ca(2+) influx factor and diacylglycerol

Agonist-receptor interactions at the plasma membrane often lead to activation of store-operated channels (SOCs) in the plasma membrane, allowing for sustained Ca(2+) influx. While Ca(2+) influx is important for many biological processes, little is known about the types of SOCs, the nature of the depletion signal, or how the SOCs are activated. We recently showed that in addition to the Ca(2+) release-activated Ca(2+) (CRAC) channel, both Jurkat T cells and human peripheral blood mononuclear cells express novel store-operated nonselective cation channels that we termed Ca(2+) release-activated nonselective cation (CRANC) channels. Here we demonstrate that activation of both CRAC and CRANC channels is accelerated by a soluble Ca(2+) influx factor (CIF). In addition, CRANC channels in inside-out plasma membrane patches are directly activated upon exposure of their cytoplasmic side to highly purified CIF preparations. Furthermore, CRANC channels are also directly activated by diacylglycerol. These results strongly suggest that the Ca(2+) store-depletion signal is a diffusible molecule and that at least some SOCs may have dual activation mechanisms.     

Low cytoplasmic [Ca(2+)] activates I(CRAC) independently of global Ca(2+) store depletion in RBL-1 cells

Release of Ca(2+) from inositol (1,4,5)-trisphosphate-sensitive Ca(2+) stores causes "capacitative calcium entry," which is mediated by the so-called "Ca(2+) release-activated Ca(2+) current" (I(CRAC)) in RBL-1 cells. Refilling of the Ca(2+) stores or high cytoplasmic [Ca(2+)] ([Ca(2+)](cyt)) inactivate I(CRAC). Here we address the question if also [Ca(2+)](cyt) lower than the resting [Ca(2+)](cyt) influences store-operated channels. We therefore combined patch clamp and mag fura-2 fluorescence methods to determine simultaneously both I(CRAC) and [Ca(2+)] within Ca(2+) stores of RBL-1 cells ([Ca(2+)](store)). We found that low [Ca(2+)](cyt) in the range of 30-50 nM activates I(CRAC) and Ca(2+) influx spontaneously and independently of global Ca(2+) store depletion, while elevation of [Ca(2+)](cyt) to the resting [Ca(2+)](cyt) (100 nM) resulted in store dependence of I(CRAC) activation. We conclude that spontaneous activation of I(CRAC) by low [Ca(2+)](cyt) could serve as a feedback mechanism keeping the resting [Ca(2+)](cyt) constant.     

Dynamic simulation of the effect of calcium-release activated calcium channel on cytoplasmic Ca2+ oscillation

A mathematical model is proposed to illustrate the activation of STIM1 (stromal interaction molecule 1) protein, the assembly and activation of calcium-release activated calcium (CRAC) channels in T cells. In combination with De Young-Keizer-Li-Rinzel model, we successfully reproduce a sustained Ca(2+) oscillation in cytoplasm. Our results reveal that Ca(2+) oscillation dynamics in cytoplasm can be significantly affected by the way how the Orai1 CRAC channel are assembled and activated. A low sustained Ca(2+) influx is observed through the CRAC channels across the plasma membrane. In particular, our model shows that a tetrameric channel complex can effectively regulate the total quantity of the channels and the ratio of the active channels to the total channels, and a period of Ca(2+) oscillation about 29 s is in agreement with published experimental data. The bifurcation analyses illustrate the different dynamic properties between our mixed Ca(2+) feedback model and the single positive or negative feedback models.     

17 beta-estradiol increases Ca(2+) influx and down regulates interleukin-2 receptor in mouse thymocytes

The influx of Ca(2+) across the T lymphocyte membrane is an essential triggering signal for activation and proliferation by an antigen. The aim of this study was to determine if Ca(2+) influx through estradiol receptor (ER) operated channels of Ca(2+) entry induced activation of lymphoid cells. Mouse thymocytes were incubated with 17 beta-estradiol (E) and in the presence or absence of the mitogen, phytohemagglutinin (PHA). Despite evidence of an enhanced binding of E to ER on thymocyte membranes, and an E dose-related influx of Ca(2+), there was a consistent down regulation of IL-2 receptor expression (P < 0.001). Incubation of thymocytes with PHA enhanced IL-2 receptor expression although the down regulatory effect of E was still evident. The results suggest that the Ca(2+) channel activated by E may have a down regulatory effect on the IL-2 receptor in thymus cells leading to the dampening of cell activation process.     

Fundamental Ca2+ signaling mechanisms in mouse dendritic cells: CRAC is the major Ca2+ entry pathway

Although Ca(2+)-signaling processes are thought to underlie many dendritic cell (DC) functions, the Ca(2+) entry pathways are unknown. Therefore, we investigated Ca(2+)-signaling in mouse myeloid DC using Ca(2+) imaging and electrophysiological techniques. Neither Ca(2+) currents nor changes in intracellular Ca(2+) were detected following membrane depolarization, ruling out the presence of functional voltage-dependent Ca(2+) channels. ATP, a purinergic receptor ligand, and 1-4 dihydropyridines, previously suggested to activate a plasma membrane Ca(2+) channel in human myeloid DC, both elicited Ca(2+) rises in murine DC. However, in this study these responses were found to be due to mobilization from intracellular stores rather than by Ca(2+) entry. In contrast, Ca(2+) influx was activated by depletion of intracellular Ca(2+) stores with thapsigargin, or inositol trisphosphate. This Ca(2+) influx was enhanced by membrane hyperpolarization, inhibited by SKF 96365, and exhibited a cation permeability similar to the Ca(2+) release-activated Ca(2+) channel (CRAC) found in T lymphocytes. Furthermore, ATP, a putative DC chemotactic and maturation factor, induced a delayed Ca(2+) entry with a voltage dependence similar to CRAC. Moreover, the level of phenotypic DC maturation was correlated with the extracellular Ca(2+) concentration and enhanced by thapsigargin treatment. These results suggest that CRAC is a major pathway for Ca(2+) entry in mouse myeloid DC and support the proposal that CRAC participates in DC maturation and migration.     

Ca2+-independent phospholipase A2 is a novel determinant of store-operated Ca2+ entry

Store-operated cation (SOC) channels and capacitative Ca(2+) entry (CCE) play very important role in cellular function, but the mechanism of their activation remains one of the most intriguing and long lasting mysteries in the field of Ca(2+) signaling. Here, we present the first evidence that Ca(2+)-independent phospholipase A(2) (iPLA(2)) is a crucial molecular determinant in activation of SOC channels and store-operated Ca(2+) entry pathway. Using molecular, imaging, and electrophysiological techniques, we show that directed molecular or pharmacological impairment of the functional activity of iPLA(2) leads to irreversible inhibition of CCE mediated by nonselective SOC channels and by Ca(2+)-release-activated Ca(2+) (CRAC) channels. Transfection of vascular smooth muscle cells (SMC) with antisense, but not sense, oligonucleotides for iPLA(2) impaired thapsigargin (TG)-induced activation of iPLA(2) and TG-induced Ca(2+) and Mn(2+) influx. Identical inhibition of TG-induced Ca(2+) and Mn(2+) influx (but not Ca(2+) release) was observed in SMC, human platelets, and Jurkat T-lymphocytes when functional activity of iPLA(2) was inhibited by its mechanism-based suicidal substrate, bromoenol lactone (BEL). Moreover, irreversible inhibition of iPLA(2) impaired TG-induced activation of single nonselective SOC channels in SMC and BAPTA (1,2-bis(2-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid)-induced activation of whole-cell CRAC current in rat basophilic leukemia cells. Thus, functional iPLA(2) is required for activation of store-operated channels and capacitative Ca(2+) influx in wide variety of cell types.     

Hypoxia leads to Na,K-ATPase downregulation via Ca(2+) release-activated Ca(2+) channels and AMPK activation

To maintain cellular ATP levels, hypoxia leads to Na,K-ATPase inhibition in a process dependent on reactive oxygen species (ROS) and the activation of AMP-activated kinase α1 (AMPK-α1). We report here that during hypoxia AMPK activation does not require the liver kinase B1 (LKB1) but requires the release of Ca(2+) from the endoplasmic reticulum (ER) and redistribution of STIM1 to ER-plasma membrane junctions, leading to calcium entry via Ca(2+) release-activated Ca(2+) (CRAC) channels. This increase in intracellular Ca(2+) induces Ca(2+)/calmodulin-dependent kinase kinase β (CaMKKβ)-mediated AMPK activation and Na,K-ATPase downregulation. Also, in cells unable to generate mitochondrial ROS, hypoxia failed to increase intracellular Ca(2+) concentration while a STIM1 mutant rescued the AMPK activation, suggesting that ROS act upstream of Ca(2+) signaling. Furthermore, inhibition of CRAC channel function in rat lungs prevented the impairment of alveolar fluid reabsorption caused by hypoxia. These data suggest that during hypoxia, calcium entry via CRAC channels leads to AMPK activation, Na,K-ATPase downregulation, and alveolar epithelial dysfunction.     

Ca(2+) influx and opening of Ca(2+)-activated K(+) channels in muscle fibers from control and mdx mice

Using the patch-clamp technique, we demonstrate that, in depolarized cell-attached patches from mouse skeletal muscle fibers, a short hyperpolarization to resting value is followed by a transient activation of Ca(2+)-activated K(+) channels (K(Ca)) upon return to depolarized levels. These results indicate that sparse sites of passive Ca(2+) influx at resting potentials are responsible for a subsarcolemmal Ca(2+) load high enough to induce K(Ca) channel activation upon muscle activation. We then investigate this phenomenon in mdx dystrophin-deficient muscle fibers, in which an elevated Ca(2+) influx and a subsequent subsarcolemmal Ca(2+) overload are suspected. The number of Ca(2+) entry sites detected with K(Ca) was found to be greater in mdx muscle. K(Ca) activity reflecting subsarcolemmal Ca(2+) load was also found to be independent of the activity of leak channels carrying inward currents at negative potentials in mdx muscle. These results indicate that the sites of passive Ca(2+) influx newly described in this study could represent the Ca(2+) influx pathways responsible for the subsarcolemmal Ca(2+) overload in mdx muscle fibers.     

A new type of Ca(2+) channel blocker that targets Ca(2+) sensors and prevents Ca(2+)-mediated apoptosis.

Calmodulin (CaM), as well as other Ca(2+) binding motifs (i.e., EF hands), have been demonstrated to be Ca(2+) sensors for several ion channel types, usually resulting in an inactivation in a negative feedback manner. This provides a novel target for the regulation of such channels. We have designed peptides that interact with EF hands of CaM in a specific and productive manner. Here we have examined whether these peptides block certain Ca(2+)-permeant channels and inhibit biological activity that is dependent on the influx of Ca(2+). We found that these peptides are able to enter the cell and directly, as well as indirectly (through CaM), block the activity of glutamate receptor channels in cultured neocortical neurons and a nonselective cation channel in Jurkat T cells that is activated by HIV-1 gp120. As a consequence, apoptosis mediated by an influx of Ca(2+) through these channels was also dose-dependently inhibited by these novel peptides. Thus, this new type of Ca(2+) channel blocker may have utility in controlling apoptosis due to HIV infection or neuronal loss due to ischemia.     

Ca2+-calmodulin-dependent facilitation and Ca2+ inactivation of Ca2+ release-activated Ca2+ channels

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 store-operated influx occurs through Ca2+ release-activated Ca2+ (CRAC) channels. Here, we report that intracellular Ca2+ modulates CRAC channel activity through both positive and negative feedback steps in RBL-1 cells. Under conditions in which cytoplasmic Ca2+ concentration can fluctuate freely, we find that store-operated Ca2+ entry is impaired either following overexpression of a dominant negative calmodulin mutant or following whole-cell dialysis with a calmodulin inhibitory peptide. The peptide had no inhibitory effect when intracellular Ca2+ was buffered strongly at low levels. Hence, Ca2+-calmodulin is not required for the activation of CRAC channels per se but is an important regulator under physiological conditions. We also find that the plasma membrane Ca2+ATPase is the dominant Ca2+ efflux pathway in these cells. Although the activity of the Ca2+ pump is regulated by calmodulin, the store-operated Ca2+ entry is more sensitive to inhibition by the calmodulin mutant than by Ca2+ extrusion. Hence, these two plasmalemmal Ca2+ transport systems may differ in their sensitivities to endogenous calmodulin. Following the activation of Ca2+ entry, the rise in intracellular Ca2+ subsequently feeds back to further inhibit Ca2+ influx. This slow inactivation can be activated by a relatively brief Ca2+ influx (30-60 s); it reverses slowly and is not altered by overexpression of the calmodulin mutant. Hence, the same messenger, intracellular Ca2+, can both facilitate and inactivate Ca2+ entry through store-operated CRAC channels and through different mechanisms.     

Morphological changes of T cells following formation of the immunological synapse modulate intracellular calcium signals

Sustained Ca(2+) influx through plasma membrane Ca(2+) released-activated Ca(2+) (CRAC) channels is essential for T cell activation. Since inflowing Ca(2+) inactivates CRAC channels, T cell activation is only possible if Ca(2+)-dependent inactivation is prevented. We have previously reported that sustained Ca(2+) influx through CRAC channels requires both mitochondrial Ca(2+) uptake and mitochondrial translocation towards the plasma membrane in order to prevent Ca(2+)-dependent channel inactivation. Here, we show that morphological changes following formation of the immunological synapse (IS) modulate Ca(2+) influx through CRAC channels. Cell shape changes were dependent on the actin cytoskeleton, and they sustained Ca(2+) entry by bringing mitochondria and the plasma membrane in closer proximity. The increased percentage of mitochondria beneath the plasma membrane following shape changes occurred in all 3 dimensions and correlated with an increase in the amplitude of Ca(2+) signals. The shape change-dependent mitochondrial localization close to the plasma membrane prevented CRAC channel inactivation even in T cells in which dynein motor protein-dependent mitochondria movements towards the plasma membrane were completely abolished, highlighting the importance of the shape change-dependent control of Ca(2+) influx. Our results suggest that morphological changes do not only facilitate an efficient contact with antigen presenting cells but also strongly modulate Ca(2+) dependent T cell activation.     

New insights into the molecular mechanisms of store-operated Ca2+ signaling in T cells

The activation of Ca(2+) entry through store-operated channels by agonists that deplete Ca(2+) from the endoplasmic reticulum (ER) is an ubiquitous signaling mechanism, the molecular basis of which has remained elusive for the past 20 years. In T lymphocytes, store-operated Ca(2+)-release-activated Ca(2+) (CRAC) channels constitute the sole pathway for Ca(2+) entry following antigen-receptor engagement, and their function is essential for driving the program of gene expression that underlies T-cell activation by antigen. The first molecular components of this pathway have recently been identified: stromal interaction molecule 1 (STIM1), the ER Ca(2+) sensor, and Orai1, a pore-forming subunit of the CRAC channel. Recent work shows that CRAC channels are activated in a complex fashion that involves the co-clustering of STIM1 in junctional ER directly opposite Orai1 in the plasma membrane. These studies reveal an abundance of sites where Ca(2+) signaling might be controlled to modulate the activity of T cells during the immune response.     

Mitochondrial regulation of store-operated CRAC channels

In eukaryotic cells, one major route for Ca(2+) influx is through store-operated CRAC channels, which are activated following a fall in Ca(2+) content within the endoplasmic reticulum. Mitochondria are key regulators of this ubiquitous Ca(2+) influx pathway. Respiring mitochondria rapidly take up some of the Ca(2+) released from the stores, resulting in more extensive store depletion and thus robust activation of CRAC channels. As CRAC channels open, the ensuing rise in cytoplasmic Ca(2+) feeds back to inactivate the channels. By buffering some of the incoming Ca(2+) mitochondria reduce Ca(2+)-dependent inactivation of the CRAC channels, resulting in more prolonged Ca(2+) influx. However, mitochondria can release Ca(2+) close to the endoplasmic reticulum, accelerating store refilling and thus promoting deactivation of the CRAC channels. Mitochondria thus regulate all major transitions in CRAC channel gating, revealing remarkable versatility in how this organelle impacts upon Ca(2+) influx. Recent evidence suggests that mitochondria also control CRAC channels through mechanisms that are independent of their Ca(2+)-buffering actions and ability to generate ATP. Furthermore, pyruvic acid, a key intermediary metabolite and precursor substrate for the Krebs cycle, reduces the extent of Ca(2+)-dependent inactivation of CRAC channels. Hence mitochondrial metabolism impacts upon Ca(2+) influx through CRAC channels and thus on a range of key downstream cellular responses.     

Store depletion-activated CaT1 currents in rat basophilic leukemia mast cells are inhibited by 2-aminoethoxydiphenyl borate. Evidence for a regulatory component that controls activation of both CaT1 and CRAC (Ca(2+) release-activated Ca(2+) channel) channels

The intestinal Ca(2+) transport protein CaT1 encoded by TRPV6 has been reported (Yue, L., Peng, J. B., Hediger, M. A., and Clapham, D. E. (2001) Nature 410, 705-709) to be all or a part of the Ca(2+) release-activated Ca(2+) channel (CRAC). The major characteristic of CRAC is its activation following store depletion. We expressed CaT1 in HEK293 cells and rat basophilic leukemia (RBL) mast cells and measured whole-cell currents by the patch clamp technique. In HEK293 cells, the expression of CaT1 consistently yielded a constitutively active current, the size of which was strongly dependent on the holding potential and duration of voltage ramps. In CaT1-expressing RBL cells, the current was either activated by store depletion or was constitutively active at a higher current density. CaT1 currents could be clearly distinguished from endogenous CRAC by their typical current-voltage relationship in divalent free solution. 2-aminoethoxydiphenyl borate (2-APB), which is considered a blocker of CRAC, was tested for its inhibitory effect on both cell types expressing CaT1. Endogenous CRAC as well as store-dependent CaT1-derived currents of RBL cells were largely blocked by 75 microm 2-APB, whereas constitutively active CaT1 currents in both RBL and HEK293 cells were slightly potentiated. These results indicate that despite the difference in the permeation properties of CRAC and CaT1 channels, the latter are similarly able to form store depletion-activated conductances in RBL mast cells that are inhibited by 2-APB.     

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.