Calcium Homeostasis and Cone Signaling Are Regulated by Interactions between Calcium Stores and Plasma Membrane Ion Channels

Calcium is a messenger ion that controls all aspects of cone photoreceptor function, including synaptic release. The dynamic range of the cone output extends beyond the activation threshold for voltage-operated calcium entry, suggesting another calcium influx mechanism operates in cones hyperpolarized by light. We have used optical imaging and whole-cell voltage clamp to measure the contribution of store-operated Ca²⁺ entry (SOCE) to Ca²⁺ homeostasis and its role in regulation of neurotransmission at cone synapses. Mn²⁺ quenching of Fura-2 revealed sustained divalent cation entry in hyperpolarized cones. Ca²⁺ influx into cone inner segments was potentiated by hyperpolarization, facilitated by depletion of intracellular Ca²⁺ stores, unaffected by pharmacological manipulation of voltage-operated or cyclic nucleotide-gated Ca²⁺ channels and suppressed by lanthanides, 2-APB, MRS 1845 and SKF 96365. However, cation influx through store-operated channels crossed the threshold for activation of voltage-operated Ca²⁺ entry in a subset of cones, indicating that the operating range of inner segment signals is set by interactions between store- and voltage-operated Ca²⁺ channels. Exposure to MRS 1845 resulted in ∼40% reduction of light-evoked postsynaptic currents in photopic horizontal cells without affecting the light responses or voltage-operated Ca²⁺ currents in simultaneously recorded cones. The spatial pattern of store-operated calcium entry in cones matched immunolocalization of the store-operated sensor STIM1. These findings show that store-operated channels regulate spatial and temporal properties of Ca²⁺ homeostasis in vertebrate cones and demonstrate their role in generation of sustained excitatory signals across the first retinal synapse.     

The Skeletal L-type Ca2+ Current Is a Major Contributor to Excitation-coupled Ca2+ entry

The term excitation-coupled Ca²⁺ entry (ECCE) designates the entry of extracellular Ca²⁺ into skeletal muscle cells, which occurs in response to prolonged depolarization or pulse trains and depends on the presence of both the 1,4-dihydropyridine receptor (DHPR) in the plasma membrane and the type 1 ryanodine receptor in the sarcoplasmic reticulum (SR) membrane. The ECCE pathway is blocked by pharmacological agents that also block store-operated Ca²⁺ entry, is inhibited by dantrolene, is relatively insensitive to the DHP antagonist nifedipine (1 μM), and is permeable to Mn²⁺. Here, we have examined the effects of these agents on the L-type Ca²⁺ current conducted via the DHPR. We found that the nonspecific cation channel antagonists (2-APB, SKF 96356, La³⁺, and Gd³⁺) and dantrolene all inhibited the L-type Ca²⁺ current. In addition, complete (>97%) block of the L-type current required concentrations of nifedipine >10 μM. Like ECCE, the L-type Ca²⁺ channel displays permeability to Mn²⁺ in the absence of external Ca²⁺ and produces a Ca²⁺ current that persists during prolonged (∼10-second) depolarization. This current appears to contribute to the Ca²⁺ transient observed during prolonged KCl depolarization of intact myotubes because (1) the transients in normal myotubes decayed more rapidly in the absence of external Ca²⁺; (2) the transients in dysgenic myotubes expressing SkEIIIK (a DHPR α_1S pore mutant thought to conduct only monovalent cations) had a time course like that of normal myotubes in Ca²⁺-free solution and were unaffected by Ca²⁺ removal; and (3) after block of SR Ca²⁺ release by 200 μM ryanodine, normal myotubes still displayed a large Ca²⁺ transient, whereas no transient was detectable in SkEIIIK-expressing dysgenic myotubes. Collectively, these results indicate that the skeletal muscle L-type channel is a major contributor to the Ca²⁺ entry attributed to ECCE.     

Expression of TRPC3 in Chinese Hamster Ovary Cells Results in Calcium-activated Cation Currents Not Related to Store Depletion

TRPC3 (or Htrp3) is a human member of the trp family of Ca²⁺-permeable cation channels. Since expression of TRPC3 cDNA results in markedly enhanced Ca²⁺ influx in response to stimulation of membrane receptors linked to phospholipase C (Zhu, X., J. Meisheng, M. Peyton, G. Bouley, R. Hurst, E. Stefani, and L. Birnbaumer. 1996. Cell. 85:661–671), we tested whether TRPC3 might represent a Ca²⁺ entry pathway activated as a consequence of depletion of intracellular calcium stores. CHO cells expressing TRPC3 after intranuclear injection of cDNA coding for TRPC3 were identified by fluorescence from green fluorescent protein. Expression of TRPC3 produced cation currents with little selectivity for Ca²⁺ over Na⁺. These currents were constitutively active, not enhanced by depletion of calcium stores with inositol-1,4,5-trisphosphate or thapsigargin, and attenuated by strong intracellular Ca²⁺ buffering. Ionomycin led to profound increases of currents, but this effect was strictly dependent on the presence of extracellular Ca²⁺. Likewise, infusion of Ca²⁺ into cell through the patch pipette increased TRPC3 currents. Therefore, TRPC3 is stimulated by a Ca²⁺-dependent mechanism. Studies on TRPC3 in inside-out patches showed cation-selective channels with 60-pS conductance and short (<2 ms) mean open times. Application of ionomycin to cells increased channel activity in cell-attached patches. Increasing the Ca²⁺ concentration on the cytosolic side of inside-out patches (from 0 to 1 and 30 μM), however, failed to stimulate channel activity, even in the presence of calmodulin (0.2 μM). We conclude that TRPC3 codes for a Ca²⁺-permeable channel that supports Ca²⁺-induced Ca²⁺-entry but should not be considered store operated.     

Expression of nonstructural rotavirus protein NSP4 mimics Ca2+ homeostasis changes induced by rotavirus infection in cultured cells

Rotavirus infection modifies Ca²⁺ homeostasis, provoking an increase in Ca²⁺ permeation, the cytoplasmic Ca²⁺ concentration ([Ca²⁺]_cyto), and total Ca²⁺ pools and a decrease in Ca²⁺ response to agonists. A glycosylated viral protein(s), NSP4 and/or VP7, may be responsible for these effects. HT29 or Cos-7 cells were infected by the SA11 clone 28 strain, in which VP7 is not glycosylated, or transiently transfected with plasmids coding for NSP4-enhanced green fluorescent protein (EGFP) or NSP4. The permeability of the plasma membrane to Ca²⁺ and the amount of Ca²⁺ sequestered in the endoplasmic reticulum released by carbachol or ATP were measured in fura-2-loaded cells at the single-cell level under a fluorescence microscope or in cell suspensions in a fluorimeter. Total cell Ca²⁺ pools were evaluated as ⁴⁵Ca²⁺ uptake. Infection with SA11 clone 28 induced an increase in Ca²⁺ permeability and ⁴⁵Ca²⁺ uptake similar to that found with the normally glycosylated SA11 strain. These effects were inhibited by tunicamycin, indicating that inhibition of glycosylation of a viral protein other than VP7 affects the changes of Ca²⁺ homeostasis induced by infection. Expression of NSP4-EGFP or NSP4 in transfected cells induced the same changes observed with rotavirus infection, whereas the expression of EGFP or EGFP-VP4 showed the behavior of uninfected and untransfected cells. Increased ⁴⁵Ca²⁺ uptake was also observed in cells expressing NSP4-EGFP or NSP4, as evidenced in rotavirus infection. These results indicate that glycosylated NSP4 is primarily responsible for altering the Ca²⁺ homeostasis of infected cells through an initial increase of cell membrane permeability to Ca²⁺.     

Hypoxia Activates a Ca2+-Permeable Cation Conductance Sensitive to Carbon Monoxide and to GsMTx-4 in Human and Mouse Sickle Erythrocytes

Background

Deoxygenation of sickle erythrocytes activates a cation permeability of unknown molecular identity (Psickle), leading to elevated intracellular [Ca²⁺] ([Ca²⁺]_i) and subsequent activation of K_Ca 3.1. The resulting erythrocyte volume decrease elevates intracellular hemoglobin S (HbSS) concentration, accelerates deoxygenation-induced HbSS polymerization, and increases the likelihood of cell sickling. Deoxygenation-induced currents sharing some properties of Psickle have been recorded from sickle erythrocytes in whole cell configuration.

Methodology/Principal Findings

We now show by cell-attached and nystatin-permeabilized patch clamp recording from sickle erythrocytes of mouse and human that deoxygenation reversibly activates a Ca²⁺- and cation-permeable conductance sensitive to inhibition by Grammastola spatulata mechanotoxin-4 (GsMTx-4; 1 µM), dipyridamole (100 µM), DIDS (100 µM), and carbon monoxide (25 ppm pretreatment). Deoxygenation also elevates sickle erythrocyte [Ca²⁺]_i, in a manner similarly inhibited by GsMTx-4 and by carbon monoxide. Normal human and mouse erythrocytes do not exhibit these responses to deoxygenation. Deoxygenation-induced elevation of [Ca²⁺]_i in mouse sickle erythrocytes did not require KCa3.1 activity.

Conclusions/Significance

The electrophysiological and fluorimetric data provide compelling evidence in sickle erythrocytes of mouse and human for a deoxygenation-induced, reversible, Ca²⁺-permeable cation conductance blocked by inhibition of HbSS polymerization and by an inhibitor of strctch-activated cation channels. This cation permeability pathway is likely an important source of intracellular Ca²⁺ for pathologic activation of KCa3.1 in sickle erythrocytes. Blockade of this pathway represents a novel therapeutic approach for treatment of sickle disease.     

A function for tyrosine phosphorylation of type 1 inositol 1,4,5-trisphosphate receptor in lymphocyte activation

Sustained elevation of intracellular calcium by Ca²⁺ release–activated Ca²⁺ channels is required for lymphocyte activation. Sustained Ca²⁺ entry requires endoplasmic reticulum (ER) Ca²⁺ depletion and prolonged activation of inositol 1,4,5-trisphosphate receptor (IP₃R)/Ca²⁺ release channels. However, a major isoform in lymphocyte ER, IP3R1, is inhibited by elevated levels of cytosolic Ca²⁺, and the mechanism that enables the prolonged activation of IP₃R1 required for lymphocyte activation is unclear. We show that IP₃R1 binds to the scaffolding protein linker of activated T cells and colocalizes with the T cell receptor during activation, resulting in persistent phosphorylation of IP₃R1 at Tyr353. This phosphorylation increases the sensitivity of the channel to activation by IP₃ and renders the channel less sensitive to Ca²⁺-induced inactivation. Expression of a mutant IP3R1-Y353F channel in lymphocytes causes defective Ca²⁺ signaling and decreased nuclear factor of activated T cells activation. Thus, tyrosine phosphorylation of IP3R1-Y353 may have an important function in maintaining elevated cytosolic Ca²⁺ levels during lymphocyte activation.     

Orai1 mutations alter ion permeation and Ca2+-dependent fast inactivation of CRAC channels: evidence for coupling of permeation and gating

Ca²⁺ entry through store-operated Ca²⁺ release-activated Ca²⁺ (CRAC) channels is an essential trigger for lymphocyte activation and proliferation. The recent identification of Orai1 as a key CRAC channel pore subunit paves the way for understanding the molecular basis of Ca²⁺ selectivity, ion permeation, and regulation of CRAC channels. Previous Orai1 mutagenesis studies have indicated that a set of conserved acidic amino acids in trans membrane domains I and III and in the I–II loop (E106, E190, D110, D112, D114) are essential for the CRAC channel's high Ca²⁺ selectivity. To further dissect the contribution of Orai1 domains important for ion permeation and channel gating, we examined the role of these conserved acidic residues on pore geometry, properties of Ca²⁺ block, and channel regulation by Ca²⁺. We find that alteration of the acidic residues lowers Ca²⁺ selectivity and results in striking increases in Cs⁺ permeation. This is likely the result of enlargement of the unusually narrow pore of the CRAC channel, thus relieving steric hindrance for Cs⁺ permeation. Ca²⁺ binding to the selectivity filter appears to be primarily affected by changes in the apparent on-rate, consistent with a rate-limiting barrier for Ca²⁺ binding. Unexpectedly, the mutations diminish Ca²⁺-mediated fast inactivation, a key mode of CRAC channel regulation. The decrease in fast inactivation in the mutant channels correlates with the decrease in Ca²⁺ selectivity, increase in Cs⁺ permeability, and enlargement of the pore. We propose that the structural elements involved in ion permeation overlap with those involved in the gating of CRAC channels.     

Strontium-Induced Repetitive Calcium Spikes in a Unicellular Green Alga

The divalent cation Sr²⁺ induced repetitive transient spikes of the cytosolic Ca²⁺ activity [Ca²⁺]_cy and parallel repetitive transient hyperpolarizations of the plasma membrane in the unicellular green alga Eremosphaera viridis. [Ca²⁺]_cy measurements, membrane potential measurements, and cation analysis of the cells were used to elucidate the mechanism of Sr²⁺-induced [Ca²⁺]_cy oscillations. Sr²⁺ was effectively and rapidly compartmentalized within the cell, probably into the vacuole. The [Ca²⁺]_cy oscillations cause membrane potential oscillations, and not the reverse. The endoplasmic reticulum (ER) Ca²⁺-ATPase blockers 2,5-di-tert-butylhydroquinone and cyclopiazonic acid inhibited Sr²⁺-induced repetitive [Ca²⁺]_cy spikes, whereas the compartmentalization of Sr²⁺ was not influenced. A repetitive Ca²⁺ release and Ca²⁺ re-uptake by the ER probably generated repetitive [Ca²⁺]_cy spikes in E. viridis in the presence of Sr²⁺. The inhibitory effect of ruthenium red and ryanodine indicated that the Sr²⁺-induced Ca²⁺ release from the ER was mediated by a ryanodine/cyclic ADP-ribose type of Ca²⁺ channel. The blockage of Sr²⁺-induced repetitive [Ca²⁺]_cy spikes by La³⁺ or Gd³⁺ indicated the necessity of a certain influx of divalent cations for sustained [Ca²⁺]_cy oscillations. Based on these data we present a mathematical model that describes the baseline spiking [Ca²⁺]_cy oscillations in E. viridis.     

Pharmacological Targeting of Native CatSper Channels Reveals a Required Role in Maintenance of Sperm Hyperactivation

The four sperm-specific CatSper ion channel proteins are required for hyperactivated motility and male fertility, and for Ca²⁺ entry evoked by alkaline depolarization. In the absence of external Ca²⁺, Na⁺ carries current through CatSper channels in voltage-clamped sperm. Here we show that CatSper channel activity can be monitored optically with the [Na⁺]_i-reporting probe SBFI in populations of intact sperm. Removal of external Ca²⁺ increases SBFI signals in wild-type but not CatSper2-null sperm. The rate of the indicated rise of [Na⁺]_i is greater for sperm alkalinized with NH₄Cl than for sperm acidified with propionic acid, reflecting the alkaline-promoted signature property of CatSper currents. In contrast, the [Na⁺]_i rise is slowed by candidate CatSper blocker HC-056456 (IC₅₀ ∼3 µM). HC-056456 similarly slows the rise of [Ca²⁺]_i that is evoked by alkaline depolarization and reported by fura-2. HC-056456 also selectively and reversibly decreased CatSper currents recorded from patch-clamped sperm. HC-056456 does not prevent activation of motility by HCO₃ ⁻ but does prevent the development of hyperactivated motility by capacitating incubations, thus producing a phenocopy of the CatSper-null sperm. When applied to hyperactivated sperm, HC-056456 causes a rapid, reversible loss of flagellar waveform asymmetry, similar to the loss that occurs when Ca²⁺ entry through the CatSper channel is terminated by removal of external Ca²⁺. Thus, open CatSper channels and entry of external Ca²⁺ through them sustains hyperactivated motility. These results indicate that pharmacological targeting of the CatSper channel may impose a selective late-stage block to fertility, and that high-throughput screening with an optical reporter of CatSper channel activity may identify additional selective blockers with potential for male-directed contraception.     

Mitochondrial Regulation of Store-operated Calcium Signaling in T Lymphocytes

Mitochondria act as potent buffers of intracellular Ca²⁺ in many cells, but a more active role in modulating the generation of Ca²⁺ signals is not well established. We have investigated the ability of mitochondria to modulate store-operated or “capacitative” Ca²⁺ entry in Jurkat leukemic T cells and human T lymphocytes using fluorescence imaging techniques. Depletion of the ER Ca²⁺ store with thapsigargin (TG) activates Ca²⁺ release-activated Ca²⁺ (CRAC) channels in T cells, and the ensuing influx of Ca²⁺ loads a TG- insensitive intracellular store that by several criteria appears to be mitochondria. Loading of this store is prevented by carbonyl cyanide m-chlorophenylhydrazone or by antimycin A1 + oligomycin, agents that are known to inhibit mitochondrial Ca²⁺ import by dissipating the mitochondrial membrane potential. Conversely, intracellular Na⁺ depletion, which inhibits Na⁺-dependent Ca²⁺ export from mitochondria, enhances store loading. In addition, we find that rhod-2 labels mitochondria in T cells, and it reports changes in Ca²⁺ levels that are consistent with its localization in the TG-insensitive store. Ca²⁺ uptake by the mitochondrial store is sensitive (threshold is <400 nM cytosolic Ca²⁺), rapid (detectable within 8 s), and does not readily saturate. The rate of mitochondrial Ca²⁺ uptake is sensitive to extracellular [Ca²⁺], indicating that mitochondria sense Ca²⁺ gradients near CRAC channels. Remarkably, mitochondrial uncouplers or Na⁺ depletion prevent the ability of T cells to maintain a high rate of capacitative Ca²⁺ entry over prolonged periods of >10 min. Under these conditions, the rate of Ca²⁺ influx in single cells undergoes abrupt transitions from a high influx to a low influx state. These results demonstrate that mitochondria not only buffer the Ca²⁺ that enters T cells via store-operated Ca²⁺ channels, but also play an active role in modulating the rate of capacitative Ca²⁺ entry.     

Modulation of the Local SR Ca2+ Release by Intracellular Mg2+ in Cardiac Myocytes

In cardiac muscle, Ca²⁺-induced Ca²⁺ release (CICR) from the sarcoplasmic reticulum (SR) defines the amplitude and time course of the Ca²⁺ transient. The global elevation of the intracellular Ca²⁺ concentration arises from the spatial and temporal summation of elementary Ca²⁺ release events, Ca²⁺ sparks. Ca²⁺ sparks represent the concerted opening of a group of ryanodine receptors (RYRs), which are under the control of several modulatory proteins and diffusible cytoplasmic factors (e.g., Ca²⁺, Mg²⁺, and ATP). Here, we examined by which mechanism the free intracellular Mg²⁺ ([Mg²⁺]_free) affects various Ca²⁺ spark parameters in permeabilized mouse ventricular myocytes, such as spark frequency, duration, rise time, and full width, at half magnitude and half maximal duration. Varying the levels of free ATP and Mg²⁺ in specifically designed solutions allowed us to separate the inhibition of RYRs by Mg²⁺ from the possible activation by ATP and Mg²⁺-ATP via the adenine binding site of the channel. Changes in [Mg²⁺]_free generally led to biphasic alterations of the Ca²⁺ spark frequency. For example, lowering [Mg²⁺]_free resulted in an abrupt increase of spark frequency, which slowly recovered toward the initial level, presumably as a result of SR Ca²⁺ depletion. Fitting the Ca²⁺ spark inhibition by [Mg²⁺]_free with a Hill equation revealed a K_i of 0.1 mM. In conclusion, our results support the notion that local Ca²⁺ release and Ca²⁺ sparks are modulated by Mg²⁺ in the intracellular environment. This seems to occur predominantly by hindering Ca²⁺-dependent activation of the RYRs through competitive Mg²⁺ occupancy of the high-affinity activation site of the channels. These findings help to characterize CICR in cardiac muscle under normal and pathological conditions, where the levels of Mg²⁺ and ATP can change.     

Calcium-dependent facilitation and graded deactivation of store-operated calcium entry in fetal skeletal muscle

Activation of store-operated Ca²⁺ entry (SOCE) into the cytoplasm requires retrograde signaling from the intracellular Ca²⁺ release machinery, a process that involves an intimate interaction between protein components on the intracellular and cell surface membranes. The cellular machinery that governs the Ca²⁺ movement in muscle cells is developmentally regulated, reflecting maturation of the junctional membrane structure as well as coordinated expression of related Ca²⁺ signaling molecules. Here we demonstrate the existence of SOCE in freshly isolated skeletal muscle cells obtained from embryonic days 15 and 16 of the mouse embryo, a critical stage of muscle development. SOCE in the fetal muscle deactivates incrementally with the uptake of Ca²⁺ into the sarcoplasmic reticulum (SR). A novel Ca²⁺-dependent facilitation of SOCE is observed in cells transiently exposed to high cytosolic Ca²⁺. Our data suggest that cytosolic Ca²⁺ can facilitate SOCE whereas SR luminal Ca²⁺ can deactivate SOCE in the fetal skeletal muscle. This cooperative mechanism of SOCE regulation by Ca²⁺ ions not only enables tight control of SOCE by the SR membrane, but also provides an efficient mechanism of extracellular Ca²⁺ entry in response to physiological demand. Such Ca²⁺ signaling mechanism would likely contribute to contraction and development of the fetal skeletal muscle.     

Mitochondrial Ca2+ Overload Underlies Aβ Oligomers Neurotoxicity Providing an Unexpected Mechanism of Neuroprotection by NSAIDs

Dysregulation of intracellular Ca²⁺ homeostasis may underlie amyloid β peptide (Aβ) toxicity in Alzheimer''s Disease (AD) but the mechanism is unknown. In search for this mechanism we found that Aβ_1–42 oligomers, the assembly state correlating best with cognitive decline in AD, but not Aβ fibrils, induce a massive entry of Ca²⁺ in neurons and promote mitochondrial Ca²⁺ overload as shown by bioluminescence imaging of targeted aequorin in individual neurons. Aβ oligomers induce also mitochondrial permeability transition, cytochrome c release, apoptosis and cell death. Mitochondrial depolarization prevents mitochondrial Ca²⁺ overload, cytochrome c release and cell death. In addition, we found that a series of non-steroidal anti-inflammatory drugs (NSAIDs) including salicylate, sulindac sulfide, indomethacin, ibuprofen and R-flurbiprofen depolarize mitochondria and inhibit mitochondrial Ca²⁺ overload, cytochrome c release and cell death induced by Aβ oligomers. Our results indicate that i) mitochondrial Ca²⁺ overload underlies the neurotoxicity induced by Aβ oligomers and ii) inhibition of mitochondrial Ca²⁺ overload provides a novel mechanism of neuroprotection by NSAIDs against Aβ oligomers and AD.     

TRPC1-mediated Ca2+ entry is essential for the regulation of hypoxia and nutrient depletion-dependent autophagy

Autophagy is a cellular catabolic process needed for the degradation and recycling of protein aggregates and damaged organelles. Although Ca²⁺ is suggested to have an important role in cell survival, the ion channel(s) involved in autophagy have not been identified. Here we demonstrate that increase in intracellular Ca²⁺ via transient receptor potential canonical channel-1 (TRPC1) regulates autophagy, thereby preventing cell death in two morphologically distinct cells lines. The addition of DMOG or DFO, a cell permeable hypoxia-mimetic agents, or serum starvation, induces autophagy in both epithelial and neuronal cells. The induction of autophagy increases Ca²⁺ entry via the TRPC1 channel, which was inhibited by the addition of 2APB and {"type":"entrez-protein","attrs":{"text":"SKF96365","term_id":"1156357400","term_text":"SKF96365"}}SKF96365. Importantly, TRPC1-mediated Ca²⁺ entry resulted in increased expression of autophagic markers that prevented cell death. Furthermore, hypoxia-mediated autophagy also increased TRPC1, but not STIM1 or Orai1, expression. Silencing of TRPC1 or inhibition of autophagy by 3-methyladenine, but not TRPC3, attenuated hypoxia-induced increase in intracellular Ca²⁺ influx, decreased autophagy, and increased cell death. Furthermore, the primary salivary gland cells isolated from mice exposed to hypoxic conditions also showed increased expression of TRPC1 as well as increase in Ca²⁺ entry along with increased expression of autophagic markers. Altogether, we provide evidence for the involvement of Ca²⁺ influx via TRPC1 in regulating autophagy to protect against cell death.Autophagy is a cellular process responsible for the delivery of proteins or organelles to lysosomes for its degradation. Autophagy participates not only in maintaining cellular homeostasis, but also promotes cell survival during cellular stress situations.^{1, 2} The stress conditions including nutrient starvation, hypoxia conditions, invading microbes, and tumor formation, have been shown to induce autophagy that allows cell survival in these stressful or pathological situations.¹ In addition, autophagy also recycles existing cytoplasmic components to generate the molecules that are required to sustain the most vital cellular functions.³ Till date, three forms of autophagy have been identified, which are designated as chaperone-mediated autophagy, microautophagy, and macroautophagy.⁴ Although the precise mechanism as to how autophagy is initiated is not well understood, many of the genes first identified in yeast that are involved in autophagy have orthologs in other eukaryotes including human homologs.^{5, 6} The presence of similar genes in all organisms suggests that autophagy might be a phenomenon that is evolutionally conserved that is essential for cell survival. In addition, since autophagy delivers a fresh pool of amino acids and other essential molecules to the cell, initiation of autophagy is highly beneficial particularly during nutritional stress situations or tissue remodeling during development and embryogenesis.⁶ Consequently, impaired or altered autophagy is often implicated in several pathologies, like neurodegenerative disorders and cancer,^{7, 8, 9} which again highlight its importance.Ca²⁺ has a vital role in the regulation of a large number of cellular processes such as cell proliferation, survival, migration, invasion, motility, and apoptosis.^{10, 11} To perform functions on such a broad spectrum, the cells have evolved multiple mechanisms regulating cellular Ca²⁺ levels, mainly by regulating the function of various Ca²⁺ channels present in different locations. Mitochondrial, ER, lysosomal, and cytosolic Ca²⁺ levels are regulated by Ca²⁺ permeable ion channels localized either on the membranes of the intracellular organelles or on the plasma membrane.¹⁰ The Ca²⁺ permeable channels, including families of TRPCs, Orais, voltage-gated, two-pore, mitochondrial Ca²⁺ uniporter, IP₃, and ryanodine receptors have all been identified to contribute towards changes in intracellular Ca²⁺ ([Ca²⁺]_i).^{10, 12, 13, 14} Channels of the TRPCs and Orai families have been related to several Ca²⁺-dependent physiological processes in various cell types, ranging from cell proliferation to contractility, to apoptosis under both physiological and pathological conditions.¹² Moreover, it has been suggested that intracellular Ca²⁺ is one of the key regulators of autophagy;¹⁵ however, the possible role of Ca²⁺ in autophagy is still inconclusive. Many reports also suggest that Ca²⁺ inhibits autophagy,^{16, 17, 18} whereas others have indicated a stimulatory role for Ca²⁺ towards autophagy.^{19, 20, 21} Furthermore, the identity of the major Ca²⁺ channel(s) involved in autophagy is not known. Members of the TRPC family have been suggested as mediators of Ca²⁺ entry into cells. Activation of the G-protein (G_q/11–PLC pathway) leads to the generation of second messenger IP₃.^{10, 22} IP₃ binds to the IP₃R, which initiates Ca²⁺ release from the ER stores, thereby facilitating stromal interacting molecule-1 (STIM1) to rearrange and activate Ca²⁺ entry via the store-operated channels.²² Two families of proteins (TRPCs and Orais) have been identified as potential candidates for SOC-mediated Ca²⁺ entry.^{12, 22} However, their role in autophagy has not yet been determined. Thus, here we investigated the role of Ca²⁺ entry channels (TRPCs and Orais) in autophagy and show that both hypoxia-mimetic and nutrient depression induces autophagy in two different cell lines. Furthermore, our data indicates that autophagy was dependent on TRPC1-mediated increase in intracellular Ca²⁺ levels, suggesting that TRPC1 has an important role in regulating autophagy and inhibiting cell death.     

Chloride channels are necessary for full platelet phosphatidylserine exposure and procoagulant activity

Platelets enhance thrombin generation at sites of vascular injury by exposing phosphatidylserine during necrosis-like cell death. Anoctamin 6 (Ano6) is required for Ca²⁺-dependent phosphatidylserine exposure and is defective in patients with Scott syndrome, a rare bleeding disorder. Ano6 may also form Cl⁻ channels, though the role of Cl⁻ fluxes in platelet procoagulant activity has not been explored. We found that Cl⁻ channel blockers or removal of extracellular Cl⁻ inhibited agonist-induced phosphatidylserine exposure. However, this was not due to direct inhibition of Ca²⁺-dependent scrambling since Ca²⁺ ionophore-induced phosphatidylserine exposure was normal. This implies that the role of Ano6 in Ca²⁺⁻dependent PS exposure is likely to differ from any putative function of Ano6 as a Cl⁻ channel. Instead, Cl⁻ channel blockade inhibited agonist-induced Ca²⁺ entry. Importantly, Cl⁻ channel blockers also prevented agonist-induced membrane hyperpolarization, resulting in depolarization. We propose that Cl⁻ entry through Cl⁻ channels is required for this hyperpolarization, maintaining the driving force for Ca²⁺ entry and triggering full phosphatidylserine exposure. This demonstrates a novel role for Cl⁻ channels in controlling platelet death and procoagulant activity.     

Local Membrane Deformations Activate Ca2+-Dependent K+ and Anionic Currents in Intact Human Red Blood Cells

Background

The mechanical, rheological and shape properties of red blood cells are determined by their cortical cytoskeleton, evolutionarily optimized to provide the dynamic deformability required for flow through capillaries much narrower than the cell''s diameter. The shear stress induced by such flow, as well as the local membrane deformations generated in certain pathological conditions, such as sickle cell anemia, have been shown to increase membrane permeability, based largely on experimentation with red cell suspensions. We attempted here the first measurements of membrane currents activated by a local and controlled membrane deformation in single red blood cells under on-cell patch clamp to define the nature of the stretch-activated currents.

Methodology/Principal Findings

The cell-attached configuration of the patch-clamp technique was used to allow recordings of single channel activity in intact red blood cells. Gigaohm seal formation was obtained with and without membrane deformation. Deformation was induced by the application of a negative pressure pulse of 10 mmHg for less than 5 s. Currents were only detected when the membrane was seen domed under negative pressure within the patch-pipette. K⁺ and Cl⁻ currents were strictly dependent on the presence of Ca²⁺. The Ca²⁺-dependent currents were transient, with typical decay half-times of about 5–10 min, suggesting the spontaneous inactivation of a stretch-activated Ca²⁺ permeability (PCa). These results indicate that local membrane deformations can transiently activate a Ca²⁺ permeability pathway leading to increased [Ca²⁺]_i, secondary activation of Ca²⁺-sensitive K⁺ channels (Gardos channel, IK1, KCa3.1), and hyperpolarization-induced anion currents.

Conclusions/Significance

The stretch-activated transient PCa observed here under local membrane deformation is a likely contributor to the Ca²⁺-mediated effects observed during the normal aging process of red blood cells, and to the increased Ca²⁺ content of red cells in certain hereditary anemias such as thalassemia and sickle cell anemia.     

Presynaptic External Calcium Signaling Involves the Calcium-Sensing Receptor in Neocortical Nerve Terminals

Background

Nerve terminal invasion by an axonal spike activates voltage-gated channels, triggering calcium entry, vesicle fusion, and release of neurotransmitter. Ion channels activated at the terminal shape the presynaptic spike and so regulate the magnitude and duration of calcium entry. Consequently characterization of the functional properties of ion channels at nerve terminals is crucial to understand the regulation of transmitter release. Direct recordings from small neocortical nerve terminals have revealed that external [Ca²⁺] ([Ca²⁺]_o) indirectly regulates a non-selective cation channel (NSCC) in neocortical nerve terminals via an unknown [Ca²⁺]_o sensor. Here, we identify the first component in a presynaptic calcium signaling pathway.

Methodology/Principal Findings

By combining genetic and pharmacological approaches with direct patch-clamp recordings from small acutely isolated neocortical nerve terminals we identify the extracellular calcium sensor. Our results show that the calcium-sensing receptor (CaSR), a previously identified G-protein coupled receptor that is the mainstay in serum calcium homeostasis, is the extracellular calcium sensor in these acutely dissociated nerve terminals. The NSCC currents from reduced function mutant CaSR mice were less sensitive to changes in [Ca²⁺]_o than wild-type. Calindol, an allosteric CaSR agonist, reduced NSCC currents in direct terminal recordings in a dose-dependent and reversible manner. In contrast, glutamate and GABA did not affect the NSCC currents.

Conclusions/Significance

Our experiments identify CaSR as the first component in the [Ca²⁺]_o sensor-NSCC signaling pathway in neocortical terminals. Decreases in [Ca²⁺]_o will depress synaptic transmission because of the exquisite sensitivity of transmitter release to [Ca²⁺]_o following its entry via voltage-activated Ca²⁺ channels. CaSR may detects such falls in [Ca²⁺]_o and increase action potential duration by increasing NSCC activity, thereby attenuating the impact of decreases in [Ca²⁺]_o on release probability. CaSR is positioned to detect the dynamic changes of [Ca²⁺]_o and provide presynaptic feedback that will alter brain excitability.     

Maintenance of Calcium Homeostasis in the Endoplasmic Reticulum by Bcl-2

The oncogene bcl-2 encodes a 26-kD protein localized to intracellular membranes, including the ER, mitochondria, and perinuclear membrane, but its mechanism of action is unknown. We have been investigating the hypothesis that Bcl-2 regulates the movement of calcium ions (Ca²⁺) through the ER membrane. Earlier findings in this laboratory indicated that Bcl-2 reduces Ca²⁺ efflux from the ER lumen in WEHI7.2 lymphoma cells treated with the Ca²⁺-ATPase inhibitor thapsigargin (TG) but does not prevent capacitative entry of extracellular calcium. In this report, we show that sustained elevation of cytosolic Ca²⁺ due to capacitative entry is not required for induction of apoptosis by TG, suggesting that ER calcium pool depletion may trigger apoptosis. Bcl-2 overexpression maintains Ca²⁺ uptake in the ER of TG-treated cells and prevents a TG-imposed delay in intralumenal processing of the endogenous glycoprotein cathepsin D. Also, Bcl-2 overexpression preserves the ER Ca²⁺ pool in untreated cells when extracellular Ca²⁺ is low. However, low extracellular Ca²⁺ reduces the antiapoptotic action of Bcl-2, suggesting that cytosolic Ca²⁺ elevation due to capacitative entry may be required for optimal ER pool filling and apoptosis inhibition by Bcl-2. In summary, the findings suggest that Bcl-2 maintains Ca²⁺ homeostasis within the ER, thereby inhibiting apoptosis induction by TG.     

Mitochondrial Participation in the Intracellular Ca2+ Network

Calcium can activate mitochondrial metabolism, and the possibility that mitochondrial Ca²⁺ uptake and extrusion modulate free cytosolic [Ca²⁺] (Ca_c) now has renewed interest. We use whole-cell and perforated patch clamp methods together with rapid local perfusion to introduce probes and inhibitors to rat chromaffin cells, to evoke Ca²⁺ entry, and to monitor Ca²⁺-activated currents that report near-surface [Ca²⁺]. We show that rapid recovery from elevations of Ca_c requires both the mitochondrial Ca²⁺ uniporter and the mitochondrial energization that drives Ca²⁺ uptake through it. Applying imaging and single-cell photometric methods, we find that the probe rhod-2 selectively localizes to mitochondria and uses its responses to quantify mitochondrial free [Ca²⁺] (Ca_m). The indicated resting Ca_m of 100–200 nM is similar to the resting Ca_c reported by the probes indo-1 and Calcium Green, or its dextran conjugate in the cytoplasm. Simultaneous monitoring of Ca_m and Ca_c at high temporal resolution shows that, although Ca_m increases less than Ca_c, mitochondrial sequestration of Ca²⁺ is fast and has high capacity. We find that mitochondrial Ca²⁺ uptake limits the rise and underlies the rapid decay of Ca_c excursions produced by Ca²⁺ entry or by mobilization of reticular stores. We also find that subsequent export of Ca²⁺ from mitochondria, seen as declining Ca_m, prolongs complete Ca_c recovery and that suppressing export of Ca²⁺, by inhibition of the mitochondrial Na⁺/ Ca²⁺ exchanger, reversibly hastens final recovery of Ca_c. We conclude that mitochondria are active participants in cellular Ca²⁺ signaling, whose unique role is determined by their ability to rapidly accumulate and then release large quantities of Ca²⁺.     

Luminal Mg2+, a key factor controlling RYR2-mediated Ca2+ release: cytoplasmic and luminal regulation modeled in a tetrameric channel

In cardiac muscle, intracellular Ca²⁺ and Mg²⁺ are potent regulators of calcium release from the sarcoplasmic reticulum (SR). It is well known that the free [Ca²⁺] in the SR ([Ca²⁺]_L) stimulates the Ca²⁺ release channels (ryanodine receptor [RYR]2). However, little is known about the action of luminal Mg²⁺, which has not been regarded as an important regulator of Ca²⁺ release.