Identification of new functions of Ca2+ release from intracellular stores in central nervous system

Ca²⁺ release from intracellular stores regulates muscle contraction and a vast array of cell functions, but its role in the central nervous system (CNS) has not been completely elucidated. A new method of blocking IP₃ signaling by artificially expressing IP₃ 5-phosphatase has been used to clarify the functions of intracellular Ca²⁺ mobilization in CNS. Here I review two of such functions: the activity-dependent synaptic maintenance mechanism and the regulation of neuronal growth by spontaneous Ca²⁺ oscillations in astrocytes. These findings add new bases for better understanding CNS functions and suggest the presence of as yet unidentified neuronal and glial functions that are regulated by Ca²⁺ store-dependent Ca²⁺ signaling.     

Imaging of mitochondrial Ca2+ dynamics in astrocytes using cell-specific mitochondria-targeted GCaMP5G/6s: Mitochondrial Ca2+ uptake and cytosolic Ca2+ availability via the endoplasmic reticulum store

Mitochondrial Ca²⁺ plays a critical physiological role in cellular energy metabolism and signaling, and its overload contributes to various pathological conditions including neuronal apoptotic death in neurological diseases. Live cell mitochondrial Ca²⁺ imaging is an important approach to understand mitochondrial Ca²⁺ dynamics. Recently developed GCaMP genetically-encoded Ca²⁺ indicators provide unique opportunity for high sensitivity/resolution and cell type-specific mitochondrial Ca²⁺ imaging. In the current study, we implemented cell-specific mitochondrial targeting of GCaMP5G/6s (mito-GCaMP5G/6s) and used two-photon microscopy to image astrocytic and neuronal mitochondrial Ca²⁺ dynamics in culture, revealing Ca²⁺ uptake mechanism by these organelles in response to cell stimulation. Using these mitochondrial Ca²⁺ indicators, our results show that mitochondrial Ca²⁺ uptake in individual mitochondria in cultured astrocytes and neurons can be seen after stimulations by ATP and glutamate, respectively. We further studied the dependence of mitochondrial Ca²⁺ dynamics on cytosolic Ca²⁺ changes following ATP stimulation in cultured astrocytes by simultaneously imaging mitochondrial and cytosolic Ca²⁺ increase using mito-GCaMP5G and a synthetic organic Ca²⁺ indicator, x-Rhod-1, respectively. Combined with molecular intervention in Ca²⁺ signaling pathway, our results demonstrated that the mitochondrial Ca²⁺ uptake is tightly coupled with inositol 1,4,5-trisphosphate receptor-mediated Ca²⁺ release from the endoplasmic reticulum and the activation of G protein-coupled receptors. The current study provides a novel approach to image mitochondrial Ca²⁺ dynamics as well as Ca²⁺ interplay between the endoplasmic reticulum and mitochondria, which is relevant for neuronal and astrocytic functions in health and disease.     

A comparison of fluorescent Ca2+ indicators for imaging local Ca2+ signals in cultured cells

Localized subcellular changes in Ca²⁺ serve as important cellular signaling elements, regulating processes as diverse as neuronal excitability and gene expression. Studies of cellular Ca²⁺ signaling have been greatly facilitated by the availability of fluorescent Ca²⁺ indicators. The respective merits of different indicators to monitor bulk changes in cellular Ca²⁺ levels have been widely evaluated, but a comprehensive comparison for their use in detecting and analyzing local, subcellular Ca²⁺ signals is lacking. Here, we evaluated several fluorescent Ca²⁺ indicators in the context of local Ca²⁺ signals (puffs) evoked by inositol 1,4,5-trisphosphate (IP₃) in cultured human neuroblastoma SH-SY5Y cells, using high-speed video-microscopy. Altogether, nine synthetic Ca²⁺ dyes (Fluo-4, Fluo-8, Fluo-8 high affinity, Fluo-8 low affinity, Oregon Green BAPTA-1, Cal-520, Rhod-4, Asante Calcium Red, and X-Rhod-1) and three genetically-encoded Ca²⁺-indicators (GCaMP6-slow, -medium and -fast variants) were tested; criteria include the magnitude, kinetics, signal-to-noise ratio and detection efficiency of local Ca²⁺ puffs. Among these, we conclude that Cal-520 is the optimal indicator for detecting and faithfully tracking local events; that Rhod-4 is the red-emitting indicator of choice; and that none of the GCaMP6 variants are well suited for imaging subcellular Ca²⁺ signals.     

The luminal Ca2+ chelator,TPEN, inhibits NAADP-induced Ca2+ release

The regulation of Ca²⁺ release by luminal Ca²⁺ has been well studied for the ryanodine and IP₃ receptors but has been less clear for the NAADP-regulated channel. In view of conflicting reports, we have re-examined the issue by manipulating luminal Ca²⁺ with the membrane-permeant, low affinity Ca²⁺ buffer, TPEN, and monitoring NAADP-induced Ca²⁺ release in sea urchin egg homogenate. NAADP-induced Ca²⁺ release was almost entirely blocked by TPEN (IC₅₀ 17–25 μM) which suppressed the maximal extent of Ca²⁺ release without altering NAADP sensitivity. In contrast, Ca²⁺ release via IP₃ receptors was 3- to 30-fold less sensitive to TPEN whereas that evoked by ionomycin was essentially unaffected. The effect of TPEN on NAADP-induced Ca²⁺ release was not due to an increase in the luminal pH or chelation of trace metals since it could not be mimicked by NH₄Cl or phenanthroline. The fact that TPEN had no effect upon ionophore-induced Ca²⁺ release also argued against a substantial reduction in the driving force for Ca²⁺ efflux. We propose that, in the sea urchin egg, luminal Ca²⁺ is important for gating native NAADP-regulated two-pore channels.     

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.     

Effects of piperine and deoxyschizandrin on synchronized Ca2+ oscillations in cultured hippocampal neuronal cells

It has been reported that piperine (PIP) and deoxyschizandrin (DS) can modulate synchronized Ca²⁺ oscillations in cultured hippocampal neuronal networks. We investigated the modulation effects of four different combinations of piperine and deoxyschizandrin on synchronized Ca²⁺ oscillations in cultured hippocampal neuronal networks. The results showed that all four combinations (PIP:DS 4.9:1.9, 2.45:2.85, 7.35:0.95, and 2.45:0.95 mg/L) inhibit Ca²⁺ oscillation intensity to a similar extent. However, the first three combinations had strong inhibitory effects on the frequency of Ca²⁺ oscillations whereas the last combination (2.45:0.95 mg/L) only slightly enhanced the frequency of Ca²⁺ oscillations. We propose an improved Chay’s model to explain the mechanism of the effects of piperine and deoxyschizandrin on synchronized Ca²⁺ oscillations in cultured hippocampal neuronal cells. We concluded that deoxyschizandrin modulated synchronized Ca²⁺ oscillations in cultured hippocampal neuronal networks bidirectionally and the effect depended on concentration. Deoxyschizandrin reduced voltage-gated sodium channel conductance and ATP-sensitive potassium channel conductance, and affected the rate of exchange of intracellular calcium and the pump activity of Ca²⁺-ATPase in the endoplasmic reticulum (ER). Piperine reduced the activity of calcium release in the ER, and reduced the pump activity of calcium in the cytomembrane or enhanced the pump activity of Ca²⁺-ATPase in the ER.     

Molecular Dynamics of the Neuronal EF-Hand Ca2+-Sensor Caldendrin

Caldendrin, L- and S-CaBP1 are CaM-like Ca²⁺-sensors with different N-termini that arise from alternative splicing of the Caldendrin/CaBP1 gene and that appear to play an important role in neuronal Ca²⁺-signaling. In this paper we show that Caldendrin is abundantly present in brain while the shorter splice isoforms L- and S-CaBP1 are not detectable at the protein level. Caldendrin binds both Ca²⁺ and Mg²⁺ with a global K_d in the low µM range. Interestingly, the Mg²⁺-binding affinity is clearly higher than in S-CaBP1, suggesting that the extended N-terminus might influence Mg²⁺-binding of the first EF-hand. Further evidence for intra- and intermolecular interactions of Caldendrin came from gel-filtration, surface plasmon resonance, dynamic light scattering and FRET assays. Surprisingly, Caldendrin exhibits very little change in surface hydrophobicity and secondary as well as tertiary structure upon Ca²⁺-binding to Mg²⁺-saturated protein. Complex inter- and intramolecular interactions that are regulated by Ca²⁺-binding, high Mg²⁺- and low Ca²⁺-binding affinity, a rigid first EF-hand domain and little conformational change upon titration with Ca²⁺ of Mg²⁺-liganted protein suggest different modes of binding to target interactions as compared to classical neuronal Ca²⁺-sensors.     

Controlling the urge for a Ca2+ surge: all-or-none Ca2+ release in neurons

Changes in the intracellular calcium concentration ([Ca²⁺]_i) convey signals that are essential to the life and death of neurons. Ca²⁺-induced Ca²⁺-release (CICR), a process in which a modest elevation in [Ca²⁺]_i is amplified by a secondary release of Ca²⁺ from stores within the cell, plays a prominent role in shaping neuronal [Ca²⁺]_i signals. When CICR becomes regenerative, an explosive increase in [Ca²⁺]_i generates a Ca²⁺ wave that spreads throughout the cell. A discrete threshold controls activation of this all-or-none behavior and cellular context adjusts the threshold. Thus, the store acts as a switch that determines whether a given pattern of electrical activity will produce a local or global Ca²⁺ signal. This gatekeeper function seems to control some forms of Ca²⁺-triggered plasticity in neurons. BioEssays 21:743–750, 1999. © 1999 John Wiley & Sons, Inc.     

Calcineurin Mediates Synaptic Scaling Via Synaptic Trafficking of Ca2+-Permeable AMPA Receptors

Homeostatic synaptic plasticity is a negative-feedback mechanism for compensating excessive excitation or inhibition of neuronal activity. When neuronal activity is chronically suppressed, neurons increase synaptic strength across all affected synapses via synaptic scaling. One mechanism for this change is alteration of synaptic AMPA receptor (AMPAR) accumulation. Although decreased intracellular Ca²⁺ levels caused by chronic inhibition of neuronal activity are believed to be an important trigger of synaptic scaling, the mechanism of Ca²⁺-mediated AMPAR-dependent synaptic scaling is not yet understood. Here, we use dissociated mouse cortical neurons and employ Ca²⁺ imaging, electrophysiological, cell biological, and biochemical approaches to describe a novel mechanism in which homeostasis of Ca²⁺ signaling modulates activity deprivation-induced synaptic scaling by three steps: (1) suppression of neuronal activity decreases somatic Ca²⁺ signals; (2) reduced activity of calcineurin, a Ca²⁺-dependent serine/threonine phosphatase, increases synaptic expression of Ca²⁺-permeable AMPARs (CPARs) by stabilizing GluA1 phosphorylation; and (3) Ca²⁺ influx via CPARs restores CREB phosphorylation as a homeostatic response by Ca²⁺-induced Ca²⁺ release from the ER. Therefore, we suggest that synaptic scaling not only maintains neuronal stability by increasing postsynaptic strength but also maintains nuclear Ca²⁺ signaling by synaptic expression of CPARs and ER Ca²⁺ propagation.     

Growth and nutrient composition of Ca2+ use efficient and Ca2+ use inefficient genotypes of tomato

The response of two tomato lines (Lycopersicon esculentum Mill. Ca²⁺ use efficient line 113 and Ca²⁺ use inefficient line 67) to a range of constant low Ca²⁺ concentrations was investigated in a sand culture system. Four Ca²⁺ concentrations were established and maintained throughout the experiment: 0.038, 0.75, 1.51 and 3.75 mM CaCl₂ on a constant background of 1.1 mM NaCl. Response to Ca²⁺ was determined by analysis of growth parameters and of shoot Ca²⁺, Na⁺, K⁺ and Cl⁻ concentrations. Differences in Ca²⁺ and K⁺ use efficiencies were expressed as the calcium utilization efficiency ratio, or CaER, and potassium utilization efficiency ratio, or KER, (mg of dry weight produced·mg⁻¹ of Ca²⁺ or K⁺ in plant). Dry weight production of line 113 was significantly higher than line 67, and was associated with a higher CaER and KER. The Ca²⁺ treatments differentially affected shoot Ca²⁺, Na⁺, Cl⁻ and K⁺ concentrations. As expected, shoot Ca²⁺ and Cl⁻ concentrations increased whereas Na⁺ concentration decreased with Ca²⁺ treatments. Line 113 had more than twice the amount of Na⁺ in shoot tissue than line 67. The K⁺ to Na⁺ ratio was twice as high in line 67 than in line 113. No evidence for higher soluble Ca²⁺ contributing to higher Ca²⁺ utilization was observed. The relationship between Ca²⁺ use efficiency and growth was not correlated with higher percentages of soluble Ca²⁺ in leaf tissue or with differences in root morphology. Differences in Ca²⁺ use efficiency alone could not explain the higher growth rate in line 113. This study demonstrated that the physiological factors involved in the genetic control of Ca²⁺ use efficiency should be assessed under a range of constant low Ca²⁺ concentrations in order to observe the physiological changes taking place. Thus, the use of Ca²⁺ deficient conditions are to be avoided as it may interfere with the expression of the physiological factors involved in Ca²⁺ use efficiency.     

Crystal Structures of Progressive Ca2+ Binding States of the Ca2+ Sensor Ca2+ Binding Domain 1 (CBD1) from the CALX Na+/Ca2+ Exchanger Reveal Incremental Conformational Transitions

Na⁺/Ca²⁺ exchangers (NCX) constitute a major Ca²⁺ export system that facilitates the re-establishment of cytosolic Ca²⁺ levels in many tissues. Ca²⁺ interactions at its Ca²⁺ binding domains (CBD1 and CBD2) are essential for the allosteric regulation of Na⁺/Ca²⁺ exchange activity. The structure of the Ca²⁺-bound form of CBD1, the primary Ca²⁺ sensor from canine NCX1, but not the Ca²⁺-free form, has been reported, although the molecular mechanism of Ca²⁺ regulation remains unclear. Here, we report crystal structures for three distinct Ca²⁺ binding states of CBD1 from CALX, a Na⁺/Ca²⁺ exchanger found in Drosophila sensory neurons. The fully Ca²⁺-bound CALX-CBD1 structure shows that four Ca²⁺ atoms bind at identical Ca²⁺ binding sites as those found in NCX1 and that the partial Ca²⁺ occupancy and apoform structures exhibit progressive conformational transitions, indicating incremental regulation of CALX exchange by successive Ca²⁺ binding at CBD1. The structures also predict that the primary Ca²⁺ pair plays the main role in triggering functional conformational changes. Confirming this prediction, mutagenesis of Glu⁴⁵⁵, which coordinates the primary Ca²⁺ pair, produces dramatic reductions of the regulatory Ca²⁺ affinity for exchange current, whereas mutagenesis of Glu⁵²⁰, which coordinates the secondary Ca²⁺ pair, has much smaller effects. Furthermore, our structures indicate that Ca²⁺ binding only enhances the stability of the Ca²⁺ binding site of CBD1 near the hinge region while the overall structure of CBD1 remains largely unaffected, implying that the Ca²⁺ regulatory function of CBD1, and possibly that for the entire NCX family, is mediated through domain interactions between CBD1 and the adjacent CBD2 at this hinge.     

Dynamic buffering of mitochondrial Ca2+ during Ca2+ uptake and Na+-induced Ca2+ release

In cardiac mitochondria, matrix free Ca²⁺ ([Ca²⁺]_m) is primarily regulated by Ca²⁺ uptake and release via the Ca²⁺ uniporter (CU) and Na⁺/Ca²⁺ exchanger (NCE) as well as by Ca²⁺ buffering. Although experimental and computational studies on the CU and NCE dynamics exist, it is not well understood how matrix Ca²⁺ buffering affects these dynamics under various Ca²⁺ uptake and release conditions, and whether this influences the stoichiometry of the NCE. To elucidate the role of matrix Ca²⁺ buffering on the uptake and release of Ca²⁺, we monitored Ca²⁺ dynamics in isolated mitochondria by measuring both the extra-matrix free [Ca²⁺] ([Ca²⁺]_e) and [Ca²⁺]_m. A detailed protocol was developed and freshly isolated mitochondria from guinea pig hearts were exposed to five different [CaCl₂] followed by ruthenium red and six different [NaCl]. By using the fluorescent probe indo-1, [Ca²⁺]_e and [Ca²⁺]_m were spectrofluorometrically quantified, and the stoichiometry of the NCE was determined. In addition, we measured NADH, membrane potential, matrix volume and matrix pH to monitor Ca²⁺-induced changes in mitochondrial bioenergetics. Our [Ca²⁺]_e and [Ca²⁺]_m measurements demonstrate that Ca²⁺ uptake and release do not show reciprocal Ca²⁺ dynamics in the extra-matrix and matrix compartments. This salient finding is likely caused by a dynamic Ca²⁺ buffering system in the matrix compartment. The Na⁺- induced Ca²⁺ release demonstrates an electrogenic exchange via the NCE by excluding an electroneutral exchange. Mitochondrial bioenergetics were only transiently affected by Ca²⁺ uptake in the presence of large amounts of CaCl₂, but not by Na⁺- induced Ca²⁺ release.     

Ca2+-Permeable Acid-sensing Ion Channels and Ischemic Brain Injury

Acidosis is a common feature of brain in acute neurological injury, particularly in ischemia where low pH has been assumed to play an important role in the pathological process. However, the cellular and molecular mechanisms underlying acidosis-induced injury remain unclear. Recent studies have demonstrated that activation of Ca²⁺-permeable acid-sensing ion channels (ASIC1a) is largely responsible for acidosis-mediated, glutamate receptor-independent, neuronal injury. In cultured mouse cortical neurons, lowering extracellular pH to the level commonly seen in ischemic brain activates amiloride-sensitive ASIC currents. In the majority of these neurons, ASICs are permeable to Ca²⁺, and an activation of these channels induces increases in the concentration of intracellular Ca²⁺ ([Ca²⁺]_i). Activation of ASICs with resultant [Ca²⁺]_i loading induces time-dependent neuronal injury occurring in the presence of the blockers for voltage-gated Ca²⁺ channels and the glutamate receptors. This acid-induced injury is, however, inhibited by the blockers of ASICs, and by reducing [Ca²⁺]_o. In focal ischemia, intracerebroventricular administration of ASIC1a blockers, or knockout of the ASIC1a gene protects brain from injury and does so more potently than glutamate antagonism. Furthermore, pharmacological blockade of ASICs has up to a 5 h therapeutic time window, far beyond that of glutamate antagonists. Thus, targeting the Ca²⁺-permeable acid-sensing ion channels may prove to be a novel neuroprotective strategy for stroke patients.     

Genetically Encoded Green Fluorescent Ca2+ Indicators with Improved Detectability for Neuronal Ca2+ Signals

Imaging the activities of individual neurons with genetically encoded Ca²⁺ indicators (GECIs) is a promising method for understanding neuronal network functions. Here, we report GECIs with improved neuronal Ca²⁺ signal detectability, termed G-CaMP6 and G-CaMP8. Compared to a series of existing G-CaMPs, G-CaMP6 showed fairly high sensitivity and rapid kinetics, both of which are suitable properties for detecting subtle and fast neuronal activities. G-CaMP8 showed a greater signal (F _max/F _min = 38) than G-CaMP6 and demonstrated kinetics similar to those of G-CaMP6. Both GECIs could detect individual spikes from pyramidal neurons of cultured hippocampal slices or acute cortical slices with 100% detection rates, demonstrating their superior performance to existing GECIs. Because G-CaMP6 showed a higher sensitivity and brighter baseline fluorescence than G-CaMP8 in a cellular environment, we applied G-CaMP6 for Ca²⁺ imaging of dendritic spines, the putative postsynaptic sites. By expressing a G-CaMP6-actin fusion protein for the spines in hippocampal CA3 pyramidal neurons and electrically stimulating the granule cells of the dentate gyrus, which innervate CA3 pyramidal neurons, we found that sub-threshold stimulation triggered small Ca²⁺ responses in a limited number of spines with a low response rate in active spines, whereas supra-threshold stimulation triggered large fluorescence responses in virtually all of the spines with a 100% activity rate.     

Effects of staurosporine on Ca2+-dependent and Ca2+-independent [14C]GABA release from rat brain synaptosomes

The effect of a protein kinase inhibitor, staurosporine, on Ca²⁺-dependent and Ca²⁺-independent release of [¹⁴C]GABA in isolated rat brain synaptosomes was studied. Calcium-dependent [¹⁴C]GABA release was stimulated by depolarization with a K⁺ channel blocker, 4-aminopyridine (4-AP), or high K⁺ concentration. It has been shown that the effect of 4-AP is Ca²⁺-dependent, while high K⁺ is able to evoke [¹⁴C]GABA release in both Ca²⁺-dependent and Ca²⁺-independent manners. In addition, Ca²⁺-independent [¹⁴C]GABA release was studied using α-latrotoxin (LTX) as a tool. Pretreatment of synaptosomes with staurosporine resulted in pronounced inhibition of 4-AP-stimulated Ca²⁺-dependent [¹⁴C]GABA release. The inhibitory effect of staurosporine on [¹⁴C]GABA release was not due to modulation of 4-AP-promoted⁴⁵Ca²⁺ influx into synaptosomes. If the process of [¹⁴C]GABA release occurred in the Ca²⁺-independent manner irrespectively of what, LTX or high K⁺, stimulated this process, it was not inhibited by staurosporine. Considering the above findings, it is reasonable to assume that the absence of Ca²⁺ in the extracellular medium created conditions for activation of the process of neurotransmitter release without Ca²⁺-dependent dephosphorylation of neuronal phosphoproteins; as a consequence, regulation of exocytotic process was modulated in such a manner that inhibition of protein kinases did not disturb exocytosis.     

Inactivation by Ca2+ of Ca2+-stimulated ATPase from rat red cells

Summary The effect of Ca²⁺ on the stability of the Ca²⁺-stimulated ATPase has been investigated. Our results showed that the preincubation of the rat red cell membranes in presence of Ca²⁺ causes an irreversible inhibition of the enzyme. The same effect was obtained with Ba²⁺ instead of Ca²⁺. Once initiated the inactivation of the enzyme could be halted by the addition of ethylene glycol bis (B-amino ethyl ether) N,N-tetra acitic acid (EGTA), but inactivation was irreversible. The presence of ATP in the preincubation with Ca²⁺ prevented the inactivation but calmodulin did not.     

Differentiation between Ca2+ transport and ATP-induced Ca2+ binding by sarcoplasmic reticulum

The Ca²⁺ actively accumulated by sarcoplasmic reticulum isolated from skeletal muscle is composed of two fractions; one represented by intravesicular free Ca²⁺ and another represented by Ca²⁺ selectively bound to the membranes. Both of these Ca²⁺ fractions depend on ATP, although it is not clear whether ATP hydrolysis is essential for accumulation of the second Ca²⁺ fraction. The existence of the membrane-bound Ca²⁺ induced by ATP is clearly shown in experiments in which the Ca²⁺ retention by sarcoplasmic reticulum is measured in the presence and in the absence of X-537A, a Ca²⁺ ionophore, which makes the membrane permeable to Ca²⁺. Thus, in the presence of X-537A all Ca²⁺ accumulated due to ATP is bound to the membranes. This membrane-bound Ca²⁺ represents about 30 nmol/mg protein in the range of external $\text{p}\text{Ca}$ values of 7 to 3.5. The magnitude of this Ca²⁺ fraction is slightly higher whether or not the experiments are performed in the presence of oxalate, which greatly increased the intravesicular Ca²⁺ accumulation. Furthermore, taking advantage of the impermeability of sarcoplasmic reticulum to EGTA, it is possible to show the existence of the membrane-bound Ca²⁺ as a distinct fraction from that which exists intravesicularly.     

Suppression of programmed neuronal death by a thapsigargin-induced Ca2+ influx

Rat sympathetic neurons undergo programmed cell death (PCD) in vitro and in vivo when they are deprived of nerve growth factor (NGF). Chronic depolarization of these neurons in cell culture with elevated concentrations of extracellular potassium ([K⁺]_o) prevents this death. The effect of prolonged depolarization on neuronal survival is thought to be mediated by a rise of intracellular calcium concentration ([Ca²⁺]_i) caused by Ca²⁺ influx through voltage-gated channels. In this report we investigate the effects of chronic treatment of rat sympathetic neurons with thapsigargin, an inhibitor of intracellular Ca²⁺ sequestration. In medium containing a normal concentration of extracellular Ca²⁺ ([Ca²⁺]_o), thapsigargin caused a sustained rise of intracellular Ca²⁺ concentration and partially blocked death of NGF-deprived cells. Elevating [Ca²⁺]_o in the presence of thapsigargin further increased [Ca²⁺]_i, suggesting that the sustained rise of [Ca²⁺]_i was caused by a thapsigargin-induced Ca²⁺ influx. This treatment potentiated the effect of thapsigargin on survival. The dihydropyridine Ca²⁺ channel antagonist, nifedipine, blocked both a sustained elevation of [Ca²⁺]_i and enhanced survival caused by depolarization with elevated [K⁺]_o, suggesting that these effects are mediated by Ca²⁺ influx through L-type channels. Nifedipine did not block the sustained rise of [Ca²⁺]_i or enhanced survival caused by thapsigargin treatment, indicating that these effects were not mediated by influx of Ca²⁺ through L-type channels. These results provide additional evidence that increased [Ca²⁺]_i can suppress neuronal PCD and identify a novel method for chronically raising neuronal [Ca²⁺]_i for investigation of this and other Ca²⁺-dependent phenomena. © 1995 John Wiley & Sons, Inc.