NTP,the photoproduct of nifedipine,activates caffeine-sensitive ion channels in leech neurons

Leech P neurons possess caffeine-sensitive ion channels in intracellular Ca(2+) stores and in the plasma membrane. The following results indicate that these channels are also activated by 2,6-dimethyl-4-(2-nitrosophenyl)-3,5-pyridinedicarboxylic acid dimethyl ester (NTP), the photoproduct of the L-type Ca(2+) channel-blocker nifedipine: (1) Just like caffeine, NTP evoked Ca(2+) influx and intracellular Ca(2+) release, as well as the influx of various other divalent cations and that of Na(+). (2) In the presence of high NTP or caffeine concentrations the plasma membrane channels close, suggesting desensitization of the channel-activating mechanism. (3) Depending on the concentration, NTP and caffeine induce cross-desensitization or act additively. (4) NTP was effective in the same neurons as caffeine (P, N, Leydig, 101), and it was ineffective in neurons in which caffeine was also ineffective (AP, T, L, 8, AE). (5) In Retzius neurons, NTP and caffeine evoked intracellular Ca(2+) release but no Ca(2+) influx. Despite these parallels, the effects of NTP and caffeine were not identical, which may be due to differences in the mechanisms of channel activation or desensitization and/or to substance-specific side effects. The caffeine-sensitive ion channels were activated by NTP concentrations > or =10 microM, which is almost three orders of magnitude smaller than the threshold concentration of caffeine.     

Activation of Ca(2+)-dependent currents in cultured rat dorsal root ganglion neurones by a sperm factor and cyclic ADP-ribose.

The effects of intracellular application of two novel Ca2+ releasing agents have been studied in cultured rat dorsal root ganglion (DRG) neurones by monitoring Ca(2+)-dependent currents as a physiological index of raised free cytosolic Ca2+ ([Ca2+]i). A protein based sperm factor (SF) extracted from mammalian sperm, has been found to trigger Ca2+ oscillations and to sensitize unfertilized mammalian eggs to calcium induced calcium release (CICR). In this study intracellular application of SF activated Ca(2+)-dependent currents in approximately two-thirds of DRG neurones. The SF induced activity was abolished by heat treatment, attenuated by increasing the intracellular Ca2+ buffering capacity of the cells and persisted when extracellular Ca2+ was replaced by Ba2+. In addition, activity could be triggered or potentiated by loading the cells with Ca2+ by activating a series of voltage-gated Ca2+ currents. Ca(2+)-activated inward current activity was also generated by intracellular application of cyclic ADP-ribose (cADPR), a metabolite of NAD+, which causes Ca2+ release in sea urchin eggs. This activity could also be enhanced by loading the cells with Ca2+. The cADPR induced activity, but not the SF induced activity, was abolished by depleting the caffeine sensitive Ca2+ store. Ruthenium red markedly attenuated SF induced activity but had little action on cADPR induced activity or caffeine induced activity. Our results indicate that both SF and cADPR release intracellular Ca2+ pools in DRG neurones and that they appear to act on subtly distinct stores or distinct intracellular Ca2+ release mechanisms, possibly by modulating CICR.     

Ion channels and regulation of intracellular calcium in vascular endothelial cells

Endothelial cells in vivo form an interface between flowing blood and vascular tissue, responding to humoral and physical stimuli to secrete relaxing and contracting factors that contribute to vascular homeostasis and tone. The activation of endothelial cell-surface receptors by vasoactive agents is coupled to an elevation in cytosolic Ca2+, which is caused by Ca2+ entry via ion channels in the plasma membrane and by Ca2+ release from intracellular stores. Ca2+ entry may occur via four different mechanisms: 1) a receptor-mediated channel coupled to second messengers; 2) a Ca2+ leak channel dependent on the electrochemical gradient for Ca2+; 3) a stretch-activated nonselective cation channel; and 4) internal Na+-dependent Ca2+ entry (Na+-Ca2+ exchange). The rate of Ca2+ entry through these ion pathways can be modulated by the resting membrane potential. Membrane potential may be regulated by at least two types of K channels: inwardly rectifying K channels activated upon hyperpolarization or shear stress; and a Ca2+-activated K channel activated upon depolarization, which may function to repolarize the agonist-stimulated endothelial cell. After agonist stimulation, cytosolic Ca2+ increases in a biphasic manner, with an initial peak due to inositol 1,4,5-trisphosphate-mediated Ca2+ release from intracellular stores, followed by a sustained plateau that is dependent on the presence of [Ca2+]o and on membrane potential. The delay in agonist-activated Ca2+ influx is consistent with the coupling of receptor activation to Ca2+ entry via a second messenger. Oscillations in [Ca2+]i, which may involve both Ca2+ entry and release, have been observed in isolated and confluent endothelial cell monolayers stimulated by histamine and bradykinin. Receptor-mediated Ca2+ entry, release, and refilling of intracellular stores follows a cycle that involves the plasma membrane.     

Simultaneous measurement of Ca2+ release and influx into smooth muscle cells in response to caffeine. A novel approach for calculating the fraction of current carried by calcium

Activation of ryanodine receptors on the sarcoplasmic reticulum of single smooth muscle cells from the stomach muscularis of Bufo marinus by caffeine is accompanied by a rise in cytoplasmic [Ca2+] ([Ca2+]i), and the opening of nonselective cationic plasma membrane channels. To understand how each of these pathways contributes to the rise in [Ca2+]i, one needs to separately monitor Ca2+ entry through them. Such information was obtained from simultaneous measurements of ionic currents and [Ca2+]i by the development of a novel and general method to assess the fraction of current induced by an agonist that is carried by Ca2+. Application of this method to the currents induced in these smooth muscle cells by caffeine revealed that approximately 20% of the current passing through the membrane channels activated following caffeine application is carried by Ca2+. Based on this information we found that while Ca2+ entry through these channels rises slowly, release of Ca2+ from stores, while starting at the same time, is much faster and briefer. Detailed quantitative analysis of the Ca2+ release from stores suggests that it most likely decays due to depletion of Ca2+ in those stores. When caffeine was applied twice to a cell with only a brief (30 s) interval in between, the amount of Ca2+ released from stores was markedly diminished following the second caffeine application whereas the current carried in part by Ca2+ entry across the plasma membrane was not significantly affected. These and other studies described in the preceding paper indicate that activation of the nonselective cation plasma membrane channels in response to caffeine was not caused as a consequence of emptying of internal Ca2+ stores. Rather, it is proposed that caffeine activates these membrane channels either by direct interaction or alternatively by a linkage between ryanodine receptors on the sarcoplasmic reticulum and the nonselective cation channels on the surface membrane.     

Calcium regulation of the short-term plasticity of the cholinoreceptors in neurons RPa3 and LPa3 of the edible snail]

Pharmacological influences, changing intracellular content of Ca2+, reversibly change the speed and depth of extinction of the input current of the Helix RPa3 and LPa3 neurones, elicited by a repeated iontophoretic application of acetylcholine to the soma. Suppression by extracellular medium, devoid of Ca2+ and by verapamyl (100-150 mumol/l) of Ca2+ input to the cell, induced by cholinoreceptors activation, reversibly weakens the extinction. Raise of intracellular Ca2+ level by blockade with ruthenium red (5-10 mumol/l) of specific Ca2+ transport by mitochondria and by mobilization with caffeine (1-4 mmol/l) of Ca2+, deposited by endoplasmic reticulum, accelerates and intensifies the extinction. The obtained results testify that the short-term cholinoreceptors plasticity of the above neurones is positively controlled by Ca2+ entering the cell by chemically controlled ion channels and mobilized from intracellular Ca-depot.     

Activation of AMPA/kainate receptors but not acetylcholine receptors causes Mg2+ influx into Retzius neurones of the leech Hirudo medicinalis

In Retzius neurones of the medicinal leech, Hirudo medicinalis, kainate activates ionotropic glutamate receptors classified as AMPA/kainate receptors. Activation of the AMPA/kainate receptor-coupled cation channels evokes a marked depolarization, intracellular acidification, and increases in the intracellular concentrations of Na+ ([Na+]i) and Ca2+. Qualitatively similar changes are observed upon the application of carbachol, an activator of acetylcholine receptor-coupled cation channels. Using multibarrelled ion-selective microelectrodes it was demonstrated that kainate, but not carbachol, caused additional increases in the intracellular free Mg2+ concentration ([Mg2+]i). Experiments were designed to investigate whether this kainate-induced [Mg2+]i increase was due to a direct Mg2+ influx through the AMPA/kainate receptor-coupled cation channels or a secondary effect due to the depolarization or the ionic changes. It was found that: (a) Similar [Mg2+]i increases were evoked by the application of glutamate or aspartate. (b) All kainate-induced effects were inhibited by the glutamatergic antagonist DNQX. (c) The magnitude of the [Mg2+]i increases depended on the extracellular Mg2+ concentration. (d) A reduction of the extracellular Ca2+ concentration increased kainate-induced [Mg2+]i increases, excluding possible Ca2+ interference at the Mg2+-selective microelectrode or at intracellular buffer sites. (e) Neither depolarizations evoked by the application of 30 mM K+, nor [Na+]i increases induced by the inhibition of the Na+/K+ ATPase caused comparable [Mg2+]i increases. (f) Inhibitors of voltage-dependent Ca2+ channels did not affect the kainate-induced [Mg2+]i increases. Moreover, previous experiments had already shown that intracellular acidification evoked by the application of 20 mM propionate did not cause changes in [Mg2+]i. The results indicate that kainate-induced [Mg2+]i increases in leech Retzius neurones are due to an influx of extracellular Mg2+ through the AMPA/kainate receptor-coupled cation channel. Mg2+ may thus act as an intracellular signal to distinguish between glutamatergic and cholinergic activation of leech Retzius neurones.     

Calcium sequestration in the liver: Review article

Hepatic parenchymal cells maintain intracellular total and cytosolic free Ca2+ levels by: entry of Ca2+ through channels, extrusion of Ca2+ by an outwardly directed Ca2+ pump, and controlled sequestration into intracellular pools. The mechanism of Ca2+ inflow is poorly characterized. The plasma membrane Ca2+ channels seem to share some of the characteristics of Ca2+ channels in excitable cells, but also differ from them. The outwardly directed plasma membrane Ca2(+)-ATPase is a calmodulin independent, P-type enzyme. Ca2+ uptake into the endoplasmic reticulum is due to the activity of a different Ca2(+)-ATPase, which is similar in molecular weight and shares antigenic determinants with the sarcoplasmic reticulum enzyme. In addition, mitochondria and nuclei also take up calcium. The exact mechanism by which Ca2+ is released from intracellular organelles is not well known. Several mechanisms for Ca2+ release from the endoplasmic reticulum were reported, including IP3 and GTP-induced. The most effective identified way of eliciting Ca2+ release from microsomal fraction is by the oxidation of critical -SH groups. This mechanism is likely to be involved in the rise of cytosolic Ca2+ observed in many situations of hepatocellular injury. In addition to being sequestered into subcellular organelles, some of the intracellular Ca2+ is bound to specific Ca2+ binding proteins. Both calmodulin and members of the annexin family were identified in the liver. Stimulation of the liver with gluconeogenic hormones results in increased Ca2+ entry into the cell, the release of Ca2+ from intracellular pools, and an oscillatory increase in free cytosolic Ca2+ levels. Extensive research is still needed for the elucidation of the exact mechanisms by which these events occur.     

Regulation of calcium influx across the plasma membrane of the human T-leukemic cell line, JURKAT: dependence on a rise in cytosolic free calcium can be dissociated from formation of inositol phosphates

A rise in the cytosolic free Ca2+ concentration due to both mobilization of Ca2+ from internal stores and influx of extracellular Ca2+ across the plasma membrane through 'second messenger-operated Ca2+ channels' is one of the first transmembrane signals detected following activation of CD2 or CD3 receptors on T-cells. In this study, we have further elucidated the regulation of these channels in the human T-leukemic cell line, JURKAT. Stimulation with either OKT3 or PHA induced a prompt influx of Ca2+ as assessed by MN2+ quenching of intracellular fura-2 fluorescence. When cytosolic free Ca2+ transient was partially buffered by loading the cells with BAPTA, neither agonist could induce Ca2+ entry into the cells as depicted by the lack of quenching of the fluorescence signal by Mn2+. This is in good agreement with our previous data on agonist-induced 45Ca2+ influx demonstrating that a rise in cytosolic free Ca2+ due to agonist-induced mobilization of Ca2+ from intracellular stores, could, directly or indirectly via the inositol cycle, initiate Ca2+ influx in these cells. Further support of this idea comes from the data demonstrating that agonist-induced mobilization of Ca2+ precedes the influx of Ca2+ across the plasma membrane. The present findings show that agonist-stimulation significantly increased the levels of Ins(1,4,5)P3 and Ins(1,3,4,5)P4 after only 5 s, indicating that one or both of these substances could play a role in the regulation of Ca2+ influx. However, when agonist-induced Mn2+ influx was totally abolished, by partially buffering the cytosolic free Ca2+ rise, the formation of Ins(1,4,5)P3 and Ins(1,3,4,5)P4 was not affected. Consequently, the dependence of an initial rise in cytosolic free Ca2+ for the subsequent regulation of Ca2+ influx across the plasma membrane, can be dissociated from the formation of both Ins(1,4,5)P3 and Ins(1,3,4,5)P4.     

Chromaffin-cell stimulation triggers fast millimolar mitochondrial Ca2+ transients that modulate secretion

Activation of calcium-ion (Ca2+) channels on the plasma membrane and on intracellular Ca2+ stores, such as the endoplasmic reticulum, generates local transient increases in the cytosolic Ca2+ concentration that induce Ca2+ uptake by neighbouring mitochondria. Here, by using mitochondrially targeted aequorin proteins with different Ca2+ affinities, we show that half of the chromaffin-cell mitochondria exhibit surprisingly rapid millimolar Ca2+ transients upon stimulation of cells with acetylcholine, caffeine or high concentrations of potassium ions. Our results show a tight functional coupling of voltage-dependent Ca2+ channels on the plasma membrane, ryanodine receptors on the endoplasmic reticulum, and mitochondria. Cell stimulation generates localized Ca2+ transients, with Ca2+ concentrations above 20-40 microM, at these functional units. Protonophores abolish mitochondrial Ca2+ uptake and increase stimulated secretion of catecholamines by three- to fivefold. These results indicate that mitochondria modulate secretion by controlling the availability of Ca2+ for exocytosis.     

K+-depolarization induces a direct release of Ca2+ from intracellular storage sites in cultured vascular smooth muscle cells from rat aorta

Using an intracellularly trapped dye, quin 2, effects of K+-depolarization on cytosolic free calcium concentrations were recorded microfluorometrically in rat aorta vascular smooth muscle cells in primary culture. When the cells were exposed to high extracellular K+ in Ca+-free media containing 2mM EGTA, there was a transient and dose-dependent elevation of cytosolic Ca2+ concentrations. However, the concentration of the cytosolic Ca2+ was not elevated when the intracellularly stored Ca2+ was depleted by the repetitive treatment with caffeine prior to the application of high K+. Thus depolarization of plasma membrane, per se, directly induces a release of Ca2+ from intracellular storage sites in vascular smooth muscle cells, and the main fraction of this released Ca2+ is derived from the caffeine sensitive storage sites; perhaps from the sarcoplasmic reticulum.     

Synergistic release of calcium in sea urchin eggs by caffeine and ryanodine.

A transient rise in intracellular Ca2+ during fertilization is necessary for activation of the quiescent sea urchin egg. Several mechanisms contribute to the rise in Ca2+ including influx across the egg plasma membrane and release from intracellular stores. The egg contains both IP3-sensitive and -insensitive Ca2+ release mechanisms and in this study we have used single-cell spectrofluorimetry to examine the effects of caffeine and ryanodine on Ca2+ release in eggs preloaded with fura 2. Caffeine induced a small Ca2+ release that was insensitive to heparin or ruthenium red. Ca2+ liberation by caffeine could be augmented by prior treatment with thapsigargin, an inhibitor of endoplasmic reticulum Ca2+ ATPase. Variable Ca2+ releases were observed in response to microinjection of ryanodine. The action of ryanodine appeared to be enhanced by prior injection of heparin and partially inhibited by ruthenium red. The release of Ca2+ by caffeine or ryanodine was generally insufficient to trigger cortical granule exocytosis, thus these eggs could be fertilized and a second Ca2+ release during fertilization was measured. Unlike the caffeine- and ryanodine-sensitive Ca(2+)-induced Ca2+ release mechanism in somatic cells, the graded responses in eggs suggested this caffeine- and ryanodine-sensitive release mechanism is not sensitive to sudden changes in Ca2+. Thus we could examine the combined actions of caffeine and ryanodine on Ca2+ release, which were synergistic. Caffeine treatment of ryanodine-injected eggs or ryanodine injection of caffeine-treated eggs stimulated a Ca2+ release significantly larger than the release by either drug independently. The experiments presented here suggest that sea urchin eggs liberate Ca2+ in response to caffeine and ryanodine; however, the regulation of this release differs from that described for caffeine- and ryanodine-sensitive Ca(2+)-induced Ca2+ release of somatic cells.     

Intracellular Ca2+ pools in PC12 cells. A unique, rapidly exchanging pool is sensitive to both inositol 1,4,5-trisphosphate and caffeine-ryanodine.

Release of Ca2+ from intracellular stores was studied in the parent PC12 cell line and in recently isolated clones sensitive or insensitive to caffeine. In the caffeine-sensitive cells the cytosolic free Ca2+ concentration ([Ca2+]i) responses by the xanthine drug and by stimulants of receptors coupled to inositol 1,4,5-trisphosphate (Ins-P3) generation (bradykinin, ATP) depend on separate pathways because 1) caffeine does not stimulate the hydrolysis of phosphatidylinositol 4,5-bisphosphate and 2) Ca(2+)-induced Ca2+ release, the process activated by caffeine, plays no major role in the Ins-P3-induced Ca2+ mobilization. Although distinct, these two mechanisms converge onto the same Ca2+ store. In fact 1) the [Ca2+]i responses by receptor agonists and caffeine were not additive; 2) either type of agent reduced (up to complete inhibition) the response to a subsequent administration of the same or the other agent; 3) all these responses were prevented by selective Ca2+ ATPase blockers; 4) ryanodine, which affects the intracellular Ca2+ channel sensitive to caffeine, also induced depletion of the receptor-sensitive Ca2+ pool; 5) in the 10 PC12 clones tested, sensitivity to caffeine paralleled ryanodine sensitivity. Therefore, PC12 cells, similar to some smooth muscle fibers but at variance with neurons and other secretory cells, express a single, rapidly exchanging Ca2+ store in which two distinct intracellular Ca2+ channels, i.e. the receptors for caffeine-ryanodine and Ins-P3, appear to be colocalized.     

Caffeine activates a Ca(2+)-permeable, nonselective cation channel in smooth muscle cells

The effects of caffeine on cytoplasmic [Ca2+] ([Ca2+]i) and plasma membrane currents were studied in single gastric smooth muscle cells dissociated from the toad, Bufo marinus. Experiments were carried out using Fura-2 for measuring [Ca2+]i and tight-seal voltage-clamp techniques for recording membrane currents. When the membrane potential was held at -80 mV, in 15% of the cells studied caffeine increased [Ca2+]i without having any effect on membrane currents. In these cells ryanodine completely abolished any caffeine induced increase in [Ca2+]i. In the other cells caffeine caused both an increase in [Ca2+]i and activation of an 80-pS nonselective cation channel. In this group of cells ryanodine only partially blocked the increase in [Ca2+]i induced by caffeine; moreover, the change in [Ca2+]i that did occur was tightly coupled to the time course and magnitude of the cation current through these channels. In the presence of ryanodine, blockade of the 80-pS channel by GdCl3 or decreasing the driving force for Ca2+ influx through the plasma membrane by holding the membrane potential at +60 mV almost completely blocked the increase in [Ca2+]i induced by caffeine. Thus, the channel activated by caffeine appears to be permeable to Ca2+. Caffeine activated the cation channel even when [Ca2+]i was clamped to below 10 nM when the patch pipette contained 10 mM BAPTA suggesting that caffeine directly activates the channel and that it is not being activated by the increase in Ca2+ that occurs when caffeine is applied to the cell. Corroborating this suggestion were additional results showing that when the membrane was depolarized to activate voltage-gated Ca2+ channels or when Ca2+ was released from carbachol- sensitive internal Ca2+ stores, the 80-pS channel was not activated. Moreover, caffeine was able to activate the channel in the presence of ryanodine at both positive and negative potentials, both conditions preventing release of Ca2+ from stores and the former preventing its influx. In summary, in gastric smooth muscle cells caffeine transiently releases Ca2+ from a ryanodine-sensitive internal store and also increases Ca2+ influx through the plasma membrane by activating an 80- pS cation channel by a mechanism which does not seem to involve an elevation of [Ca2+]i.     

Coactivation of capacitative calcium entry and L-type calcium channels in guinea pig gallbladder

We have evaluated the presence of capacitative Ca(2+) entry (CCE) in guinea pig gallbladder smooth muscle (GBSM), including a possible relation with activation of L-type Ca(2+) channels. Changes in cytosolic Ca(2+) concentration induced by Ca(2+) entry were assessed by digital microfluorometry in isolated, fura 2-loaded GBSM cells. Application of thapsigargin, a specific inhibitor of the Ca(2+) store pump, induced a transient Ca(2+) release followed by sustained entry of extracellular Ca(2+). Depletion of the stores with thapsigargin, cyclopiazonic acid, ryanodine and caffeine, high levels of the Ca(2+)-mobilizing hormone cholecystokinin octapeptide, or simple removal of external Ca(2+) resulted in a sustained increase in Ca(2+) entry on subsequent reapplication of Ca(2+). This entry was attenuated by 2-aminoethoxydiphenylborane, L-type Ca(2+) channel blockade, pinacidil, and Gd(3+). Accumulation of the voltage-sensitive dye 3,3'-dipentylcarbocyanine and direct intracellular recordings showed that depletion of the stores is sufficient for depolarization of the plasma membrane. Contractility studies in intact gallbladder muscle strips showed that CCE induced contractions. The CCE-evoked contraction was sensitive to 2-aminoethoxydiphenylborane, L-type Ca(2+) channel blockers, and Gd(3+). We conclude that, in GBSM, release of Ca(2+) from internal stores activates a CCE pathway and depolarizes plasma membrane, allowing coactivation of voltage-operated L-type Ca(2+) channels. This process may play a role in excitation-contraction coupling in GBSM.     

Neurotransmitters and Integration in Neuronal-Astroglial Networks

Two major neural cell types, glia, astrocytes in particular, and neurones can release chemical transmitters that act as soluble signalling compounds for intercellular communication. Exocytosis, a process which depends on an increase in cytosolic Ca²⁺ levels, represents a common denominator for release of neurotransmitters, stored in secretory vesicles, from these neural cells. While neurones rely predominately on the immediate entry of Ca²⁺ from the extracellular space to the cytosol in this process, astrocytes support their cytosolic Ca²⁺ increases by appropriating this ion from the intracellular endoplasmic reticulum store and extracellular space. Additionally, astrocytes can release neurotransmitters using a variety of non-vesicular pathways which are mediated by an assortment of plasmalemmal channels and transporters. Once a neuronal and/or astrocytic neurotransmitter is released into the extracellular space, it can activate plasma membrane neurotransmitter receptors on neural cells, causing autocrine and/or paracrine signalling. Moreover, chemical transmission is essential not only for homocellular, but also for heterocellular bi-directional communication in the brain. Further detailed understanding of chemical transmission will aid our comprehension of the brain (dys)function in heath and disease.     

Complete overlap of caffeine- and K+ depolarization-sensitive intracellular calcium storage site in cultured rat arterial smooth muscle cells

Changes in the concentration of cytosolic free calcium were recorded microfluorometrically in rat vascular smooth muscle cells in primary culture and loaded with quin-2. The effects of caffeine and high extracellular K+ on the release of calcium from the intracellular storage sites were determined. In the absence of extracellular calcium, both the depolarization of plasma membrane with excess extracellular K+ and the application of caffeine induced a transient and dose-dependent elevation of the cytosolic free calcium concentration, with durations of 4 and 2 min, respectively. Transient elevations of calcium repeatedly appeared in response to both repetitive depolarization (100 mM K+) and caffeine (10 mM) applications with progressive reductions in peak levels. In either case, the fifth or later treatments induced little or no rise in levels of the cytosolic calcium. The amount of released calcium induced by high K+ depolarization after (n-1) time applications (1 less than or equal to n less than or equal to 5) of caffeine was equal to that induced by the n-th application of caffeine. The amount of released calcium induced by caffeine after (n-1) time exposures (1 less than or equal to n less than or equal to 5) to K+ depolarization was equal to that observed during the n-th exposure to K+ depolarization. These results indicate that caffeine- and depolarization-sensitive intracellular calcium storage sites may be identical and that caffeine and K+, in optimal concentrations, will release an equal amount of calcium from the same storage site in cultured arterial smooth muscle cells, irrespective of the amount of stored calcium.     

Mitochondrial calcium and oxidative stress as mediators of ischemic brain injury

Acute ischemic and brain injury is triggered by excitotoxic elevation of intraneuronal Ca2+ followed by reoxygenation-dependent oxidative stress, metabolic failure, and cell death. Studies performed in vitro with neurons exposed to excitotoxic concentrations of glutamate demonstrate an initial rise in cytosolic [Ca2+], followed by a reduction to a normal, albeit slightly elevated concentration. This reduction in cytosolic [Ca2+] is due partially to active, respiration-dependent mitochondrial Ca2+ sequestration. Within minutes to an hour following the initial Ca2+ transient, most neurons undergo delayed Ca2+ deregulation characterized by a dramatic rise in cytosolic Ca2+. This prelethal secondary rise in Ca2+ is due to influx across the plasma membrane but is dependent on the initial mitochondrial Ca2+ uptake and associated oxidative stress. Mitochondrial Ca2+ uptake can stimulate the net production of reactive oxygen species (ROS) through activation of the membrane permeability transition, release of cytochrome c, respiratory inhibition, release of pyridine nucleotides, and loss of intramitochondrial glutathione necessary for detoxification of peroxides. Targets of mitochondrially derived ROS may include plasma membrane Ca2+ channels that mediate excitotoxic delayed Ca2+ deregulation.     

Extracellular Ca²+ alleviates NaCl-induced stomatal opening through a pathway involving H₂O₂-blocked Na+ influx in Vicia guard cells

To gain further insights into the function of extracellular Ca2+ in alleviating salt stress, Vicia faba guard cell protoplasts (GCPs) were patch-clamped in a whole-cell configuration. The results showed that 100 mM NaCl clearly induced Na+ influx across the plasma membrane in GCPs and promoted stomatal opening. Extracellular Ca2+ at 10 mM efficiently blocked Na+ influx and inhibited stomatal opening, which was partially abolished by La3+ (an inhibitor of plasma membrane Ca2+ channel) or catalase (CAT, a H?O? scavenger), respectively. These results suggest that the plasma membrane Ca2+ channels and H?O? possibly mediate extracellular Ca2+-blocked Na+ influx in GCPs. Furthermore, extracellular Ca2+ activated the plasma membrane Ca2+ channels under NaCl stress, which was partially abolished by CAT. These results, taken together, indicate that hydrogen peroxide (H?O?) likely regulates Na+ uptake by activating plasma membrane Ca2+ channels in GCPs. In accordance with this hypothesis, H?O? could mimic extracellular Ca2+ to activate Ca2+ channels and block Na+ influx in guard cells. A single-cell analysis of cytosolic free Ca2+ ([Ca2+](cyt)) using Fluo 3-AM revealed that extracellular Ca2+ induced the accumulation of cytosolic Ca2+ under NaCl stress, but had few effects on the accumulation of cytosolic Ca2+ under non-NaCl conditions. All of these results, together with our previous studies showing that extracellular Ca2+ induced the generation of H?O? in GCPs during NaCl stress, indicate that extracellular Ca2+ alleviates salt stress, likely by activating the H?O?-dependent plasma membrane Ca2+ channels, and the increase in cytosolic Ca2+ appears to block Na+ influx across the plasma membrane in Vicia guard cells, leading to stomatal closure and reduction of water loss.     

Caffeine-Sensitive Calcium Stores in Bovine Adrenal Chromaffin Cells

Caffeine was used to study the intracellular Ca2+ pools of bovine chromaffin cells. Its effects on cytosolic Ca2+ concentration ([Ca2+]i) were examined using fura-2. Caffeine caused a transient increase in [Ca2+]i in the presence or absence of extracellular Ca2+. In the former case, the caffeine-induced [Ca2+]i increase was higher and stayed above the basal value for several minutes. In the latter case, the [Ca2+]i rise was lower and fell to the basal level within 1 min. These results suggest that caffeine increases [Ca2+]i by causing both Ca2+ influx and Ca2+ release from intracellular pools. In the absence of extracellular Ca2+, ionomycin but not caffeine caused a further increase in [Ca2+]i in cells that had been treated with caffeine. Apparently there are at least two intracellular Ca2+ pools, only one of which is sensitive to caffeine. The caffeine-induced [Ca2+]i rise became smaller when the cells were pretreated with the inositol trisphosphate-generating agonists, methacholine and bradykinin. In addition, methacholine was unable to initiate a [Ca2+]i transient after the cells had been treated with caffeine. The results indicate that the caffeine-sensitive Ca2+ pools overlap with the inositol trisphosphate-sensitive pool and that the size of the latter pool is smaller than that of the former. The caffeine-sensitive Ca2+ pools were refilled after high K+ treatment, which suggests that the caffeine-sensitive Ca2+ pools may be important in buffering the cytosolic Ca2+. The effect of caffeine on [Ca2+]i is not due to inhibition of phosphodiesterase. Our results support a Ca2+ entry model in which depletion of intracellular Ca2+ pools controls the rate of Ca2+ entry across the plasma membrane.