Sodium, calcium and exocytosis: confessions of calcified scientists.

Stimulated exocytotic secretion from nerve endings is initiated by an increase in intracellular free calcium concentration. We summarize here our latest findings regarding the temporal relationship between depolarization, elevation of [Ca2+]i and exocytosis in single vertebrate neuroendocrine nerve endings. In addition, we present surprising findings for a regulatory role of intracellular Na+ on exocytosis.     

Ca2+-Dependent Regulation of Presynaptic Stimulus-Secretion Coupling

In the present study, we have investigated the role of Ca2+ in the coupling of membrane depolarization to neurotransmitter secretion. We have measured (a) intracellular free Ca2+ concentration ([Ca2+]i) changes, (b) rapid 45Ca2+ uptake, and (c) Ca2+-dependent and -independent release of endogenous glutamate (Glu) and gamma-aminobutyric acid (GABA) as a function of stimulus intensity by elevating the extracellular [K+] to different levels in purified nerve terminals (synaptosomes) from rat hippocampus. During stimulation, Percoll-purified synaptosomes show an increased 45Ca2+ uptake, an elevated [Ca2+]i, and a Ca2+-dependent as well as a Ca2+-independent release of both Glu and GABA. With respect to both amino acids, synaptosomes respond on stimulation essentially in the same way, with maximally a fourfold increase in Ca2+-dependent (exocytotic) release. Ca2+-dependent transmitter release as well as [Ca2+]i elevations show maximal stimulation at moderate depolarizations (30 mM K+). A correlation exists between Ca2+-dependent release of both Glu and GABA and elevation of [Ca2+]i. Ca2+-dependent release is maximally stimulated with an elevation of [Ca2+]i of 60% above steady-state levels, corresponding with an intracellular concentration of approximately 400 nM, whereas elevations to 350 nM are ineffective in stimulating Ca2+-dependent release of both Glu and GABA. In contrast, Ca2+-independent release of both Glu and GABA shows roughly a linear rise with stimulus intensity up to 50 mM K+. 45Ca2+ uptake on stimulation also shows a continuous increase with stimulus intensity, although the relationship appears to be biphasic, with a plateau between 20 and 40 mM K+.(ABSTRACT TRUNCATED AT 250 WORDS)     

Kinetics of the secretory response in bovine chromaffin cells following flash photolysis of caged Ca2+.

The kinetics of the secretory response in bovine chromaffin cells following flash photolysis of caged Ca2+ were studied by capacitance (Cm) measurements with millisecond time resolution. After elevation of the internal Ca2+ concentration ([Ca2+]i), Cm rises rapidly with one or more exponentials. The time constant of the fastest component decreases for higher [Ca2+]i (range 3-600 microM) over three orders of magnitude before it saturates at approximately 1 ms. The corresponding maximal rates of secretion can be as fast as 100,000 fF/s or 40,000 vesicles/s. There is a Ca(2+)-dependent delay before Cm rises, which may reflect the kinetics of multiple Ca2+ ions binding to the secretory apparatus. The initial rise in Cm is described by models containing a sequence of two to four single Ca(2+)-binding steps followed by a rate-limiting exocytosis step. The predicted Ca2+ dissociation constant (Kd) of a single Ca(2+)-binding site is between 7 and 21 microM. At [Ca2+]i > 30 microM clear indications of a fast endocytotic process complicate the analysis of the secretory response.     

Early requirement for alpha-SNAP and NSF in the secretory cascade in chromaffin cells.

NSF and alpha-SNAP have been shown to be required for SNARE complex disassembly and exocytosis. However, the exact requirement for NSF and alpha-SNAP in vesicular traffic through the secretory pathway remains controversial. We performed a study on the kinetics of exocytosis from bovine chromaffin cells using high time resolution capacitance measurement and electrochemical amperometry, combined with flash photolysis of caged Ca2+ as a fast stimulus. alpha-SNAP, a C-terminal mutant of alpha-SNAP, and NEM were assayed for their effects on secretion kinetics. Two kinetically distinct components of catecholamine release can be observed upon fast step-like elevation of [Ca2+]i. One is the exocytotic burst, thought to represent the readily releasable pool of vesicles. Following the exocytotic burst, secretion proceeds slowly at maintained high [Ca2+]i, which may represent vesicle maturation/recruitment, i.e. some priming steps after docking. alpha-SNAP increased the amplitude of both the exocytotic burst and the slow component but did not change their kinetics, which we examined with millisecond time resolution. In addition, NEM only partially inhibited the slow component without altering the exocytotic burst, fusion kinetics and the rate of endocytosis. These results suggest a role for alpha-SNAP/NSF in priming granules for release at an early step, but not modifying the fusion of readily releasable granules.     

Calcium dependence of exocytosis and endocytosis at the cochlear inner hair cell afferent synapse

Release of neurotransmitter at the inner hair cell (IHC) afferent synapse is a fundamental step in translating sound into auditory nerve excitation. To study the Ca2+ dependence of the underlying vesicle fusion and subsequent endocytosis, we combined Ca2+ uncaging with membrane capacitance measurements in mouse IHCs. Rapid elevations in [Ca2+]i above 8 microM caused a biphasic capacitance increase corresponding to the fusion of approximately 40,000 vesicles. The kinetics of exocytosis displayed a fifth-order Ca2+ dependence reaching maximal rates of >3 x 10(7) vesicle/s. Exocytosis was always followed by slow, compensatory endocytosis (tau congruent with 15 s). Higher [Ca2+]i increased the contribution of a faster mode of endocytosis with a Ca2+ independent time constant of approximately 300 ms. These properties provide for rapid and sustained transmitter release from this large presynaptic terminal.     

Type-3 ryanodine receptor involved in Ca2+-induced Ca2+ release and transmitter exocytosis at frog motor nerve terminals

Ca(2+)-induced Ca2+ release (CICR) occurs in frog motor nerve terminals after ryanodine receptors (RyRs) are primed for activation by conditioning large Ca2+ entry. We studied which type of RyR exists, whether CICR occurs without conditioning Ca2+ entry and how RyRs are primed. Immunohistochemistry revealed the existence of RyR3 in motor nerve terminals and axons and both RyR1 and RyR3 in muscle fibers. A blocker of RyR, 8-(N,N-diethylamino)octyl 3,4,5-trimethoxybenzoate hydrochloride (TMB-8) slightly decreased rises in intracellular Ca2+ ([Ca2+]i) induced by a short tetanus (50 Hz, 1-2s), but not after treatment with ryanodine. Repetitive tetani (50 Hz for 15s every 20s) produced repetitive rises in [Ca2+]i, whose amplitude overall waxed and waned. TMB-8 blocked the waxing and waning components. Ryanodine suppressed a slow increase in end-plate potentials (EPPs) induced by stimuli (33.3 Hz, 15s) in a low Ca2+, high Mg2+ solution. KN-62, a blocker of Ca(2+)/calmoduline-activated protein kinase II (CaMKII), slightly reduced short tetanus-induced rises in [Ca2+]i, but markedly the slow waxing and waning rises produced by repetitive tetani in both normal and low Ca2+, high Mg2+ solutions. Likewise, KN-62, but not KN-04, an inactive analog, suppressed slow increases in EPP amplitude and miniature EPP frequency during long tetanus. Thus, CICR normally occurs weakly via RyR3 activation by single impulse-induced Ca2+ entry in frog motor nerve terminals and greatly after the priming of RyR via CaMKII activation by conditioning Ca2+ entry, thus, facilitating transmitter exocytosis and its plasticity.     

Extracellular ATP causes Ca2(+)-dependent and -independent insulin secretion in RINm5F cells. Phospholipase C mediates Ca2+ mobilization but not Ca2+ influx and membrane depolarization

The mechanism by which extracellular ATP stimulates insulin secretion was investigated in RINm5F cells. ATP depolarized the cells as demonstrated both by using the patch-clamp technique and a fluorescent probe. The depolarization is due to closure of ATP-sensitive K+ channels as shown directly in outside-out membrane patches. ATP also raised cytosolic Ca2+ [( Ca2+]i). At the single cell level the latency of the [Ca2+]i response was inversely related to ATP concentration. The [Ca2+]i rise is due both to inositol trisphosphate mediated Ca2+ mobilization and to Ca2+ influx. The former component, as well as inositol trisphosphate generation, were inhibited by phorbol myristate acetate which uncouples agonist receptors from phospholipase C. This manoeuvre did not block Ca2+ influx or membrane depolarization. Diazoxide, which opens ATP-sensitive K+ channels, attenuated membrane depolarization and part of the Ca2+ influx stimulated by ATP. However, the main Ca2+ influx component was unaffected by L-type channel blockers, suggesting the activation of other Ca2+ conductance pathways. ATP increased the rate of insulin secretion by more than 12-fold but the effect was transient. Prolonged exposure to EGTA dissociated the [Ca2+]i rise from ATP-induced insulin secretion, since the former was abolished and the latter only decreased by about 60%. In contrast, vasopressin-evoked insulin secretion was more sensitive to Ca2+ removal than the accompanying [Ca2+]i rise. Inhibition of phospholipase C stimulation by phorbol myristate acetate abrogated vasopressin but only reduced ATP-induced insulin secretion by 34%. These results suggest that ATP stimulates insulin release by both phospholipase C dependent and distinct mechanisms. The Ca2+)-independent component of insulin secretion points to a direct triggering of exocytosis by ATP.     

Alpha-latrotoxin modulates the secretory machinery via receptor-mediated activation of protein kinase C

The hypothesis whether alpha-latrotoxin (LTX) could directly regulate the secretory machinery was tested in pancreatic beta cells using combined techniques of membrane capacitance (Cm) measurement and Ca2+ uncaging. Employing ramp increase in [Ca2+]i to stimulate exocytosis, we found that LTX lowers the Ca2+ threshold required for exocytosis without affecting the size of the readily releasable pool (RRP). The burst component of exocytosis in response to step-like [Ca2+]i increase generated by flash photolysis of caged Ca2+ was also speeded up by LTX treatment. LTX increased the maximum rate of exocytosis compared with control responses with similar postflash [Ca2+]i and shifted the Ca2+ dependence of the exocytotic machinery toward lower Ca2+ concentrations. LTXN4C, a LTX mutant which cannot form membrane pores or penetrate through the plasma membrane but has similar affinity for the receptors as the wild-type LTX, mimicked the effect of LTX. Moreover, the effects of both LTX and LTXN4C) were independent of intracellular or extracellular Ca2+ but required extracellular Mg2+. Our data propose that LTX, by binding to the membrane receptors, sensitizes the fusion machinery to Ca2+ and, hence, may permit release at low [Ca2+]i level. This sensitization is mediated by activation of protein kinase C.     

Localization and heterogeneity of agonist-induced changes in cytosolic calcium concentration in single bovine adrenal chromaffin cells from video imaging of fura-2.

Temporal and spatial changes in the concentration of cytosolic free calcium ([Ca2+]i) in response to a variety of secretagogues have been examined in adrenal chromaffin cells using digital video imaging of fura-2-loaded cells. Depolarization of the cells with high K+ or challenge with nicotine resulted in a rapid and transient elevation of [Ca2+]i beneath the plasma membrane consistent with Ca2+ entry through channels. This was followed by a late phase in which [Ca2+]i rose within the cell interior. Agonists that act through mobilization of inositol phosphates produced an elevation in [Ca2+]i that was most marked in an internal region of the cell presumed to be the site of IP3-sensitive stores. When the same cells were challenged with nicotine or high K+, to trigger Ca2+ entry through voltage-dependent channels, the rise in [Ca2+]i was most prominent in the same localized region of the cells. These results suggest that Ca2+ entry through voltage-dependent channels results in release of Ca2+ from internal stores and that the bulk of the measured rise in [Ca2+]i is not close to the exocytotic sites on the plasma membrane. Analysis of the time courses of changes in [Ca2+]i in response to bradykinin, angiotensin II and muscarinic agonists showed that these agonists produced highly heterogeneous responses in the cell population. This heterogeneity was most marked with muscarinic agonists which in some cells elicited oscillatory changes in [Ca2+]i. Such heterogeneous changes in [Ca2+]i were relatively ineffective in eliciting catecholamine secretion from chromaffin cells. A single large Ca2+ transient, with a component of the rise in [Ca2+]i occurring beneath the plasma membrane, may be the most potent signal for secretion.     

Ca2+ clearance mechanisms in neurohypophysial terminals of the rat

The importance of intracellular calcium ([Ca2+]i) in the release of vasopressin (AVP) and oxytocin from the central nervous system neurohypopyhysial nerve terminals has been well-documented. To date, there is no clear understanding of Ca2+ clearance mechanisms and their interplay with transmembrane Ca2+ entry, intracellular [Ca2+]i transients, cytoplasmic Ca2+ stores and hence the release of AVP at the level of a single nerve terminal. Here, we studied the mechanism of Ca2+ clearance in freshly isolated nerve terminals of the rat neurohypophysis using Fura-2 Ca2+ imaging and measured the release of AVP by radioimmuno assay. An increase in the K+ concentration in the perfusion solution from 5 to 50 mM caused a rapid increase in [Ca2+]i and AVP release. Returning K+ concentration to 5 mM led to rapid restoration of both responses to basal level. The K+-evoked [Ca2+]i and AVP increase was concentration-dependent, reliable, and remained of constant amplitude and time course upon successive applications. Extracellular Ca2+ removal completely abolished the K+-evoked responses. The recovery phase was not affected upon replacement of NaCl with sucrose or drugs known to act on intracellular Ca2+ stores such as thapsigargin, cyclopiazonic acid, caffeine or a combination of caffeine and ryanodine did not affect either resting or K+-evoked [Ca2+]i or AVP release. By contrast, the plasma membrane Ca2+ pump inhibitor, La3+, markedly slowed down the recovery phase. The mitochondrial respiration uncoupler, carbonyl cyanide 3-chlorophenylhydrazone (CCCP), slightly but significantly increased the basal [Ca2+]i, and also slowed down the recovery phase of both [Ca2+]i and release responses. In conclusion, we show in nerve terminals that (i) Ca2+ extrusion through the Ca2+ pump in the plasma membrane plays a major role in the Ca2+ clearance mechanisms of (ii) Ca2+ uptake by mitochondria also contributes to the Ca2+ clearance and (iii) neither Na+/Ca2+ exchangers nor Ca2+ stores are involved in the Ca2+ clearance or in the maintenance of basal [Ca2+]i or release of AVP.     

Synergistic signals in the mechanism of antigen-induced exocytosis in 2H3 cells: evidence for an unidentified signal required for histamine release

The aim of this study was to determine whether the increase in cytosolic free Ca2+ concentration ([Ca2+]i) in response to antigen (aggregated ovalbumin) on IgE-primed 2H3 cells was sufficient to account for exocytosis. When the [Ca2+]i responses to antigen and the Ca2+ ionophore A23187 were compared, A23187 was much less effective at releasing histamine at equivalent [Ca2+]i increases, and little or no stimulated histamine release occurred with A23187 concentrations that matched the [Ca2+]i response to antigen concentrations that stimulated maximal histamine release. The [Ca2+]i response to antigen is not, therefore, sufficient to account for exocytosis, although extracellular Ca2+ is necessary to initiate both the [Ca2+]i response and histamine release: the antigen must generate an additional, unidentified, signal that is required for exocytosis. To determine whether this signal was the activation of protein kinase C, the effects of the phorbol ester 12-0-tetradecanoyl phorbol 13-acetate (TPA) on the responses to antigen were examined. TPA blocked the antigen-induced [Ca2+]i response and the release of inositol phosphates but had little effect on histamine release and did not stimulate exocytosis by itself. The unidentified signal from the antigen is therefore distinct from the activation of protein kinase C and is generated independently of the [Ca2+]i response or the release of inositol phosphates. Taken together with other data that imply that there is very little activation of protein kinase C by antigen when the rate of histamine release is maximal, it is concluded that the normal exocytotic response to antigen requires the synergistic action of the [Ca2+]i signal together with an unidentified signal that is not mediated by protein kinase C.     

Syntillas release Ca2+ at a site different from the microdomain where exocytosis occurs in mouse chromaffin cells

Spontaneous, short-lived, focal cytosolic Ca2+ transients were found for the first time and characterized in freshly dissociated chromaffin cells from mouse. Produced by release of Ca2+ from intracellular stores and mediated by type 2 and perhaps type 3 ryanodine receptors (RyRs), these transients are quantitatively similar in magnitude and duration to Ca2+ syntillas in terminals of hypothalamic neurons, suggesting that Ca2+ syntillas are found in a variety of excitable, exocytotic cells. However, unlike hypothalamic nerve terminals, chromaffin cells do not display syntilla activation by depolarization of the plasma membrane, nor do they have type 1 RyRs. It is widely thought that focal Ca2+ transients cause "spontaneous" exocytosis, although there is no direct evidence for this view. Hence, we monitored catecholamine release amperometrically while simultaneously imaging Ca2+ syntillas, the first such simultaneous measurements. Syntillas failed to produce exocytotic events; and, conversely, spontaneous exocytotic events were not preceded by syntillas. Therefore, we suggest that a spontaneous syntilla, at least in chromaffin cells, releases Ca2+ into a cytosolic microdomain distinct from the microdomains containing docked, primed vesicles. Ryanodine (100 microM) reduced the frequency of Ca2+ syntillas by an order of magnitude but did not alter the frequency of spontaneous amperometric events, suggesting that syntillas are not involved in steps preparatory to spontaneous exocytosis. Surprisingly, ryanodine also increased the total charge of individual amperometric events by 27%, indicating that intracellular Ca2+ stores can regulate quantal size.     

Role of residual calcium in synaptic depression and posttetanic potentiation: fast and slow calcium signaling in nerve terminals.

Trains of action potentials evoked rises in presynaptic Ca2+ concentration ([Ca2+]i) at the squid giant synapse. These increases in [Ca2+]i were spatially nonuniform during the trains, but rapidly equilibrated after the trains and slowly declined over hundreds of seconds. The trains also elicited synaptic depression and augmentation, both of which developed during stimulation and declined within a few seconds afterward. Microinjection of the Ca2+ buffer EGTA into presynaptic terminals had no effect on transmitter release or synaptic depression. However, EGTA injection effectively blocked both the persistent Ca2+ signals and augmentation. These results suggest that transmitter release is triggered by a large, brief, and sharply localized rise in [Ca2+]i, while augmentation is produced by a smaller, slower, and more diffuse rise in [Ca2+]i.     

Rapid increases in cytosolic free calcium in response to muscarinic stimulation of rat parotid acinar cells

Carbachol-evoked rises in [Ca2+]i were measured in fura-2-loaded, rat parotid acinar cells. In suspensions of dissociated cells examined by dual wavelength excitation fluorimetry, a maximally effective concentration of carbachol produced a measured peak [Ca2+]i of 780 +/- 60 nM followed by a maintained elevation in the presence of 1 mM external Ca2+, and a peak of 630 +/- 95 nM followed by a return to resting values in the absence of external Ca2+. Stopped-flow, single wavelength fluorimetry was used to resolve the rising phase of the response. There was a dose-dependent lag of 70-220 ms before [Ca2+]i started to increase, and [Ca2+]i was maximal by 800-900 ms. These times were similar in the presence or absence of external Ca2+, although the initial rate of rise was faster in the presence of external Ca2+. These kinetics are consistent with a biochemical event, possibly phosphatidylinositol bisphosphate hydrolysis, mediating both internal release and Ca2+ entry, with a component of the initial rise being due to Ca2+ entry.     

Suppression of insulin release by galanin and somatostatin is mediated by a G-protein. An effect involving repolarization and reduction in cytoplasmic free Ca2+ concentration

The effects of galanin and somatostatin on insulin release, membrane potential, and cytoplasmic free Ca2+ concentration [( Ca2+]i) were investigated using beta-cells isolated from obese hyperglycemic mice. Whereas insulin release was measured in a column perifusion system, membrane potential and [Ca2+]i were measured with the fluorescent indicators bisoxonol (bis-(1,3-diethylthiobarbiturate)trimethineoxonol) and quin 2, in cell suspensions in a cuvette. Galanin (16 nM) and somatostatin (400 nM) suppressed glucose-stimulated insulin release in parallel to promoting repolarization and a reduction in [Ca2+]i. The reduction in [Ca2+]i comprised an initial nadir followed by a slow rise and the establishment of a new steady state level. The slow rise in [Ca2+]i was abolished by 50 microM D-600, a blocker of voltage-activated Ca2+ channels. Both peptides suppressed insulin release even when [Ca2+]i was raised by 25 mM K+. Under these conditions the inhibition of insulin release was partly reversed by an increase in the glucose concentration. Addition of 5 mM Ca2+ to a cell suspension, incubated in the presence of 20 mM glucose and either galanin, somatostatin, or the alpha 2-adrenergic agonist clonidine (10 nM), induced oscillations in [Ca2+]i, this effect disappearing subsequent to the addition of D-600. The effects of galanin, somatostatin, and clonidine on [Ca2+]i were abolished in beta-cells treated with pertussis toxin. In accordance with measurements of [Ca2+]i, treatment with pertussis toxin reversed the inhibitory effect of galanin on insulin release. The inhibitory action of galanin and somatostatin on insulin release is probably accounted for by not only a repolarization-induced reduction in [Ca2+]i and a decreased sensitivity of the secretory machinery to Ca2+, but also by a direct interaction with the exocytotic process. It is proposed that these effects are mediated by a pertussis toxin-sensitive GTP-binding protein.     

GABAA receptor-mediated increase of cytosolic Ca2+ in isolated bovine adrenal chromaffin cells

We have studied the effects of GABA on cytosolic free Ca2+ concentration ([Ca2+]i) as a means of investigating the role of GABA in adrenal catecholamine (CA) secretion. It was demonstrated that GABA caused an elevation of [Ca2+]i via the GABAA receptor in a concentration-dependent manner, which was well correlated with an increase of 45Ca uptake, an increase of CA release and a depolarization of chromaffin cells assessed with bis-oxonol fluorescence. Since the GABA-induced rise of [Ca2+]i was absolutely dependent on the presence of extracellular Ca2+ and partly sensitive to nifedipine, at least one entry route for Ca2+ facilitated by GABA via a voltage-sensitive Ca2+ channel was suggested. When extracellular Cl- was lowered, GABA-induced CA release, depolarization, and rise of [Ca2+]i were all markedly enhanced. It is possible that GABA plays a modulatory role in the regulation of adrenal CA secretion as a facilitatory modulator.     

2,5-Di-(tert-butyl)-1,4-benzohydroquinone rapidly elevates cytosolic Ca2+ concentration by mobilizing the inositol 1,4,5-trisphosphate-sensitive Ca2+ pool

2,5-Di-(tert-butyl)-1,4-benzohydroquinone (tBuBHQ), a potent inhibitor of liver microsomal ATP-dependent Ca2+ sequestration (Moore, G. A., McConkey, D. J., Kass, G. E. N., O'Brien, P. J., and Orrenius, S. (1987) FEBS Lett. 224, 331-336), produced a concentration-dependent, rapid increase in cytosolic free Ca2+ concentration ([Ca2+]i) in isolated rat hepatocytes (EC50 = 1-2 microM). The amplitude of the [Ca2+]i increase was essentially identical with that produced by vasopressin, but the tBuBHQ-stimulated [Ca2+]i increase remained sustained for 15-20 min. Vasopressin added 2-3 min after tBuBHQ caused [Ca2+]i to rapidly return to basal levels; however, tBuBHQ added after vasopressin resulted in a Ca2+ transient rather than a sustained [Ca2+]i elevation. Ca2+ influx was not stimulated in tBuBHQ-treated hepatocytes, but was markedly enhanced upon addition of vasopressin. Depletion of the endoplasmic reticular Ca2+ pool by the addition of vasopressin to hepatocytes incubated in low Ca2+ medium virtually abolished the tBuBHQ-mediated [Ca2+]i rise and vice versa. In saponin-permeabilized hepatocytes, tBuBHQ released Ca2+ from the same nonmitochondrial, ATP-dependent Ca2+ pool which was released by inositol 1,4,5-trisphosphate. Furthermore, tBuBHQ-induced Ca2+ release in saponin-permeabilized cells was not inhibited by neomycin, and tBuBHQ did not produce any apparent accumulation of inositol phosphates in intact hepatocytes. The rate of passive efflux of Ca2+ from Ca2+-loaded hepatic microsomes was unaltered by tBuBHQ. Thus, tBuBHQ inhibits ATP-dependent Ca2+ sequestration via a direct effect on the endoplasmic reticulum Ca2+ pump, resulting in net Ca2+ release and elevation of [Ca2+]i. Taken together, our results show that in the absence of hormonal stimuli, excess Ca2+ is only slowly cleared from the hepatocyte cytosol, indicating that the basal rate of Ca2+ removal by the plasma membrane Ca2+ pump and mitochondria is slow. Furthermore, Ca2+-mobilizing hormones appear to stimulate an active process of Ca2+ removal from hepatocyte cytosol which does not depend on re-uptake into the endoplasmic reticulum.     

Role of calcium in histamine release from rat mast cells activated by various secretagogues; intracellular calcium mobilization correlates with histamine release

Anti-IgE, con A or antigen caused an increase in the intracellular calcium concentration, [Ca2+]i, of mast cells. The increase occurred in two stages: a rapid initial rise caused by Ca-mobilization from intracellular Ca-stores and a second sustained rise caused by an influx of extracellular calcium (White, J.R., Pluznik, D.V., Ishizaka, K. & Ishizaka, T. (1985) Proc. Natl. Acad. Sci. U.S.A. 82, 8193-8197). The rapid initial rise was followed by a release of histamine, which seemed to coincide with the second rise. A23187 and compound 48/80 induced a rapid initial rise in [Ca2+]i, followed by a gradual decrease in [Ca2+]i, GMCHA-OPhBut, a specific pH 7 tryptase inhibitor (Muramatu, M., Ito, T., Takei, M. & Endo, K. (1988) Biol. Chem. Hoppe-Seyler 369, 617-625), strongly inhibited both the initial and second rises of [Ca2+]i, as well as histamine release by these secretagogues, and its effects on the initial rise were closely correlated with those on histamine release. Addition of GMCHA-OPhBut immediately after the initial rise strongly inhibited the second rise, thereby decreasing the final [Ca2+]i. These results strongly suggested a possible involvement of pH 7 tryptase, not only in Ca-mobilization leading to the initial rise in [Ca2+]i, but also in the second rise. Trapping of extracellular calcium by 3mM EGTA decreased both the initial rise in [Ca2+]i and histamine secretion induced by anti-IgE or con A; the magnitude of this effect depended on the time between induction and EGTA addition. Histamine release was closely correlated with the initial rise in [Ca2+]i. Similar results were obtained with A23187, but even 5 min after the addition of EGTA an initial rise of [Ca2+]i could still be induced, and histamine (30% of total histamine) was still released. However, A23187 did not induce a rise in [Ca2+]i in mast cells which had been exhaustively washed with Tyrode/Hepes solution containing 3mM EGTA, followed by suspension in the same solution. Even at 20 min after depletion of the extracellular calcium, compound 48/80 still caused an initial rise in [Ca2+]i to above half the maximal value, and histamine secretion was even less affected. The above results indicated that the initial rise in [Ca2+]i, due to Ca-mobilization, correlates with the histamine release promoted by the secretagogues described. On the other hand, isoproterenol strongly induced histamine secretion with no change of [Ca2+]i, while EGTA treatment prior to isoproterenol stimulation had no effect on histamine release, indicating a different secretion mechanism.     

Regulation of transmitter release from retinal bipolar cells.

Mb1 bipolar cells (ON-type cells) of the goldfish retina have exceptionally large (approximately 10 microns in diameter) presynaptic terminals, and thus, are suitable for investigating presynaptic mechanisms for transmitter release. Using enzymatically dissociated Mb1 bipolar cells under whole-cell voltage clamp, we measured the Ca2+ current (ICa), the intracellular free Ca2+ concentration ([Ca2+]i), and membrane capacitance changes associated with exocytosis and endocytosis. Release of transmitter (glutamate) was monitored electrophysiologically by a glutamate receptor-rich neuron as a probe. L-type Ca2+ channels were localized at the presynaptic terminals. The presynaptic [Ca2+]i was strongly regulated by cytoplasmic Ca2+ buffers, the Na(+)-Ca2+ exchanger and the Ca2+ pump in the plasma membrane. Once ICa was activated, a steep Ca2+ gradient was created around Ca2+ channels; [Ca2+]i increased to approximately 100 microM at the fusion sites of synaptic vesicles whereas up to approximately 1 microM at the cytoplasm. The short delay (approximately 1 ms) of exocytosis and the lack of prominent asynchronous release after the termination of ICa suggested a low-affinity Ca2+ fusion sensor for exocytosis. Depending on the rate of Ca2+ influx, glutamate was released in a rapid phasic mode as well as a tonic mode. Multiple pools of synaptic vesicles as well as vesicle cycling seemed to support continuous glutamate release. Activation of protein kinase C increased the size of synaptic vesicle pool, resulting in the potentiation of glutamate release. Goldfish Mb1 bipolar cells may still be an important model system for understanding the molecular mechanisms of transmitter release.     

Localized Ca2+ entry preferentially effects protein dephosphorylation, phosphorylation, and glutamate release.

The release of neurotransmitter glutamate from isolated nerve terminals (synaptosomes) was found to be tightly coupled to the entry of Ca2+ through voltage-dependent Ca2+ channels, but is relatively unresponsive to "bulk" increases in cytosolic Ca2+ concentrations ([Ca2+]c) effected by Ca2+ ionophore. Under the same conditions, this dependence on Ca2+ influx, specifically through Ca2+ channels, was also seen for the dephosphorylation of a 96-kDa protein, (P96), present in the nerve terminals, as well as the phosphorylation of proteins migrating at 75 kDa (P75), corresponding to the synapsins, a group of well characterized synaptic vesicle-associated proteins. P96 dephosphorylation, following Ca2+ influx, was persistent and insensitive to the phosphatase inhibitor okadaic acid, suggesting a phosphatase other than protein phosphatase 1 and 2A as being responsible. Perhaps through the same phosphatase activity the increase in P75 phosphorylation was rapidly reversed with a time course similar to P96 dephosphorylation. When release, P96 dephosphorylation, and P75 phosphorylation were considered as functions of the [Ca2+]c increases achieved by depolarization and Ca2+ ionophore, there was no correlation of any of these with the overall concentration of Ca2+ in the cytosol. Since the fura-2 method used to measure [Ca2+] gives an averaged [Ca2+]c, these results imply that the release and protein dephosphorylation events are functionally coupled to local [Ca2+]c, in the immediate vicinity of Ca2+ channels. The reported clustering of the latter at the active zone area of the synapse and the parallelism between synaptic vesicle exocytosis and the phosphorylation of synaptic vesicle-associated proteins (p75:synapsins Ia/Ib), suggests that P96 may be similarly localized at the active zone area and, therefore, may be of significance in a modulatory role in glutamate release.