Evidence for a Role of Protein Kinase C Substrate B-50 (GAP-43) in Ca2+-Induced Neuropeptide Cholecystokinin-8 Release from Permeated Synaptosomes

Abstract: To study the involvement of the protein kinase C (PKC) substrate B-50 [also known as growth-associated protein-43 (GAP-43), neuromodulin, and F1] in presynaptic cholecystokinin-8 (CCK-8) release, highly purified synaptosomes from rat cerebral cortex were permeated with the bacterial toxin streptolysin O (SL-O). CCK-8 release from permeated synaptosomes, determined quantitatively by radioimmunoassay, could be induced by Ca²⁺ in a concentration-dependent manner (EC₅₀ of ～10^-5M). Ca²⁺-induced CCK-8 release was maximal at 10⁴M Ca²⁺, amounting to ～10% of the initial 6,000 ± 550 fmol of CCK-8 content/mg of synaptosomal protein. Only 30% of the Ca^a+-induced CCK-8 release was dependent on the presence of exogenously added ATP. Two different monoclonal anti-B-50 antibodies were introduced into permeated synaptosomes to study their effect on Ca²⁺-induced CCK-8 release. The N-terminally directed antibodies (NM2), which inhibited PKC-mediated B-50 phosphorylation, inhibited Ca²⁺-induced CCK-8 release in a dose-dependent manner, whereas the C-terminally directed antibodies (NM6) affected neither B-50 phosphorylation nor CCK-8 release. The PKC inhibitors PKC_19–36 and 1 ?(5-isoquinolinylsulfonyl)-2-methylpiperazine (H-7), which inhibited B-50 phosphorylation in permeated synaptosomes, had no effect on Ca²⁺-induced CCK-8 release. Our data strongly indicate that B-50 is involved in the mechanism of presynaptic CCK-8 release, at a step downstream of the Ca²⁺ trigger. As CCK-8 is stored in large densecored vesicles, we conclude that B-50 is an essential factor in the exocytosis from this type of neuropeptide-containing vesicle. The differential effects of the monoclonal antibodies indicate that this B-50 property is localized in the N-terminal region of the B-50 molecule, which contains the PKC phosphorylation site and calmodulin-binding domain.     

Perfusion of Immobilized Isolated Nerve Terminals as a Model for the Regulation of Transmitter Release: Release of Different, Endogenous Transmitters, Repeated Stimulation, and High Time Resolution

To study the release of neurotransmitters, i.e., the recruitment of transmitters for release and the regulation of the release process, isolated nerve terminals (synaptosomes) of the rat forebrain were immobilized in Sephadex gel inside a perfusion chamber. In this way, the following were achieved: (a) A very limited pressure stress was exerted on the synaptosomes, so that these remained viable for long periods (greater than 30 min) inside the chamber and did not elute from the chamber, which allowed long-term experiments with repeated stimulations; (b) estimation of the release of various endogenous transmitters, both in a Ca(2+)-dependent (exocytotic) and Ca(2+)-independent manner; (c) a step-like stimulation with depolarizing agents (rise time, 3-4 s) and a high time resolution (600-ms sampling); and (d) negligible reuptake of transmitter into the terminals or extracellular breakdown. It is concluded that this perfusion setup helps to provide new insights in the presynaptic stimulus-secretion coupling, co-transmission, and the exo-endocytosis cycle.     

Presynaptic Glutamate Receptors Regulate Noradrenaline Release from Isolated Nerve Terminals

The wide-ranging neuronal actions of excitatory amino acids, such as glutamate, are thought to be mediated mainly by postsynaptic N-methyl-D-aspartate (NMDA) and non-NMDA receptors. We now report the existence of presynaptic glutamate receptors in isolated nerve terminals (synaptosomes) prepared from hippocampus, olfactory bulb, and cerebral cortex. Activation of these receptors by NMDA or non-NMDA agonists, in a concentration-dependent manner, resulted in Ca(2+)-dependent release of noradrenaline from vesicular transmitter stores. The NMDA-stimulated release was potentiated by glycine and was blocked by Mg2+ and selective NMDA antagonists. In contrast, release stimulated by selective non-NMDA agonists was blocked by 6-cyano-7-nitroquinoxaline-2,3- dione, but not by Mg2+ or NMDA antagonists. Our data suggest that the presynaptic glutamate receptors can be classified pharmacologically as both the NMDA and non-NMDA types. These receptors, localized on nerve terminals of the locus ceruleus noradrenergic neurons, may play an important role in interactions between noradrenaline and glutamate.     

Regulation of Vesicle Traffic and Neurotransmitter Release in Isolated Nerve Terminals

In this overview current insights in the regulation of presynaptic transmitter release, mainly acquired in studies using isolated CNS nerve terminals are highlighted. The following aspects are described. (i) The usefulness of pinched-off nerve terminals, so-called synaptosomes, for biochemical and ultrastructural studies of presynaptic stimulus-secretion coupling. (ii) The regulation of neurotransmitter release by multiple Ca²⁺ channels, with special emphasis on the specificity of different classes of these channels with respect to the release of distinct types of neurotransmitters, that are often co-localized, such as amino acids and neuropeptides. (iii) Possible molecular mechanisms involved in targeting synaptic vesicle (SV) traffic toward the active zone. (iv) The role of presynaptic receptors in regulating transmitter release, with special emphasis on different glutamate subtype receptors. Isolated nerve terminals are of great value as model system in order to obtain a better understanding of the regulation of the release of distinct classes of neurotransmitters in tiny CNS nerve endings.     

Transmitter Glutamate Release from Isolated Nerve Terminals: Evidence for Biphasic Release and Triggering by Localized Ca2+

The kinetics of Ca2(+)-dependent release of glutamate from guinea-pig cerebrocortical synaptosomes evoked by KCl or 4-aminopyridine are investigated using a continuous fluorimetric assay. Release by both agents is biphasic, with a rapid phase complete within 2 s followed by a more extensive slow phase with a half-maximal release in 52 s for KCl-evoked release and greater than 120 s for 4-aminopyridine-evoked release. The two phases of glutamate release may reflect a dual localization of releasable vesicles at the active zone and in the bulk cytoplasm. Decreasing depolarization depresses the extent rather than increasing the time for half-maximal Ca2(+)-dependent release. Both the fast and the slow phases of glutamate release require external Ca2+ and cytoplasmic ATP. KCl depolarization produces a transient "spike" of cytoplasmic free Ca2+ [( Ca2+]c), which recovers to a plateau; the major component of glutamate release occurs during this plateau. Predepolarization in the absence of added external Ca2+, to inhibit transient Ca2+ channels, does not affect the subsequent glutamate release evoked by Ca2+ readdition. Thus, release involves primarily noninactivating Ca2+ channels. For a given increase in [Ca2+]c, KCl and 4-aminopyridine cause equal release of glutamate, while ionomycin releases much less glutamate. This lowered efficiency is not due to ATP depletion. It is concluded that glutamate exocytosis is evoked by localized Ca2+ entering through noninactivating voltage-dependent Ca2+ channels and that nonlocalized Ca2+ entry with ionomycin is inefficient.     

Characterization of the Effect of Monensin on γ-Amino-n-Butyric Acid Release from Isolated Nerve Terminals

The action of the polyether antibiotic monensin on the release of gamma-[3H]amino-n-butyric acid [( 3H]GABA) from mouse brain synaptosomes is characterized. Monensin enhances the release of this amino acid transmitter in a dose-dependent manner and does not modify the efflux of the nontransmitter amino acid alpha-[3H]aminoisobutyrate. The absence of external Ca2+ fails to prevent the stimulatory effect of monensin on [3H]GABA release. Furthermore, monensin is less effective in stimulating [3H]GABA release in the presence of Ca2+. The releasing response to monensin is absolutely dependent on external Na+. The blockade of voltage-sensitive Na+ or Ca2+ channels does not modify monensin-induced release of the transmitter. Also, the blockade of the GABA uptake pathway fails to prevent the stimulatory effect of monensin on [3H]GABA release. Although monensin markedly increases Na+ permeability in synaptosomes, these data indicate that the Ca2+-independent monensin-stimulated transmitter release is not mediated by the Na+-dependent uptake pathway. It is concluded that the entrance of Na+ through monensin molecules inserted in the presynaptic membrane might be sufficient to initiate the intraterminal molecular events underlying transmitter release.     

Bioenergetics and Transmitter Release in the Isolated Nerve Terminal

The isolated nerve terminal (or synaptosome) is the simplest preparation that allows mitochondrial bioenergetics to be studied in a physiological milieu, as well as facilitating investigation of the protein chemistry and regulation of synaptic vesicle exocytosis and recovery and providing a target for the study of the mechanism of action of numerous neurotoxins. This brief review discusses studies from our laboratory that may have provided some insight into these aspects of nerve terminal function.     

Ca2+-Independent Release of Glutamate During In Vitro Anoxia in Isolated Nerve Terminals

The effects of in vitro anoxia on the release of glutamate in isolated nerve terminals were studied. The extra-synaptosomal concentration of glutamate ([Glu]ext) under aerobic conditions was 2.3 microM and increased to 4.9 microM after 10 min of anoxia. However, when synaptosomes were incubated in the presence of lactate plus pyruvate instead of glucose, to prevent anaerobic glycolysis, anoxia induced an eightfold increase in the [Glu]ext. The accumulation of glutamate in the external medium during anoxia was Ca2+ independent and insensitive to a significant reduction of the Ca(2+)-dependent release of the amino acid. These results indicate that a Ca(2+)-independent efflux of cytoplasmic glutamate occurs during in vitro anoxia in isolated nerve terminals.     

Regulatory Interactions Among Axon Terminals Affecting the Release of Different Transmitters from Rat Striatal Slices Under Hypoxic and Hypoglycemic Conditions

An in vitro model of ischemia was utilized to study the effects of both oxygen and glucose depletion on transmitter release from rat striatal slices. The spontaneous and stimulation-evoked releases of tritiated dopamine, gamma-aminobutyric acid, glutamate, and acetylcholine were measured. Hypoxia increased the evoked release of glutamate and dopamine without effect on the resting release. In contrast, hypoglycemia itself increased the resting release of dopamine. Hypoxia in combination with hypoglycemia provoked a massive release of glutamate, dopamine, and gamma-aminobutyric acid. The effect on acetylcholine release was less pronounced. Ca2+ withdrawal partly reduced the effect of hypoxia combined with hypoglycemia on dopamine release and application of tetrodotoxin (1 microM) abolished it. MK-801 (3 microM), an N-methyl-D-aspartate receptor antagonist, attenuated the effect of hypoxia and hypoglycemia on [3H]dopamine release. omega-Conotoxin (0.1 microM) had a similar effect on stimulation-evoked release under a hypoxic condition. The D2 receptor antagonist sulpiride (100 microM) failed to enhance the release of [3H]acetylcholine in hypoxia combined with hypoglycemia. It was suggested that in response to hypoxia combined with hypoglycemia there is a massive release of glutamate due to the increased firing rate which in turn releases dopamine from the axon terminals through stimulation of presynaptic N-methyl-D-aspartate receptors. Dopaminergic inhibitory control on ACh release seems not to be operative under conditions of hypoxia combined with hypoglycemia.     

Bilirubin Inhibits Ca2+-Dependent Release of Norepinephrine from Permeabilized Nerve Terminals

Although the well-known neurotoxic agent bilirubin can induce alterations in neuronal signaling, direct effects on neurotransmitter release have been difficult to demonstrate. In the present study we have used permeabilized nerve terminals (synaptosomes) from rat brain prelabeled with [³H]norepinephrine to examine the effects of bilirubin on transmitter release. Rat cerebrocortical synaptosomes were permeabilized with streptolysin-O (2 U/ml) in the absence or presence of bilirubin (10 M–320 M) and Ca²⁺ (100 M), and the amount of radiolabeled transmitter released during 5 min to the medium was analysed. Low levels of bilirubin decreased Ca²⁺-evoked release in a dose-dependent manner, with half-maximal effect at approx 25 M bilirubin. Higher levels of bilirubin (100–320 M) increased [³H]norepinephrine efflux in the absence of Ca²⁺, suggesting that high bilirubin levels induced leakage of transmitter from vesicles. The nontoxic precursor biliverdin had no effect on Ca²⁺-dependent exocytosis. Our data indicate that bilirubin directly inhibits both exocytotic release and vesicular storage of brain catecholamines.     

Evidence for the Corelease of Dynorphin and Glutamate from Rat Hippocampal Mossy Fiber Terminals

Abstract: Hippocampal mossy fiber (MF) nerve endings may be isolated in a subcellular fraction (P₃) that releases both prodynorphin-derived peptides and glutamate (Glu) in a calcium-dependent manner when depolarized. However, this isolation procedure does not yield a pure preparation of MF synaptosomes. The present study evaluates the proportion of dynorphin (Dyn) and Glu that is released from synaptosomes in the P₃ fraction that are of MF origin. We have addressed this issue by determining the degree to which a selective lesion of the dentate granule cell/MF system in vivo concomitantly reduces the exocytosis of Dyn and Glu from the P₃ subcellular fraction. Unilateral injections of colchicine into the dentate gyrus resulted in a substantial and selective degeneration of the granule cell/ MF pathway in the rat hippocampal formation. The overall integrated density of the Timm-stained band, which corresponds to the position of the MF terminal field, was estimated to be reduced by 75%. After this extensive loss of MF boutons, the K⁺-evoked release of Dyn and Glu from the P₃ fraction was reduced by 95 and 51 %, respectively. The loss of Timm staining and evoked Dyn release indicate that colchicine effectively eliminated MF synaptosomes from the P₃ fraction. Those subcellular entities that were not destroyed by colchicine comprised ～50% of the protein and evoked Glu release measured by using the P₃fraction. In addition, the present results demonstrate that the inhibitory potency of the K opioid agonist U-50.488H was not altered by the elimination of MF boutons from this synaptosomal preparation. This finding indicates that U-50,488H is capable of suppressing Glu exocytosis from both MF and non-MF synaptosomes. These results are consistent with the hypothesis that Dyn peptides and Glu are coreleased from hippocampal MF terminals.     

Release of Excitatory Amino Acids from Cultured Hippocampal Astrocytes Induced by a Hypoxic-Hypoglycemic Stimulation

An excess release of excitatory amino acids (EAA) is an important factor for postischemic brain damage. In the present communication, we demonstrate that cultured hippocampal cells release EAA after hypoxic-hypoglycemic treatment. The amounts of EAA released from astrocytes were appreciably above those released from neurons. Furthermore, the amount of aspartate released from astrocytes was comparable to that of glutamate, although the endogenous content of aspartate was one-fifth that of glutamate. The endogenous content of aspartate in astrocytes increased even after hypoxic-hypoglycemic treatment. These results suggests that ischemic neuronal death is due, at least in part, to the excitotoxicity of aspartate and glutamate derived from surrounding astrocytes.     

Binding of Cholecystokinin-8 (CCK-8) Peptide Derivatives to CCKA and CCKB Receptors

Abstract: The structural requirements for the selective binding of cholecystokinin-8 (CCK-8)-related peptides to peripheral (CCK_A) receptors are not sufficiently understood. In this study, the interaction of a series of newly shortened analogues of CCK-8 with both receptor subtypes was analyzed by displacement studies using [³H]-CCK-8 and ¹²⁵l-Bolton-Hunter (BH)-CCK-8 as radioligands. The pentapeptide derivative of CCK-8, succinyl-Tyr (SO₃H)-Met-Gly-Trp-Met-phenethylamide, was found to bind selectively with high affinity to the CCK_A receptor. The replacement of Met²⁸ and/or Met³¹ by norleucine and of L-Trp³⁰ by its D-analogue had no significant effect on the binding properties of the peptide. Further C-terminal shortening resulted in a drastic loss of affinity and selectivity of the CCK receptor binding.     

Release of Endogenous Amino Acids from the Hippocampus and Brain Stem from Developing and Adult Mice in Ischemia

The release of neurotransmitters and modulators has been studied mostly using labeled preloaded compounds. For several reasons, however, the estimated release may not reliably reflect the release of endogenous compounds. The basal and K⁺-evoked release of the neuroactive endogenous amino acids GABA, glycine, taurine, l-glutamate and l-aspartate was now studied in slices from the hippocampus and brain stem from 7-day-old and 3-month-old mice under control and ischemic conditions. The release of synaptically not active l-glutamine, l-alanine, l-threonine and l-serine was assessed for comparison. The estimates for the hippocampus and brainstem were markedly different and also different in developing and adult mice. GABA release was much greater in 3-month-old than in 7-day-old mice, whereas with taurine the situation was the opposite, in the hippocampus in particular. K⁺ stimulation enhanced glycine release more in the mature than immature brain stem while in the hippocampus the converse was observed. Ischemia enhanced the release of all neuroactive amino acids in both brain regions, the effects being relatively most pronounced in the case of GABA, aspartate and glutamate in the hippocampus in 3-month-old mice, and taurine in 7-day-old and glycine in 3-month-old mice in the brain stem. These results are qualitatively similar to those obtained on earlier experiments with labeled preloaded amino acids. However, the magnitudes of the release cannot be quite correctly estimated using radioactive labels. In developing mice only taurine release may counteract the harmful effects of excitatory amino acids in ischemia in both hippocampus and brain stem.     

Release of Glutamate, Aspartate, and γ-Aminobutyric Acid from Isolated Nerve Terminals

Abstract: With the advent of cloning, sequencing, and patchclamping techniques, knowledge of the postsynaptic actions of amino acid neurotransmitters has undergone a dramatic advance. The primary sequences of the inhibitory receptors for γ-aminobutyric acid (GABA) (Schofield et al., 1987) and glycine (Grenningloh et al., 1987) are now established, and patch-clamp analysis has elucidated many of the factors that regulate the opening of their ion channels. The excitatory glutamate receptors are being extensively characterized at both the pharmacological (reviewed by Foster and Fagg, 1984) and the electrophysiological (reviewed by Cull-Candy and Usowicz, 1987) level. In this climate, it is perhaps surprising that the fundamental presynaptic release mechanism for the amino acid neurotransmitters remains controversial.     

Electrical Stimulation of the Stratum Radiatum Increases the Release and Neosynthesis of Aspartate, Glutamate, and γ-Aminobutyric Acid in Rat Hippocampal Slices

The release of endogenous aspartic, glutamic, and gamma-aminobutyric acids (Asp, Glu, GABA, respectively) was measured in the effluent from superfused hippocampal slices using a new and sensitive mass spectrometric method. The stimulation of the stratum radiatum of the rat dorsal hippocampus caused a Ca2+-dependent increase in the release of these amino acids. This release was accompanied by an increase in the incorporation of [13C2] from [13C]glucose into Asp, Glu, and GABA, suggesting an increase in their neosynthesis. The removal of Ca2+ from the superfusion fluid brought about a marked decrease in Asp and Glu release at rest, and prevented their stimulation-evoked release and the appearance of population spikes. The results support the hypothesis that Asp and Glu are excitatory neurotransmitters in intrinsic hippocampal circuits and are possibly released from the Schaffer collaterals and commissural fibres. The increase in GABA release and neosynthesis during stimulation of the stratum radiatum could be related to recurrent inhibition evoked by transsynaptic stimulation of the pyramidal cells.     

Involvement of L-Type-Like Amino Acid Transporters in S-Nitrosocysteine-Stimulated Noradrenaline Release in the Rat Hippocampus

Abstract: Nitrogen oxides, such as nitric oxide, have been shown to regulate neuronal functions, including neurotransmitter release. We investigated the effect of S-nitroso-l -cysteine (SNC) on noradrenaline (NA) release in the rat hippocampus in vivo and in vitro. SNC stimulated [³H]NA release from prelabeled hippocampal slices in a dose-dependent manner. SNC stimulated endogenous NA release within 30 min to almost five times the basal level in vivo (microdialysis in freely moving rats). In a Na⁺-containing Tyrode's buffer, SNC-stimulated [³H]NA release was inhibited 30% by the coaddition of l -leucine. In the Na⁺-free, choline-containing buffer, SNC-stimulated [³H]NA release, which was similar to that in the Na⁺-containing buffer, was inhibited markedly by l -leucine, l -alanine, l -methionine, l -phenylalanine, and l -tyrosine. The effects of the other amino acids examined were smaller or very limited. The effect of l -leucine was stronger than that of d -leucine. A specific inhibitor of the L-type amino acid transporter, 2-aminobicyclo[2.2.1]-heptane-2-carboxylate (BCH), inhibited the effects of SNC on [³H]NA release in the Na⁺-free buffer. Uptake of l -[³H]leucine into the slices in the Na⁺-free buffer was inhibited by SNC, BCH, and l -phenylalanine, but not by l -lysine. The effect of SNC on cyclic GMP accumulation was not inhibited by l -leucine, although SNC stimulated cyclic GMP accumulation at concentrations up to 25 µM, much less than the concentration that stimulates NA release. These findings suggest that SNC is incorporated into rat hippocampus via the L-type-like amino acid transporter, at least in Na⁺-free conditions, and that SNC stimulates NA release in vivo and in vitro in a cyclic GMP-independent manner.     

Endogenous Noradrenaline and Dopamine in Nerve Terminals of the Hippocampus: Differences in Levels and Release Kinetics

The presence and release of endogenous catecholamines in rat and guinea pig hippocampal nerve terminals was studied by fluorimetric HPLC analysis. In isolated nerve terminals (synaptosomes) the levels and breakdown of endogenous catecholamines were determined and the release process was characterized with respect to its kinetics and Ca2+ and ATP dependence. Endogenous noradrenaline and dopamine, but not adrenaline, were detected in isolated hippocampal nerve terminals. For dopamine both the levels and the amounts released were more than 100-fold lower than those for noradrenaline. In suspension, released endogenous catecholamines were rapidly broken down. This could effectively be blocked by monoamine oxidase inhibitors, Ca(2+)-free conditions, and glutathione. The release of both noradrenaline and dopamine was highly Ca2+ and ATP dependent. Marked differences were observed in the kinetics of release between the two catecholamines. Noradrenaline showed an initial burst of release within 10 s after K+ depolarization. The release of noradrenaline was terminated after approximately 3 min of K+ depolarization. In contrast, dopamine release was more gradual, without an initial burst and without clear termination of release within 5 min. It is concluded that both catecholamines are present in nerve terminals in the rat hippocampus and that their release from (isolated) nerve terminals is exocytotic. The characteristics of noradrenaline release show several similarities with those of other classical transmitters, whereas dopamine release characteristics resemble those of neuropeptide release in the hippocampus but not those of dopamine release in other brain areas. It is hypothesized that in the hippocampus dopamine is released from large, dense-cored vesicles, probably colocalized with neuropeptides.     

Adenosine and Glutamate Modulate Each Other's Release from Rat Hippocampal Synaptosomes

Abstract: In rat hippocampal synaptosomes, adenosine decreased the K⁺ (15 mM) or the kainate (1 mM) evoked release of glutamate and aspartate. An even more pronounced effect was observed in the presence of the stable adenosine analogue, R-phenylisopropyladenosine. All these effects were reversed by the selective adenosine A₁ receptor antagonist 8-cyclo-pentyltheophylline. In the same synaptosomal preparation, K⁺ (30 mM) strongly stimulated the release of the preloaded [³H]adenosine in a partially Ca²⁺-dependent and tetrodotoxin (TTX)-sensitive manner. Moreover, in the same experimental conditions, both l -glutamate and l -aspartate enhanced the release of [³H]adenosine derivatives ([³H]ADD). The gluta-mate-evoked release was dose dependent and appeared to be Ca²⁺ independent and tetrodotoxin insensitive. This effect was not due to metabolism because even the nonmetabolizable isomers d -glutamate and d -aspartate were able to stimulate [³H]ADD release. In contrast, the specific glutamate agonists N-methyl-d -aspartate, kainate, and quisqualate failed to stimulate [³H]ADD release, suggesting that glutamate and aspartate effects were not mediated by known excitatory amino acid receptors. Moreover, NMDA was also ineffective in the absence of Mg²⁺ and l -glutamate-evoked release was not inhibited by adding the specific antagonists 2-amino-5-phosphonovaleric acid or 6–7-dinitroquinoxaline-2, 3-dione. The stimulatory effect did not appear specific for only excitatory amino acids, as γ-anunobutyric acid stimulated [³H]ADD release in a dose-related manner. These results suggest that, at least in synaptosomal preparations from rat hippocampus, adenosine and glutamate modulate each other's release. The exact mechanism of such interplay, although still, unknown, could help in the understanding of excitatory amino acid neurotoxicity.     

Arachidonic Acid Release and Catecholamine Secretion from Digitonin-Treated Chromaffin Cells: Effects of Micromolar Calcium, Phorbol Ester, and Protein Alkylating Agents

The relationship between catecholamine secretion and arachidonic acid release from digitonin-treated chromaffin cells was investigated. Digitonin renders permeable the plasma membranes of bovine adrenal chromaffin cells to Ca2+, ATP, and proteins. Digitonin-treated cells undergo exocytosis of catecholamine in response to micromolar Ca2+ in the medium. The addition of micromolar Ca2+ to digitonin-treated chromaffin cells that had been prelabeled with [3H]arachidonic acid caused a marked increase in the release of [3H]arachidonic acid. The time course of [3H]arachidonic acid release paralleled catecholamine secretion. Although [3H]arachidonic acid release and exocytosis were both activated by free Ca2+ in the micromolar range, the activation of [3H]arachidonic acid release occurred at Ca2+ concentrations slightly lower than those required to activate exocytosis. Pretreatment of the chromaffin cells with N-ethylmaleimide (NEM) or p-bromophenacyl bromide (BPB) resulted in dose-dependent inhibition of 10 microM Ca2+-stimulated [3H]arachidonic acid release and exocytosis. The IC50 of NEM for both [3H]arachidonic acid release and exocytosis was 40 microM. The IC50 of BPB for both events was 25 microM. High concentrations (5-20 mM) of Mg2+ caused inhibition of catecholamine secretion without altering [3H]arachidonic acid release. A phorbol ester that activates protein kinase C, 12-O-tetradecanoylphorbol-13-acetate (TPA), caused enhancement of both [3H]arachidonic acid release and exocytosis. The findings demonstrate that [3H]arachidonic acid release is stimulated during catecholamine secretion from digitonin-treated chromaffin cells and they are consistent with a role for phospholipase A2 in exocytosis from chromaffin cells. Furthermore the data suggest that protein kinase C can modulate both arachidonic acid release and exocytosis.