Role of Q-type Ca2+ channels in vasopressin secretion from neurohypophysial terminals of the rat.

1. The nerve endings of rat neurohypophyses were acutely dissociated and a combination of pharmacological, biophysical and biochemical techniques was used to determine which classes of Ca2+ channels on these central nervous system (CNS) terminals contribute functionally to arginine vasopressin (AVP) and oxytocin (OT) secretion. 2. Purified neurohypophysial plasma membranes not only had a single high-affinity binding site for the N-channel-specific omega-conopeptide MVIIA, but also a distinct high-affinity site for another omega-conopeptide (MVIIC), which affects both N- and P/Q-channels. 3. Neurohypophysial terminals exhibited, besides L- and N-type currents, another component of the Ca2+ current that was only blocked by low concentrations of MVIIC or by high concentrations of omega-AgaIVA, a P/Q-channel-selective spider toxin. 4. This Ca2+ current component had pharmacological and biophysical properties similar to those described for the fast-inactivating form of the P/Q-channel class, suggesting that in the neurohypophysial terminals this current is mediated by a 'Q'-type channel. 5. Pharmacological additivity studies showed that this Q-component contributed to rises in intraterminal Ca2+ concentration ([Ca2+]i) in only half of the terminals tested. 6. Furthermore, the non-L- and non-N-component of Ca(2+)-dependent AVP release, but not OT release, was effectively abolished by the same blockers of Q-type current. 7. Thus Q-channels are present on a subset of the neurohypophysial terminals where, in combination with N- and L-channels, they control AVP but not OT peptide neurosecretion.

Arachidonic acid regulation of vasopressin release and intracellular Ca2+ in neurohypophysial nerve endings.

The effects of arachidonic acid (AA) and arachidonic acid metabolites on vasopressin secretion and on intracellular free calcium concentration ([Ca2+]i) from both intact and streptolysin-O permeabilized isolated nerve endings of the rat neurohypophysis were studied. Arachidonic acid induced a dose-dependent increase in resting vasopressin (AVP) secretion in both intact and streptolysin-O permeabilized nerve endings. Although AA also dose-dependently induced an increase in [Ca2+]i in intact nerve endings, the AA-induced secretory response was largely independent of an increase in [Ca2+]i. Secretory responses in intact nerve endings showed AA-induced secretion to be sustained and that AA-induced vasopressin secretion occurs via exocytosis. Arachidonic acid also dose-dependently potentiated K+-depolarization evoked vasopressin release. The potentiation of secretion occurred despite an AA-induced reduction in K+-evoked Ca2+ influx. In addition, AA reinitiated secretion following a decline in the Ca2+-dependent exocytotic secretory response suggesting a separate secretory mechanism from Ca2+-induced secretion. Inhibition of the metabolic pathways for AA suggested that AA itself mediates the secretory effects and that AA is likely subject to rapid metabolism by lipoxygenases.

Stimulus-secretion coupling in the neurohypophysis of the jerboa Jaculus orientalis.

1. In many mammals, severe dehydration is known to cause exhaustion of the vasopressin content of the neural lobe. Here, we have examined the physiological state of the neurohypophysis of the jerboa Jaculus orientalis, a rodent inhabitant of a semi-desert climate. 2. Isolated neurohypophyses and neurosecretory nerve endings were perfused in vitro and vasopressin and oxytocin release were determined by radioimmunoassay. 3. Electrical stimulation of the neurohypophysis with bursts of pulses mimicking the activity of hypersecreting neuroendocrine neurones induced similar increases of secretion in both control animals and animals dehydrated for up to 2 months. Neurohormone release was greatly potentiated when the bursts of pulses were separated by silent intervals. 4. Prolonged stimulation of neurohypophyses from both control and dehydrated animals induced a sustained increase of vasopressin release; in contrast, oxytocin release under similar conditions showed a biphasic secretory pattern consisting of a transient increase that subsequently decreased to a steady level whose amplitude was similar to that for vasopressin. 5. K(+)-induced secretion was largely inhibited by the Ca2+ channel blockers nicardipine and omega-conotoxin, suggesting that in this neurosecretory system both L- and N-type calcium channels play a major role in stimulus-secretion coupling. Depolarization of isolated nerve endings using a fast-flow perifusion system showed that there was no difference in the amplitude and the time course of the secretory response in dehydrated and hydrated animals. 6. The results demonstrate that, despite the climatic conditions in which the jerboas live, their neural lobes retain the capacity to release, upon depolarization of the plasma membrane of the nerve endings, large amounts of neurohormone. It is concluded that the neurohypophyseal peptidergic release system in the dehydrated jerboa functions adequately even under extreme environmental stress.

Synthesis, turnover, and release of peptides from the neurohypophysis of the Jerboa Jaculus orientalis.

Peptide contents of neural lobes from adult jerboas (Jaculus orientalis) under different states of hydration were determined by radioimmunoassay. The amounts of vasopressin, oxytocin, and their associated neurophysins in animals dehydrated for up to 4 weeks were not significantly different from those of controls. The different neurohypophyseal peptide were separated on two different types of gradient using reverse-phase high-performance liquid chromatography. The shape of the chromatograms suggests that, in contrast to the case of the rat, for which only three types of neurophysins have been shown, there are, in jerboa, many subspecies of neurophysins. This was also shown using two-dimensional electrophoresis. Injection of [35S]cysteine into the supraoptic nucleus followed by HPLC of extracts from the neural lobes from animals under different states of dehydration showed that the labeled material is not released any faster in dehydrated animals than in controls. Labeled vasopressin, oxytocin, and neurophysins could still be detected by HPLC 4 weeks after injection. Neural lobes from animals injected with [35S]cysteine were perfused in vitro and the release of neuropeptides was triggered by bursts of electrical pulses and also by K(+)-induced depolarization. The amplitude of the rate constant for release and the amounts of vasopressin and of radiolabeled material released were similar in animals dehydrated for up to 3 weeks and in controls. Under physiological conditions similar to those that would be expected to occur in their natural habitat, the jerboas appear to have a hypothalamoneurohypophyseal system which is down-regulated.

Intracellular calcium and vasopressin release of rat isolated neurohypophysial nerve endings.

1. Monitoring of [Ca2+]i and vasopressin secretion in isolated nerve endings from the rat neurohypophysis were studied to determine the relationship between the time course of vasopressin secretion and depolarization-induced changes in [Ca2+]i. 2. Membrane depolarization by increasing the extracellular [K+] led to concentration-dependent, parallel increases in the amount of vasopressin release and in peak increases in [Ca2+]i. Half-maximal activation of a change in [Ca2+]i was attained at 40 mM extracellular K+. 3. The Ca2+ chelator dimethyl-BAPTA (1,2-bis(O-aminophenoxy)ethane-N,N,N'N'-tetraacetic acid), loaded into the nerve endings, reduced K+ depolarization-evoked vasopressin release and efficiently antagonized K(+)-induced changes in [Ca2+]i. Moreover, dimethyl-BAPTA dramatically reduced basal [Ca2+]i without a reduction in basal secretion. 4. The duration of the vasopressin secretory response was similar regardless of applied 50 mM K+ depolarizations longer than 30 s. The t1/2 of the secretory response was 45 s. Application of repetitive K+ depolarization pulses repetitive secretory responses of similar amplitude and duration. 5. The K(+)-induced changes in [Ca2+]i remained elevated throughout the duration of the depolarizing stimulus decreasing less than 30% over 3 min. The sustained increase in [Ca2+]i resulted largely from continued enhanced Ca2+ influx, demonstrated by susceptibility to the dihydropyridine, L-type calcium channel blocker, nicardipine. 6. Vasopressin secretion could be reinitiated following its decline to a step K+ depolarization by a further step increase in K+ or by removal and readdition of extracellular [Ca2+]. Alterations in [Ca2+]i paralleled periods of secretory activity. 7. Analysis of secretory responsiveness and change in [Ca2+]i to K+ depolarization in medium of altered extracellular [Ca2+] indicates that [Ca2+]i of 20 microM is sufficient to trigger vasopressin release. K(+)-induced alterations in [Ca2+]i could be observed at [Ca2+]o as low as 5 microM. Although smaller in amplitude to that observed at 2.2 mM [Ca2+]o the duration of the K(+)-induced secretory response increased at lower [Ca2+]o. 8. Transient vasopressin secretory responses were observed to sustained levels of [Ca2+] in digitonin and streptolysin-O-permeabilized nerve endings. Secretion could be re-evoked, following its decline, by a step increase in [Ca2+] or by removal and readdition of [Ca2+]o.(ABSTRACT TRUNCATED AT 400 WORDS)

Sodium-evoked, calcium-independent vasopressin release from rat isolated neurohypophysial nerve endings.

1. The effects of Na+ on vasopressin release and on redistribution of Ca2+, Na+ and H+ in isolated rat neurohypophysial nerve endings have been studied. 2. Substituting Na+ for a non-permanent cation produced a pronounced and sustained release of vasopressin. This increase occurred in the absence of external Ca2+ and in nerve endings loaded with the Ca2+ chelator dimethyl-BAPTA (1,2-bis-(O-aminophenoxy)ethane-N,N,N',N'-tetraacetic acid). 3. The effect of Na+ was independent of a rise in intracellular Ca2+ as judged by the measurement of [Ca2+]i using the indicator fura-2 and 45Ca2+ efflux studies. Although Na+ could release Ca2+ from internal reservoirs the small elevation in [Ca2+]i induced by Na+ could not explain the large and sustained increase in vasopressin secretion. 4. The channel blockers TTX (tetrodotoxin), D888 (desmethyoxyverapamil), N144 (5-nitro-2-(phenylpropylamino)-benzoic acid) or SITS (4-acetamido-4'-isothiocyanatostilbene-2,2'-disulphonic acid) could not prevent the Na(+)-dependent increase in vasopressin release. Similarly this increase was not affected by metabolic inhibitors (Ruthenium Red and KCN) nor by CCCP (carbonyl cyanide m-chlorophenylhydrazone), an uncoupler of oxidative phosphorylation. 5. Selectivity among monovalent cations to promote secretion was found with the largest effect on the secretory response being produced by Na+. Similarly Cl- was found to be the most potent anion studied for inducing, in the presence of Na+, an increase in neurohormone release. 6. Measuring [Na+]i by means of the Na+ indicator SBFI showed that the extent of the secretory response was correlated with the intraterminal Na+ concentration. 7. The Na(+)-induced, Ca(2+)-independent release of vasopressin occurred by exocytosis as judged (i) by the linear relationship between the amount of vasopressin secreted and that of the co-localized neurophysin and (ii) by the demonstration that the extracellular marker horseradish peroxidase was only found in endocytotic vacuoles and not in the cytoplasm of the stimulated nerve endings. 8. The Na(+)-dependent secretory response found on addition of extracellular Na+ was not the result of the change in internal pH as measured with the indicator BCECF and as mimicked by addition of propionic acid. 9. Addition of Na+ to digitonin- or streptolysin-O-permeabilized nerve endings in the presence or absence of Ca2+ also gave rise to an increase in vasopressin secretion. 10. It is concluded that an increase in internal Na+ per se can promote, in the absence of a rise in intracellular Ca2+, an increase in neuropeptide secretion.

G-proteins mediate inhibition and activation of Ca(2+)-induced exocytosis from SLO-permeabilized peptidergic nerve endings.

In SLO-permeabilized isolated nerve endings from the rat neurohypophysis, GTP, guanosine 5'[y-thio]triphosphate (GTPyS) and guanosine 5'(beta y-imido]triphosphate (GMPPNP) inhibit the Ca(2+)-evoked vasopressin release. Pretreatment with pertussis toxin enhances the inhibitory effects of both GTP-analogues. Omission of Mg2+ overcomes the effect of GMPPNP and reverses the inhibitory effect of GTP and GTPyS. In the absence of Mg2+, GTP and GTPyS now potentiate Ca(2+)-evoked secretion.

Exo-endocytosis in isolated peptidergic nerve terminals occurs in the sub-second range.

Exo- and endocytotic processes induced by depolarization of isolated neurosecretory nerve terminals show a close temporal correlation, which suggests a short time of integration of the neurosecretory granule membrane with the plasma membrane. In order to determine minimal time requirements for exocytosis-coupled endocytosis to occur, we have analyzed by electron microscopy uptake of horseradish peroxidase (HRP) as a fluid phase marker at the onset of depolarization. We have applied rapid mixing and sampling (quenched flow) to assess events in sub-second time periods after stimulation. A significant number of labelled endocytotic vacuoles was observed during the first second of depolarization. This number then further increased by a factor of about 2 (within 5 s) and 4 (within 50 s). Thus, as for exocytosis, the rate of endocytosis decreased considerably during prolonged stimulation. These data indicate i) that a substantial proportion of secretory granules undergoes exocytosis very shortly after stimulation, and ii) that, following exocytosis, the minimal time required for consecutive membrane retrieval is in the sub-second range.

Endothelin regulation of neuropeptide release from nerve endings of the posterior pituitary.

We have investigated the role of endothelin (ET) in the stimulus-secretion coupling mechanism in the posterior pituitary. We report that isolated nerve endings contain immunoreactive endothelin, the level of which is regulated by homeostatic mechanisms involved in control of water balance. ET-1 and ET-3 potentiate vasopressin release induced by depolarization through interaction with specific receptors of the ETA subtype and this response is antagonized by sarafotoxin S6b. The second messenger for this effect, however, remains unknown since the potentiation of depolarization-induced vasopressin release occurs in the absence of an increase in cellular calcium.

Membrane retrieval following exocytosis in isolated neurosecretory nerve endings.

In the neurosecretory nerve endings of the neurohypophysis depolarization-induced exocytosis is followed by endocytosis of vacuole-like structures with diameter similar to that of neurosecretory granules. However, it remains unknown whether the membrane of the endocytotic vacuoles is comprised primarily of retrieved secretory granule membrane, plasma membrane or of a mixture of the granule and plasma membrane. In the present paper membrane retrieval following depolarization-induced exocytosis has been studied in isolated neurosecretory nerve endings from the rat neurohypophysis. The origin of the retrieved membrane was assessed by pre-labeling the plasma membrane with an antibody against neural cell adhesion molecule, a plasma membrane specific protein. Horseradish peroxidase was used as an index of fluid endocytosis and secretion of vasopressin was measured by radioimmunoassay. Following potassium-induced depolarization, endocytotic vacuoles showed labeling with the fluid phase marker horseradish peroxidase but never showed significant neural cell adhesion molecule labeling. The time-course of endocytosis following closely that of exocytosis as endocytotic vacuoles labeled with horseradish peroxidase were only observed when the fluid phase marker was present in the extracellular medium during the period of evoked exocytosis. Our results are consistent with a model in which in neurosecretory nerve endings, after transient exocytotic fusion of the granule membrane with the plasma membrane, the granule membrane is rapidly and selectively retrieved into the nerve endings in the form of vacuoles similar in size to that of the neurosecretory granules.

Possible role during exocytosis of a Ca(2+)-activated channel in neurohypophysial granules.

Ion channels from bovine neurohypophysial granules were incorporated into artificial lipid bilayers. The larger amplitude channel is permeable to cations and exhibits multiple conductances. The channel opens only in the presence of free Ca2+, but is inhibited by relatively high Ca2+ concentrations. Release of vasopressin from permeabilized neurohypophysial terminals also shows a similar biphasic dependence on Ca2+. Release is selectively inhibited by low concentrations of the long-chain alcohol octanol, but not by high concentrations of ethanol, as is the neurosecretory granule Ca(2+)-activated cation channel. Furthermore, Ca(2+)-evoked release and channel activity are both inhibited by the long-chain tetraethylammonium analogs decamethonium and decyl-triethyl ammonium bromide. The close correlation between channel and release properties lead us to conclude that the Ca(2+)-activated channel is involved in peptide secretion.

The light chain of tetanus toxin inhibits calcium-dependent vasopressin release from permeabilized nerve endings.

The effects of tetanus toxin and its light and heavy chain subunits on vasopressin release were investigated in digitonin-permeabilized neurosecretory nerve terminals isolated from the neural lobe of the rat pituitary gland. Exocytosis was induced by challenging the permeabilized nerve endings with micromolar calcium concentrations. Tetanus toxin inhibited vasopressin release only in the presence of the reducing agent dithiothreitol. This effect was irreversible. The purified light chain of tetanus toxin strongly inhibited exocytosis in a dose-dependent manner with half-maximal effect at c. 10 nM. The action of the light chain was observed after only 2.5 min of preincubation. Separated heavy chain subunit had no effect on hormone secretion. Inhibition of vasopressin release could be prevented by preincubating the light chain of tetanus toxin with an immune serum against tetanus toxin. The data clearly demonstrate that in mammalian neurosecretory nerve endings tetanus toxin acts at a step downstream from the activation by Ca2+ of the exocytotic machinery and that the functional domain of this toxin is confined to its light chain.

Depolarization, intracellular calcium and exocytosis in single vertebrate nerve endings.

We have investigated the temporal relationship between depolarization, elevation of [Ca2+]i and exocytosis in single vertebrate neuroendocrine nerve terminals. The change of [Ca2+]i and vasopressin release were measured with a time resolution of less than 1 s in response to K(+)-induced depolarization. Exocytosis was also monitored in the whole-terminal patch-clamp configuration by time resolved capacitance measurements while [Ca2+]i was simultaneously followed by fura-2 fluorescence measurements. In intact as well as patch-clamped nerve terminals sustained depolarization leads to a sustained rise of [Ca2+]i. The rate of vasopressin release from intact nerve terminals rises in parallel with [Ca2+]i but then declines rapidly towards basal (t1/2 approximately 15 s) despite the maintained high [Ca2+]i indicating that only a limited number of exocytotic vesicles can be released. We demonstrate that in nerve terminals exocytosis can be followed during step depolarization by capacitance measurements. The capacitance increase starts instantaneously whereas [Ca2+]i rises with a half time of several hundred milliseconds. An instantaneous steep capacitance increase is followed by a slow increase with a slope of 25-50 fF/s indicating the sequential fusion of predocked and cytoplasmic vesicles. During depolarization the capacitance slope declines to zero with a similar time course as the vasopressin release indicating a decrease in exocytotic activity. Depolarization per se in the absence of a sufficient rise of [Ca2+]i does not induce exocytosis but elevation of [Ca2+]i in the absence of depolarization is as effective as in its presence. The experiments suggest that a rapid rise of [Ca2+]i in a narrow region beneath the plasma membrane induces a burst of exocytotic activity preceding the elevation of bulk [Ca2+]i in the whole nerve terminal.

Intracellular calcium and hormone release from nerve endings of the neurohypophysis in the presence of opioid agonists and antagonists.

Rat neural lobes and isolated nerve terminals from the neurohypophysis were stimulated in the presence of different opioid agonists and antagonists. The secretion of arginine vasopressin and oxytocin and rise in cytoplasmic calcium induced by depolarization were analyzed by radioimmunoassay and the fluorescent probe fura-2, respectively. The kappa-agonists dynorphin A(1-13) and dynorphin A(1-8) did not affect electrically evoked release of vasopressin, although oxytocin release was slightly reduced. U-50 488, a relatively specific kappa-receptor agonist, had no effect on the amount of vasopressin or oxytocin secreted, although it significantly reduced K(+)-evoked changes in [Ca2+]i in isolated nerve endings. Two kappa-receptor antagonists, MR 2266 and diprenorphin, alone had no effect on vasopressin and oxytocin secretion from isolated nerve endings depolarized with potassium. Opioid agonists less selective for the kappa receptors, etorphin and ethylketocyclazocin, were found to inhibit the release of both vasopressin and oxytocin significantly. Naloxone, a nonselective opiate receptor antagonist, alone had no effect on vasopressin release but potentiated the electrically evoked release of oxytocin. Naloxone also could overcome the inhibitory effect of etorphin on oxytocin and vasopressin release observed after electrical stimulation of the neural lobe. A number of inconsistencies therefore exist between the effects of opioid agonists and antagonists on neuropeptide release and on the evoked changes in [Ca2+]i. In view of these inconsistencies and the high concentrations of opioid agonists and antagonists necessary to modify release, we conclude that it is doubtful that opioid molecules have a physiological role in controlling neurohypophysial secretion.

Ca(2+)-independent regulation of neurosecretion by intracellular Na+.

While secretion from nerve endings is strictly controlled by an increase in cytoplasmic free calcium several reports suggest intracellular sodium may serve a regulatory role. Whether sodium acts directly to modulate secretion or indirectly by influencing cytoplasmic calcium dynamics is unknown. This study shows, based on parallel experiments studying [Na+]i, [Ca2+]i and vasopressin secretion, that sodium acts directly to regulate secretion in isolated nerve endings from the rat neurohypophysis. The elevation in secretion that develops is dose-dependently related to the [Na+]i and can occur in the absence of changes in [Ca2+]i.

Calcium currents and peptide release from neurohypophysial terminals are inhibited by ethanol.

The effects of EtOH on peptide release and on high-threshold, voltage-activated calcium (Ca++) channels were examined in acutely dissociated rat neurohypophysial terminals. These terminals release the peptide hormones, arginine vasopressin (AVP) and oxytocin. Release of AVP from isolated intact neurohypophyses, induced by either electrical stimulation or elevated potassium, was inhibited by clinically relevant concentrations of EtOH. "Whole-cell" patch-clamp recording methods were used to study the effects of EtOH on voltage-activated Ca++ currents (ICa) in the peptidergic nerve terminals. Amplitudes of both fast-inactivating ICa and long-lasting ICa were reduced in EtOH, and the reduction in ICa did not result from a shift in its current-voltage or steady-state inactivation relationships. Only the fast-inactivating component recovered after removal of EtOH. The effects of EtOH on ICa could not be attributed to changes in osmolarity. In contrast to ICa, the fast, transient K+ current was insensitive to EtOH. These results suggest that EtOH-induced reduction of ICa in the peptidergic nerve terminals produces a decrease in AVP release, resulting in lowered plasma AVP levels.

Ethanol reduces vasopressin release by inhibiting calcium currents in nerve terminals.

Ingestion of ethanol (EtOH) is known to result in a reduction of plasma arginine-vasopressin (AVP) levels in mammals. We examined the basis for this effect using a combination of biochemical and electrophysiological techniques. Release of AVP from nerve terminals isolated from the rat neurohypophysis was very sensitive to EtOH, with significant reductions in AVP release evident in 10 mM EtOH. However, EtOH did not affect the release of AVP from terminals which had been permeabilized with digitonin, suggesting that voltage-gated calcium channels might be the target of EtOH's actions. Patch clamping of these terminals indicated that both inactivating and long-lasting calcium currents were reduced in EtOH, but the long-lasting currents were more sensitive (significant reductions in 10 mM EtOH). EtOH-induced decreases in plasma AVP levels can be explained by EtOH's inhibition of calcium currents in the nerve terminals.

Effect of sodium and calcium on basal secretory activity of rat neurohypophysial peptidergic nerve terminals.

1. The release of arginine vasopressin (AVP) from a perifused preparation of peptidergic nerve terminals isolated from rat neurohypophyses was studied during manipulations of the external sodium and calcium concentrations. Intracellular concentrations of these two ions were manipulated by use of ouabain and a calcium ionophore, respectively. 2. Removal of extracellular Na+ caused, in a concentration-dependent manner, a significant decrease of secretory activity. Conversely, graded addition of Na+ to a Na(+)-free perifusion medium increased secretion. Half-maximal activation of secretory activity was attained at ca 75 mM [Na+]o. 3. Manipulations of extracellular Ca2+ did not affect the level of hormonal secretion in the absence of extracellular Na+. However, when Na+ was present in the perifusion medium, removal of extracellular Ca2+ induced an increase of secretory activity. 4. The effects of manipulations of [Na+]o were not dependent on the presence of Ca2+ in the perifusion medium nor on the nature of the Na+ replacement used (i.e. choline or mannitol). 5. Ouabain (0.1 mM) increased the basal secretory activity and potentiated the secretory response to removal of Ca2+ from the perifusion medium. 6. The Ca2+ ionophore A23187 stimulated, in a concentration-dependent fashion, the secretory activity of the peptidergic nerve terminals and this stimulation was strictly dependent on the presence of Ca2+ in the perifusion medium. 7. These results show that basal secretion is directly dependent on [Na]o and indicate that intracellular Na+ is an important factor in the control of secretory mechanisms. Evidence is presented in regard to a possible antagonistic effect of extracellular Ca2+ and Na+ on secretion.