Involvement of DHP voltage-sensitive calcium channels and protein kinase C in thyroliberin (TRH) release by developing hypothalamic neurons in culture

Contribution of L-type Ca(2+) channels to evoked transmitter release in cultured Xenopus nerve-muscle synapses

1. Simultaneous pre- and postsynaptic patch recordings were obtained from the varicosity synapses formed by Xenopus motoneurons on muscle cells in embryonic cultures, in order to elucidate the contribution of N- and L-type Ca(2+) channels to the varicosity Ca(2+) current (I(Ca)) and evoked transmitter release. 2. Although N-type channels are predominant in the varicosities and generally thought to be responsible for all evoked release, in most synapses a fraction of I(Ca) and release could be reversibly blocked by the L-type channel antagonist nifedipine, and enhanced by the agonist Bay K8644. Up to 50 % (mean, 21 %) of the I(Ca) evoked by a voltage clamp waveform mimicking a normal presynaptic action potential (APWF) is composed of L-type current. 3. Surprisingly, the nifedipine-sensitive (L) channels activated more rapidly (time-constant, 0.46 ms at +30 mV) than the nifedipine-insensitive (N) channels (time constant, 1.42 ms). Thus the L-type current would play a disproportionate role in the I(Ca) linked to a normal action potential. 4. The relationship between I(Ca) and release was the same for nifedipine-sensitive and -resistant components. The N- and L-components of I(Ca) are thus equally potent in evoking release. This may represent an immature stage before N-type channels become predominant. 5. Replacing Ca(2+) in the medium with Ba(2+) strongly enhanced the L-type component, suggesting that L-type channels may be inactivated at Ca(2+) levels close to those at rest. 6. We speculate that populations of L-type channels in different parts of the neuron may be recruited or inactivated by fluctuations of the cytosolic Ca(2+) concentration within the physiological range.

Development of pro-TRH gene expression in primary cultures of fetal hypothalamic cells

Little is known about the temporal relationship and the sequential steps for peptide biosynthesis during the terminal differentiation of the peptide phenotype in central nervous system. Analysis of the TRH phenotype in primary cultures of rat fetal day 17 hypothalamic cells has shown that TRH levels start increasing only after a week in culture, in contrast with in vivo data showing a steady increase during late fetal life. The purpose of this study was to compare the developmental patterns of TRH and pro-TRH mRNA levels in vitro to determine whether the initial low and steady levels of TRH are due to deficient transcription. Pro-TRH mRNA levels were detected by semi-quantitative RT-PCR through the development of primary cultures of serum-supplemented hypothalamic fetal cells from 17 day old embryos. Pro-TRH mRNA levels per dish increased steadily since the beginning of the culture. In contrast, TRH levels per dish were low and stable during the first week increasing afterwards, but remaining low compared to equivalent in vivo values. Pro-TRH mRNA levels per hypothalamus increased between fetal day 17 and postnatal 14, suggesting that the in vitro pattern of pro-TRH mRNA development mimics that occurring in vivo. These data show that pro-TRH gene expression does not limit TRH accumulation in vitro suggesting that the transcriptional and post-transcriptional programs leading to peptide accumulation are established independently.

Modulation of neurotransmitter release by dihydropyridine-sensitive calcium channels involves tyrosine phosphorylation

Cultured rat cerebellar granule cells depolarized by high KCl, display a large component of Ca2+ influx through L-type voltage-dependent Ca2+ channels as defined by a sensitivity to 1 microM nifedipine. This Ca2+ influx is not coupled to neurotransmitter exocytosis but has implications for neuronal development. KCl stimulation in the absence of external Ca2+ followed by the readdition of Ca2+ allows the coupling of a class of L-type Ca2+ channels to neurotransmitter exocytosis as assessed by loading of glutamatergic pools with [3H]-D-aspartate. KCl stimulation in the absence of external Ca2+ ('predepolarization') enhances tyrosine phosphorylation of several cellular proteins, and inhibitors of tyrosine kinases block both phosphorylation and the neurotransmitter release coupled to the L-type Ca2+ channel. More specifically, an inhibitor of src family tyrosine kinases, PP1, blocks the effects of predepolarization suggesting a role for a src family kinase in the process. Furthermore, L-type Ca2+ channel recruitment and modulation of release could be activated with the tyrosine phosphatase inhibitor sodium orthovanadate. The phosphoproteins enhanced by predepolarization, which include the cytoskeletal proteins focal adhesion kinase (FAK) and vinculin, are also highly phosphorylated early on in culture when neurite outgrowth occurs. As the neurons develop a network of neurites, both tyrosine phosphorylation and L-type Ca2+ channel activity decrease. These results show a novel mechanism for the recruitment of L-type Ca2+ channels and their coupling to neurotransmitter release which involves tyrosine phosphorylation. This phenomenon has a role in cerebellar granule cell development.

Effect of short photoperiods on the in vitro GnRH release by hypothalamic explants in intact and castrated male Syrian hamsters: relation to testicular regression and recrudescence

Prolonged exposure of adult Syrian hamsters to short days decreases LH and FSH circulating levels within 2-4 weeks, then induces testicular regression. After 18 weeks of short days, the testis size and gonadotropin levels increase spontaneously. This study investigated whether these phases of photosensitivity and photorefractoriness corresponded to variations of in vitro GnRH release. Male hamsters were either kept under long days (LD 16:8) or transferred to short days (SD 6:18) and sacrificed from 2-26 weeks after transfer. To separate the effects of testis feedback from a possible direct photoperiodic drive on the hypothalamus, males were bilaterally castrated, kept under LD or transferred to SD, and sacrificed from 2-14 weeks after transfer. Hypothalamic explants were incubated in a saline buffer for three periods of 15 min and exposed to KCl (60 mM) for 15 min. The return to basal values was followed for six periods of 15 min, then the explants were stimulated with copper complexed equimolarly with histidine (Cu/His, 200 microM) and prostaglandin E2 (PGE2, 10 microM). At the end of the incubation period, the concentration of GnRH remaining in the explants was measured. In intact males, GnRH release in vitro increased significantly between 2 and 4 weeks after transfer to short days; it returned to values similar to LD ones between 6 and 12 weeks, during the phase of testis involution. At the beginning of photorefractoriness (SD 14-18), it increased transiently and returned to values similar to LD ones from SD 20, during the testis spontaneous recrudescence. After castration, the in vitro GnRH release decreased significantly under LD and SD. The transfer of castrated hamsters to SD resulted in transient increases of GnRH release (SD 4, 8 and 14), and in a progressive loss of the explant's ability to release GnRH in vitro. These results showed a photoperiodic regulation of in vitro GnRH release and a testis feedback effect on this release. They demonstrated an inverse relationship between the readily releasable pool of GnRH and the circulating levels of gonadotrophins at the beginning of photosensitive and photorefractory phases and after castration.

Regulatory role of ATP at developing neuromuscular junctions

Neuronal factors co-released with neurotransmitters may play an important role in synaptic development and function. Extracellular application of adenosine 5'-triphosphate (ATP), a substance co-stored and co-released with acetylcholine (ACh) in peripheral nervous systems, potentiated the spontaneous secretion of ACh at developing neuromuscular synapses in Xenopus 1-day-old cell cultures, as shown by a marked increase in the frequency of spontaneous synaptic currents recorded in the post-synaptic muscle cell. ATP also increased the frequency of miniature endplate potentials in the isolated tails of 2-week-old Xenopus tadpoles, with much smaller effect than that observed in cell cultures. The potentiation effect of ATP on ACh release in Xenopus cell cultures was inhibited by L-type Ca2+ channel blockers, suggesting that the L-type Ca2+ channel is responsible for the positive regulation of spontaneous ACh secretion by ATP at the developing neuromuscular synapses. The frequency of spontaneous synaptic events was found to vary greatly from cell to cell in the culture, over two orders of magnitude. Synapses with high frequency events are probably under the influence of endogenously released ATP. In addition, ATP was shown to potentiate the responses of isolated myocytes to iontophoretically-applied ACh. Local application of ATP to one region of the elongated myocyte surface resulted in potentiated ACh responses only at the ATP-treated region. Single channel recording showed that ATP specifically increased the open time and opening frequency of embryonic-type, low conductance ACh channels. Pharmacological experiments suggest that ATP exerted both its pre- and post-synaptic effects by binding to P2-purinoceptors and activating protein kinase C. Moreover, the potentiation effects of ATP were restricted to the early stages of embryos. Taken together, these results suggest that ATP co-released with ACh or released from stimulated myocytes may promote synaptic development by potentiating pre-synaptic ACh release and post-synaptic ACh channel activity during the early phase of synaptogenesis.

Potentiation by endogenously released ATP of spontaneous transmitter secretion at developing neuromuscular synapses in Xenopus cell cultures

1. Previously we have shown that extracellular application of ATP, a substance co-stored and co-released with acetylcholine (ACh) in the peripheral nervous system, markedly potentiated the frequency of spontaneous synaptic currents (SSCs) produced by ACh. In the present study, we have further characterized the purinoceptor which mediates the potentiation effect of ATP and the role of endogenously released ATP. 2. Pretreatment with a P2-purinoceptor antagonist, suramin (0.3 mM), but not a P1-purinoceptor antagonist, 8-phenyltheophylline (0.1 mM), prevented the potentiating effect of ATP. 3. We studied the role of endogenously released ATP by examining the effect of a specific P2-purinoceptor antagonist on the frequency of spontaneous synaptic events at high-activity synapses (> or = 3 Hz) and found that suramin, but not 8-phenyltheophylline markedly reduced the frequency of SSCs at these high-activity synapses. In addition, desensitizing the P2-purinoceptor with alpha,beta-methylene ATP also produced similar effects to suramin. 4. Extracellular application of the L-type Ca2+ channel blockers, verapamil, nifedipine or diltiazem (10 microM each) reduced SSC frequency of high-activity synapses, while the N-type Ca2+ channel blocker, omega-conotoxin had no appreciable effect. The potentiating effect of ATP was further prevented by pretreatment with the L-type Ca2+ channel blockers. On the other hand, Bay K 8644, which is a depolarization-dependent L-type Ca2+ channel agonist, potentiated SSC frequency at these high-activity synapses. 5. These results suggest that endogenous release of ATP at developing neuromuscular synapses is responsible for the maintenance of high levels of spontaneous ACh release, which is known to play a crucial role in regulating postsynaptic differentiation.

L-type Ca2+ channel is involved in the regulation of spontaneous transmitter release at developing neuromuscular synapses

Involvement of an L-type Ca2+ channel in the regulation of spontaneous transmitter release was studied in Xenopus nerve-muscle cultures. The frequency of spontaneous synaptic currents, which reflects impulse-independent acetylcholine release from the nerve terminals, showed a marked increase in high-K+ medium or after treatment with a phorbol ester, 12-O-tetradecanoyl-phorbol 13-acetate, a drug that activates protein kinase C and depolarizes the presynaptic neuron. The potentiation effect of high K+ and 12-O-tetradecanoyl-phorbol 13-acetate requires Ca2+ influx through the L-type Ca2+ channel in the plasma membrane, since it was significantly reduced by the presence of nifedipine, verapamil or diltiazem and enhanced by Bay K 8644, an L-type Ca2+ channel agonist. It was shown recently that adenosine 5'-triphosphate markedly potentiates the spontaneous acetylcholine release at these synapses through the binding of P2-purinoceptors and the activation of protein kinase C. We found in the present study that potentiation effects of adenosine 5'-triphosphate are inhibited by L-type Ca2+ channel blockers, suggesting that the L-type Ca2+ channel is responsible for the positive regulation of spontaneous acetylcholine secretion by adenosine 5'-triphosphate at the developing neuromuscular synapses. Our data suggest that modulation of the L-type Ca2+ channel in embryonic motor nerve terminals is important for the regulation of spontaneous transmitter release.

Omega-conotoxin- and nifedipine-insensitive voltage-operated calcium channels mediate K(+)-induced release of pro-thyrotropin-releasing hormone-connecting peptides Ps4 and Ps5 from perifused rat hypothalamic slices

The rat thyrotropin-releasing hormone (TRH) precursor (prepro-TRH) contains five copies of the TRH progenitor sequence linked together by intervening sequences. Recently, we have shown that the connecting peptides prepro-TRH-(160-169) (Ps4) and prepro-TRH-(178-199) (Ps5) are released from rat hypothalamic neurones in response to elevated potassium concentrations, in a calcium-dependent manner. In the present study, the role of voltage-operated calcium channels in potassium-induced release of Ps4 and Ps5 was investigated, using a perifusion system for rat hypothalamic slices. The release of Ps4 and Ps5 stimulated by potassium (70 mM) was blocked by the inorganic ions Co2+ (2.6 mM) and Ni2+ (5 mM). In contrast, the stimulatory effect of KCl was insensitive to Cd2+ (100 microM). The dihydropyridine antagonist nifedipine (10 microM) had no effect on K(+)-evoked release of Ps4 and Ps5. Furthermore, the response to KCl was not affected by nifedipine (10 microM) in combination with diltiazem (1 microM), a benzothiazepine which increases the affinity of dihydropyridine antagonists for their receptor. The dihydropyridine agonist BAY K 8644, at concentrations as high as 1 mM, did not stimulate the basal secretion of Ps4 and Ps5. In addition, BAY K 8644 had no potentiating effect on K(+)-induced release of Ps4 and Ps5. The marine cone snail toxin omega-conotoxin, a blocker of both L- and N-type calcium channels had no effect on the release of Ps4 and Ps5 stimulated by potassium. Similarly, the omega-conopeptide SNX-111, a selective blocker of N-type calcium channels, did not inhibit the stimulatory effect of potassium. The release of Ps4 and Ps5 evoked by high K+ was insensitive to the non-selective calcium channel blocker verapamil (20 microM). Amiloride (1 microM), a putative blocker of T-type calcium channels, did not affect KCl-induced secretion of the two connecting peptides. Taken together, these results indicate that two connecting peptides derived from the pro-TRH, Ps4 and Ps5, are released by K(+)-induced depolarization through activation of voltage-sensitive calcium channels. The calcium channels appear to have a pharmacological profile different from that of L- and N-type channels. Although, their insensitivity to low Cd2+ concentrations and sensitivity to Ni2+ ions would support the involvement of T-type calcium channels, the lack of effect of amiloride suggests that they belong to a yet undefined class of calcium channels.

Ionic currents in cultured rat hypothalamic neurones

1. Dissociated neurones from embryonic rat hypothalamus were grown for several weeks in culture where they formed complex networks. These synaptically coupled networks were capable of generating synchronized bursting activity. Voltage-activated membrane currents were studied in these neurones using a patch clamp in the whole-cell configuration. 2. Outward currents were carried by K+ ions and consisted of an inactivating and a non-inactivating component. These components were similar to the transient K+ current (IA) and the delayed rectifier current (IK) reported in neurones from the postnatal rat hypothalamus. Application of Zn2+ (1 mM) blocked the transient component completely while reducing the non-inactivating component by only approximately 20%. 3. Inward currents were carried by Na+ and Ca2+ ions. Rapidly activating transient Na+ currents were activated at approximately -25 mV. TTX entirely blocked these currents at low concentration (300 nM). Voltage sensitivity of the Na+ conductance was 5.8 mV per e-fold change with half-maximal activation occurring at -8 mV. Na+ current kinetics could be well described by the Hodgkin-Huxley model (m3h). 4. With depolarizing pulses from a holding potential of -80 mV two Ca2+ current components with different ranges of activation were identified. Low voltage-activated (LVA, T-type) Ca2+ currents were activated at approximately -50 mV. High voltage-activated (HVA; also called L- or N-type) Ca2+ currents were observed at membrane potentials more positive to approximately -30 mV. LVA Ca2+ currents were observed in hypothalamic neurones that had developed a network of dendritic processes in the course of several weeks in culture. Activation and inactivation time constants of LVA Ca2+ currents were 15-25 ms and 30-100 ms (-30 to -45 mV). In contrast to HVA Ca2+ currents, no LVA Ca2+ currents were seen in neuronal somata obtained from the network cultures by mechanical dissociation. This suggests that most of the LVA Ca2+ channels are located on the dendritic tree rather than on the soma membrane. 5. HVA Ca2+ currents were maximal between 0 and +10 mV (external [Ca2+] = 5 mM). The time-to-peak was in the range of 1.7-5.4 ms (+30 to -10 mV). Tail currents following repolarization decayed monoexponentially with a time constant of approximately 210 microseconds. During 500 ms depolarizations, 90% of the current inactivated. The time course of inactivation showed two time constants of approximately 40 and approximately 700 ms.(ABSTRACT TRUNCATED AT 400 WORDS)

Differential expression and subcellular localization of secretogranin II and synaptophysin during early development of mouse hypothalamic neurons in culture

Mature neurons contain two distinct regulated secretory pathways, characterized electron microscopically by so-called large dense core vesicles and small synaptic vesicles, respectively. Each vesicle type is characterized by vesicle-specific proteins, such as the granins (chromogranins/secretogranins) for the matrix of large dense core vesicles and synaptophysin for the membrane of small synaptic vesicles. So far, no data exist on the biogenesis of these two distinct vesicle types during neuronal development. We have used secretogranin II and synaptophysin as markers for the biogenesis of these two vesicle types during the development of mouse hypothalamic neurons in culture, using immunocytochemistry and biochemical analyses. By immunofluorescence, we found that secretogranin II appears as early as synaptophysin, but in a subset of neurons only, and with different subcellular localizations. It was observed in cytoplasmic areas where little or no synaptophysin immunofluorescence was detected, such as lamellipodia, emerging neurites and growth cones. At later stages, the proportion of secretogranin II-containing varicosities remained steady whereas that of synaptophysin-containing varicosities increased dramatically. By quantitative analysis we found that the level of expression of synaptophysin increased several-fold during synaptogenesis whereas that of secretogranin II decreased. These data suggest that large dense core vesicles and small synaptic vesicles can be formed separately and expressed at different levels. They provide evidence for a differential biogenesis of these two distinct vesicle types.

Ontogeny of thyrotropin-releasing hormone biosynthesis and release in hypothalamic neurons

Thyrotropin-releasing hormone (TRH) is expressed at early postmitotic stages of hypothalamic neuron development, in the mouse and rat, as revealed by the presence of the mature peptide, of pro-TRH mRNAs, and of large precursor forms. This indicates a coordinate expression of several genes encoding, respectively, pro-TRH, its processing enzymes, and the cell machinery for intracellular transport, sorting, and release of TRH. During development, an acceleration of pro-TRH processing is revealed by an increased proportion of the mature peptide. This is correlated with changes in the respective distribution of pro-TRH and TRH along neurites and the ontogenesis of neurosecretory granules.

Single calcium channels on a cholinergic presynaptic nerve terminal

The calyx-type synapse of the chick ciliary ganglion was used to examine single calcium channels in a vertebrate cholinergic presynaptic nerve terminal by means of the cell-attached, patch-clamp technique. Calcium channels were recorded on the internal, transmitter-release face of the nerve terminal, but were not detected on the external face. These channels were recruited at -30 mV, with maximum activation at about +30 mV, and were sometimes clustered at high densities. Single-channel conductance estimates with voltage-pulse or -ramp techniques gave values of 11-14 pS with 110 mM barium, which is in the intermediate, N-type range for calcium channels on a control neuron. This nerve terminal calcium channel, termed the NPT-type, may link action potentials to transmitter release at many vertebrate fast-transmitting synapses.

Release of pro-thyrotropin-releasing hormone connecting peptides PS4 and PS5 from perifused rat hypothalamic slices

Thyrotropin-releasing hormone prohormone contains five copies of the thyrotropin-releasing hormone progenitor sequence Gln-His-Pro-Gly, each flanked by pairs of basic amino acids and separated by intervening sequences (connecting peptides). Using a perifusion system for rat hypothalamic slices, we have studied the ionic mechanisms underlying the release of two connecting peptides originating from the thyrotropin-releasing hormone precursor: prepro-thyrotropin-releasing hormone-(160-169) (Ps4) and prepro-thyrotropin-releasing hormone-(178-199) (Ps5). Quantification of these two peptides in the effluent fluid was performed using sensitive and highly specific radioimmunoassay procedures. Reverse phase high performance liquid chromatography analysis of the effluent perifusate showed that released peptides co-eluted with synthetic Ps4 and Ps5. The secretion of Ps4 and Ps5 was stimulated by depolarizing agents such as (i) high potassium concentrations, (ii) ouabain, an Na+/K(+)-ATPase inhibitor, and (iii) veratridine, a stimulator of voltage-operated Na+ channels. The response to potassium (70 mM) was not affected by the specific Na+ channel blocker tetrodotoxin. The K+ channel blocker tetraethylammonium did not modify K(+)-evoked release of Ps4 and Ps5. These data suggest that voltage-operated Na+ channels are not involved in the stimulatory effect of high K+ on the release of Ps4 and Ps5. The lack of effect of picrotoxin, a Cl- channel blocker, on the secretion of the connecting peptides indicates that chloride ions play a minor role in the release process. In contrast, deprivation of Ca2+ in the perifusion medium suppressed K(+)-evoked release of the two peptides, indicating that voltage-operated Ca2+ channels are implicated in the release process. Taken together, the present results show that non-thyrotropin-releasing hormone peptides originating from the thyrotropin-releasing hormone precursor are secreted by mediobasal hypothalamic fragments. The release of these peptides is stimulated by depolarization through a calcium-dependent process. These data indicate that Ps4 and Ps5 may be released at the level of the median eminence into the portal circulation, suggesting that these peptides may play a role in the control of anterior pituitary cells.

Functional maturation of somatostatin neurons and somatostatin receptors during development of mouse hypothalamus in vivo and in vitro

Ontogenesis of somatostatin (SRIF) neurons and receptors was studied in fetal hypothalamic cell cultures kept in serum-free medium, and compared to the in vivo developmental pattern. Initial rise in neuronal content of SRIF occurred later in vitro than in vivo. In vitro, K(+)-induced SRIF release was only present after synaptogenesis. SRIF binding sites were measurable as early as 1 day after birth and at an equivalent time in culture, after 6 days in vitro (DIV); their affinity was in the nanomolar range. In cultured cells, binding reached a maximum at two weeks in vitro and decreased sharply thereafter as a consequence of binding site occupancy by the endogenous ligand. Indeed, pretreatment with cysteamine decreased SRIF concentration in the neuronal cultures and twice as many binding sites as in control cultures of 21 DIV were measured. Competition kinetics using unlabelled SMS 201-995 to displace [125I]SRIF revealed two distinct binding sites in the neuronal preparations (IC50 = 11 +/- 3 pM and 4.5 +/- 0.8 nM). In contrast, only the lower affinity site was present on glial cell preparations (1.7 +/- 0.4 nM). SRIF inhibited adenylate cyclase activity in glia and neurons, and the onset of SRIF coupling to the second messenger occurred earlier in vitro than in vivo. Pertussis toxin pretreatment was equally effective in neuronal and glial cell preparations to decrease SRIF binding and to inhibit adenylate cyclase activity.

Calcium currents recorded from a vertebrate presynaptic nerve terminal are resistant to the dihydropyridine nifedipine

The influx of Ca ions into the presynaptic nerve terminal through ion channels is a key link between the action potential and the release of chemical transmitters. It is not clear, however, which types of Ca channel are involved in neurosecretion at vertebrate synapses. In particular, there is disagreement as to whether these channels are sensitive to dihydropyridine blockers, characteristic of L-type Ca channels. We have used the chicken ciliary ganglion calyx synapse to test the effect of the dihydropyridine nifedipine on Ca current recorded directly from a cholinergic presynaptic nerve terminal. We used a control neuron to define the experimental conditions under which L-type Ca channels are blocked by 10 microM nifedipine. We then tested the effect of the dihydropyridine on Ca currents recorded from the presynaptic terminal using the same conditions. Nifedipine did not reduce the calyx Ca current nor did it block chemical transmission through the ganglion. The lack of effect of the dihydropyridine was not due to restricted access since omega-conotoxin GVIA, a peptide toxin that blocks transmission at this synapse, rapidly blocked the calyx Ca current. Thus, the predominant Ca channel in this presynaptic nerve terminal is not dihydropyridine sensitive and, hence, cannot be characterized as L-type.

Effects of ions and ionic channel activators or blockers on release of alpha-MSH from perifused rat hypothalamic slices

The involvement of sodium and chloride ions in the process of alpha-melanocyte-stimulating hormone (a-MSH) release from hypothalamic neurons was investigated using perifused rat hypothalamic slices. Three different stimuli were found to increase a-MSH release from hypothalamic slices: high K+ concentration (50 mM), veratridine (50 microM), and the Na+/K(+)-ATPase inhibitor ouabain (1 mM). Spontaneous or K(+)-evoked a-MSH release was insensitive to the specific Na+ channel blocker tetrodotoxin (TTX; 1.5 microM) and to the blocker of K+ channels tetraethylammonium (TEA; 30 mM) or 4-aminopyridine (4-AP; 4 mM). In contrast, blockage of ouabain-sensitive Na+/K(+)-ATPase increased the resting level of a-MSH and caused a dramatic potentiation of K(+)-evoked a-MSH release. The Na+ channel activator veratridine (50 microM) triggered a-MSH release. This stimulatory effect was blocked by TTX and prolonged by TEA application, indicating the occurrence of voltage-sensitive Na+ and K+ channels on a-MSH neurons. Replacement of Na+ by impermeant choline ions from 95 to 60 mM did not alter K(+)-evoked a-MSH release. Conversely, dramatic reduction of the external Na+ concentration to 16 mM caused a robust increase of a-MSH secretion from hypothalamic neurons, likely through activation of the Na+/Ca2+ exchange system. These data indicate that the depolarizing effect of K+ results from direct activation of voltage-operated Ca2+ channels. The lack of effect of TEA on basal a-MSH release prompted us to investigate the possible involvement of chloride ions in the regulation of the spontaneous activity of a-MSH neurons. Substitution of Cl- for impermeant acetate ions did not affect basal or K(+)-evoked a-MSH release.(ABSTRACT TRUNCATED AT 250 WORDS)

Involvement of voltage-operated calcium channels in alpha-melanocyte-stimulating hormone (alpha-MSH) release from perifused rat hypothalamic slices

The contribution of voltage-operated calcium (VOC) channels in the mechanism of release of alpha-melanocyte-stimulating hormone (alpha-MSH) from hypothalamic neurons was investigated using perifused rat hypothalamic slices. The stimulatory effect of potassium (50 mM) on alpha-MSH release was completely blocked by cadmium (1 mM) a calcium competitor which indifferently blocks T-, L-and N-type VOC channels. To determine the nature of calcium conductances involved in K+-evoked alpha-MSH release, we have investigated the effect of a VOC channel agonist and 3 antagonists on the secretion of the neuropeptide. Administration of synthetic omega-conotoxin fraction GVIA (1 microM), a peptide toxin which blocks both N- and L-type VOC channels, reduced by 33% K+-induced alpha-MSH release. In contrast, the 1,4-dihydropyridine (DHP) antagonist nifedipine, at concentrations up to 100 microM, did not affect the response of hypothalamic alpha-MSH neurons to depolarizing concentrations of KCl. In addition, the secretion of alpha-MSH induced by high K+ concentrations was not reduced by nifedipine (10 microM) in the presence of diltiazem (1 microM), a benzothiazepine derivative which increases the affinity of the DHP antagonist for L-type VOC channels. The DHP agonist BAY K 8644 (0.1-10 microM) did not modify the early phase of the response of alpha-MSH neurons to K+-induced depolarization. In contrast BAY K 8644 (1 or 10 microM) significantly prolonged the duration of K+-induced alpha-MSH release. This sustained release of alpha-MSH induced by BAY K 8644 (10 microM) was totally suppressed by nifedipine (10 microM).(ABSTRACT TRUNCATED AT 250 WORDS)

Identification of ionic currents at presynaptic nerve endings of the lizard

1. Ionic currents associated with the invasion of an action potential into the motor nerve ending of the lizard, Anolis carolinensis, were measured with a focal extracellular electrode at several locations along the nerve ending. 2. These experimentally observed currents could be matched with computer simulations of action potential propagation into the nerve ending. They revealed that while Na+ channels are the major ionic current pathway in the heminode, K+ channels provide the major pathway in the terminal branches and boutons. 3. Calcium current in the presynaptic ending was unmasked by the application of tetraethylammonium (TEA). This current was blocked by: (a) cadmium, (b) omega-conotoxin GVIA and (c) nifedipine, but was unaffected by nickel at concentrations less than or equal to 100 microM. Nifedipine's action became more definitive when the duration of the action potential was greatly extended by pre-treatment with TEA. The effect of Bay K 8644 was inconsistent. 4. Transmitter release, as measured by postsynaptic current, had a pharmacological response profile similar to that of the Ca2+ current, with the exception that transmitter release was increased reliably and reversibly by Bay K 8644. 5. This pharmacological response profile is identical to that of the L type Ca2+ channel identified by Fox, Nowycky & Tsien (1987 alpha) in chick dorsal root ganglion neurones. We saw no evidence for more than a single type of Ca2+ channel in lizard motor nerve endings. 6. A calcium-activated K+ current IK(Ca) was revealed by application of 3,4-diaminopyridine (DAP), a delayed-rectifier K+ channel blocker. This K(Ca) current was blocked by TEA, charybdotoxin and by substitution of cobalt for extracellular calcium.