Serotonin and cyclic GMP both induce an increase of the calcium current in the same identified molluscan neurons

Serotonin (5-HT) has previously been shown to evoke an increase in the duration of the Ca2+-dependent spike of molluscan neurons by decreasing the S current (Klein et al., 1982), a K+ current controlled by cAMP. However, in a group of identified ventral neurons of the snail Helix aspersa in which 5-HT (1-10 microM) also prolonged the duration of the Ca2+-dependent action potential, no 5-HT-induced depression of S current or of any other outward current was observed. Instead, 5-HT was found to evoke the prolongation of the somatic spike by inducing an increase in Ca2+ membrane conductance. This 5-HT-induced increase of Ca2+-current was mimicked neither by the intracellular injection of cAMP nor by the extracellular application of forskolin (20 microM). In contrast, it was mimicked by the intracellular injection of cGMP and by the extracellular application of 100 nM zaprinast, a cGMP-phosphodiesterase inhibitor. The extracellular application of phorbol ester TPA (100 nM), an activator of protein kinase C, was also found to increase the Ca2+ current in the identified snail ventral neurons, but this enhancing effect had a different time course from that induced by 5-HT. These results indicate that there is a second mechanism for prolonging the Ca2+ spike of molluscan neurons, consisting of an increase in Ca2+ current, in which cGMP may play a role as second messenger.     

Differential effects of pentylenetetrazole on ion currents of Aplysia neurones

The effect of the convulsant drug pentylenetetrazole (PTZ) on separated membrane current components has been studied in identified voltage-clamped Aplysia neurones. External PTZ blocks the voltage-dependent Na+, Ca2+ currents and the delayed rectifier current (INa, ICa and IK,V, respectively). The amplitude of the Ca2+-activated K+ current (IK,Ca) is increased. The amplitude of the fast inactivating K+ current (IA) is transiently increased at low concentrations of PTZ but is depressed at higher concentrations or after long-lasting application of the drug. The effect of PTZ on leakage current (IL) seems to depend on the cell type. In some cells (R-15, L-7, LP-1) IL is decreased while it is increased in other cells (L-11, BL-1, BR-1). PTZ accelerates the inactivation of IK,V and IA and shifts the current-voltage relation of ICa to negative voltages by 5-8 mV. Pressure injection of PTZ into the neurone did not affect IK,V or IK,Ca. Thus PTZ seems to act on the outside of the plasma membrane. The effect of external PTZ on INa, ICa, IK,V and IL is also observed if the internal Ca2+ activity is buffered with EGTA suggesting that an increase in the internal Ca2+ activity is not involved. At -40 mV PTZ induces a tetrodotoxin-insensitive inward current carried by Na+ ions. PTZ transforms the beating pacemaker cell L-11 into a bursting pacemaker and the bursting pacemaker cell R-15 exhibits 'square-wave'-like oscillations of the membrane potential.     

Calcium regulation of neurite elongation and growth cone motility

Neurite outgrowth from isolated, identified molluscan (Helisoma trivolvis) neurons in culture can be suppressed by neurotransmitters and electrical activity, both of which increase intraneuronal Ca2+ levels (Haydon et al., 1984; Cohan et al., 1986, 1987). We explored the possibility of a causal relationship between Ca2+ influx from the cell exterior and neurite outgrowth using a spectrum of pharmacological manipulations known to affect transmembrane Ca2+ flux. Ca2+ ionophore A23187, an agent expected to increase Ca2+ influx, suppressed both elongation and motile growth cone structures (i.e., filopodia and lamellipodia) in a dose-dependent (10(8)-10(6) M) and reversible manner. Furthermore, high concentrations of Ca2+ channel blockers (La3+, Cd2+, Co2+; e.g., 10(-4) M La3+) suppressed both elongation and growth cone movements. These data support previous experiments, which indicated that neurite outgrowth is dependent upon a specific range of intracellular Ca2+ concentrations (Connor, 1986; Cohan et al., 1987). However, tests of the dose-dependency of the effects of Ca2+ channel blockers on outgrowth revealed that specific, low concentrations of Ca2+ channel blockers (e.g., 10(-5) M La3+) caused, simultaneously, a reduction of growth cone filopodia and an acceleration of elongation. Consistent with the results using low levels of Ca2+ channel blockers, reduced extracellular Ca2+-stimulated neurite elongation while suppressing growth cone motility. Finally, neurotransmitter regulation of neurite outgrowth was shown to require influx of extracellular Ca2+; serotonin inhibition of neuron B19 was prevented by La3+ (10(-5) M) or by incubation in a reduced Ca2+ environment. Taken together, these results indicate that there are optimum levels of Ca2+ influx that promote normal neurite elongation and growth cone movements; these 2 components of outgrowth appear to have differential sensitivities to Ca2+.     

Depletion of serotonin in the nervous system of Aplysia reduces the behavioral enhancement of gill withdrawal as well as the heterosynaptic facilitation produced by tail shock

Noxious stimuli, such as electrical shocks to the animal's tail, enhance Aplysia's gill- and siphon-withdrawal reflex. Previous experimental work has indicated that this behavioral enhancement, known as dishabituation (if the reflex has been habituated) or sensitization (if it has not been habituated), might be mediated, at least in part, by the endogenous monoaminergic transmitter serotonin (5-HT). To assess 5-HT's role in dishabituation and sensitization of Aplysia withdrawal reflex, we treated Aplysia with the serotonergic neurotoxin 5,7-dihydroxytryptamine (5,7-DHT). We found that 5,7-DHT treatment significantly reduced the dishabituation of the withdrawal reflex produced by tail shock. Treatment with the neurotoxin also blocked the heterosynaptic facilitation of monosynaptic connections between siphon sensory neurons and their follower cells, which contributes to the behavioral enhancement. Analysis by high-performance liquid chromatography indicated that 5,7-DHT treatment significantly reduced 5-HT levels in the Aplysia CNS. Moreover, the neurotoxic effects of 5,7-DHT appeared to be relatively specific for serotonergic pathways. Thus, 5,7-DHT treatment did not disrupt the ability of nonserotonergic facilitatory interneurons, the L29 cells, to facilitate the connections of siphon sensory neurons. Also, 5,7-DHT reduced 5-HT-dependent, but not dopamine-dependent, histofluorescence in Aplysia central ganglia. Finally, 5,7-DHT does not reduce the levels of the facilitatory peptides SCPA and SCPB within the Aplysia CNS. Our results, together with those of Mackey et al. (1989), indicate that 5-HT plays a major role in mediating dishabituation and sensitization of Aplysia's withdrawal reflex.     

Effect of ethanol on subthreshold currents of Aplysia pacemaker neurons

The subthreshold currents in bursting pacemaker neurons of the Aplysia abdominal ganglion were individually studied with the voltage clamp technique for sensitivity to 4% ethanol. The most prevalent effect of ethanol on unclamped bursting neurons was a hyperpolarization. This was shown to be due to a decrease of a voltage independent inward leakage current. Direct measurement of the Na-dependent slow inward current showed that this current was eliminated by 4% ethanol. Direct measurement of the Ca-dependent slow inward current showed that this current was substantially reduced by 4% ethanol. Injection of EGTA into cell bodies did not eliminate the ethanol-induced block of the slow inward calcium current. Thus, ethanol cannot be reducing the Ca-dependent slow inward current solely by an increase of internal calcium concentration. The effect of ethanol on voltage dependent outward current was measured by blockage of all inward current. The peak outward current was increased by ethanol. The rate of inactivation of this outward current was also increased. Calcium activated potassium current (IK(Ca)) is particularly complicated in its response to ethanol because it is dependent on both Ca and voltage for its activation. The level of IK(Ca) elicited in response to constant Ca injection was increased by ethanol treatment. The level of this current as activated by voltage clamp pulses was either increased or decreased depending on the neuron type. Ca2+ activated potassium conductance increased e-fold for a 26 mV depolarization in membrane holding potential. Ethanol decreased this voltage dependence to e-fold for a 55 mV change in potential. This result was interpreted to mean that ethanol shifted an effective Ca2+ binding site of these channels from about halfway through the membrane field to one quarter of the way across. The same theoretical approach allowed the further conclusion that ethanol caused an increased internal free calcium concentration probably by decreasing calcium binding by intracellular buffers.     

Modulation of peptide release from single identified Aplysia neurons in culture.

Aplysia neurons B1 and B2 contain large amounts of the neuropeptides SCPA and SCPB. When grown in culture, individual B1 and B2 cells incorporate 35S-methionine into the SCPs, which can be released in a stimulus- and calcium-dependent fashion (Lloyd et al., 1986). We now show that single cells can be stimulated in a manner to evoke release of the SCPs that declines only slightly with repeated stimulation. This has allowed us to examine the ability of several physiologically relevant agonists to modulate the stimulus-evoked release of the SCPs. Bath application of either FMRFamide or 5-HT resulted in a significant decrease in the amount of SCPs released by intracellular stimulation of B1 or B2. The action of 5-HT was dose dependent with an inhibition of release of approximately 70% at a concentration of 100 microM. SCPA did not significantly affect release. The bath application of several compounds that are expected to elevate intracellular levels of cAMP were also found to depress release. To investigate the possibility that the agonists inhibited the release of the SCPs via a hyperpolarization of membrane potential (and perhaps a loss of spikes in the neurites), we examined the actions of 5-HT, FMRFamide, and SCPA on several electrophysiological parameters intended to monitor the level of cell excitability. Surprisingly, even though 5-HT depressed the release of the SCPs from both cells, it depolarized and increased the excitability of B1, and hyperpolarized and decreased the excitability of B2. Furthermore, in contrast to the effects seen in culture, 5-HT depolarized both B1 and B2 in situ.(ABSTRACT TRUNCATED AT 250 WORDS)     

Mechanism of calcium-dependent inactivation of a potassium current in Aplysia neuron R15: interaction between calcium and cyclic AMP

In the preceding paper (Kramer and Levitan, 1988), we presented evidence that an inwardly rectifying K+ current (IR) is inactivated by Ca2+ influx accompanying spontaneous bursting activity in the Aplysia neuron R15. In this paper we examine the mechanism that enables Ca2+ to inactivate IR. Since IR is enhanced by cyclic AMP in neuron R15 (Drummond et al., 1980; Benson and Levitan, 1983), we examined the Ca2+-dependent inactivation of IR after application of either serotonin (5-HT), the adenylate cyclase activator forskolin, or a membrane-permeable cAMP analog, all agents that increase cAMP and hence the magnitude of IR. Even though more active IR channels are available under these conditions, less Ca2+-dependent inactivation is observed. This is contrasted with the Ca2+-dependent inactivation of the voltage-gated Ca2+ current (ICa). Elevating cAMP enhances ICa in R15 and also increases its Ca2+-dependent inactivation. Hence the mechanisms whereby Ca2+ inactivates IR and ICa appear to differ from each other. Elevating internal Ca2+ by repeatedly depolarizing the neuron suppresses the response of IR to brief applications of 5-HT, and speeds the relaxation of the response, suggesting that Ca2+ can interfere with the cAMP-dependent activation of IR. One biochemical site where Ca2+ can reduce cellular cAMP is by activating the Ca2+/calmodulin-sensitive form of phosphodiesterase. We have detected such enzyme activity in homogenates of Aplysia abdominal ganglia and extracts of single R15 somata. Inhibitors of the phosphodiesterase activity suppress the Ca2+-dependent inactivation of IR. Finally, we have used a radioimmunoassay to measure cAMP in individual R15 somata, and have found that R15 neurons hyperpolarized for prolonged periods contain more cAMP than do R15 neurons allowed to burst, consistent with the hypothesis that Ca2+ influx reduces cAMP.(ABSTRACT TRUNCATED AT 250 WORDS)     

2 types of calcium-dependent outward potassium currents in the somatic membrane of Helix pomatia neurons

Peculiarities of delayed potassium outward current were studied in voltage clamp experiments on nonidentified intracellularly perfused neurons of the snail Helix pomatia. Together with voltage operated potassium currents which depend on the intracellular Ca2+ ions (IK(Cain], another peculiar calcium-dependent potassium current was shown to exist. This current increases with an increase of the external Ca2+ concentration (IK(Caout] and is insensitive to intracellular administration of EGTA and fluoride. It is blocked by extracellular application of cobalt ions (1.5 mmol/l). As distinct from (IK(Cain), IK(Caout] rapidly reaches a maximum and then inactivates to a steady-state level.     

Protein kinase C activators reduce the inositol trisphosphate-induced outward current and the Ca2+-activated outward current in identified neurons of Aplysia

Effects of intracellularly injected activators of protein kinase C on the InsP3-induced K+ current and the Ca2+-activated K+ current recorded from identified neurons (R9-R12) of Aplysia kurodai were investigated with conventional voltage-clamp and pressure-injection techniques. Intracellular injection of InsP3 into identified neurons produced a 4-aminopiridine (4-AP)-resistant, tetraethylammonium (TEA)-sensitive, and quinidine-sensitive K+ current similar to the Ca2+ activated K+ current elicited by direct injection of Ca2+ ions into the same neurons. The diacylglycerol analogue 1,2-oleoylacetylglycerol (OAG) at an intracellular concentration of 65 nM produced irreversible decreases in both the InsP3-induced K+ current and the Ca2+-activated K+ current. The phorbol 12,13-dibutyrate (PDBu) at an intracellular concentration of 150 nM also decreased irreversibly both the InsP3-induced K+ current and the Ca2+-activated K+ current. These results suggest that protein kinase C activators reduce both the InsP3-induced K+ current and the Ca2+-activated K+ current recorded from certain identified neurons of Aplysia and that protein kinase C reduces the ability of Ca2+ to open K+ channels rather than affecting the ability of InsP3 to release Ca2+ from intracellular stores.     

Association of neuroactive peptides with the protein secretory pathway in identified neurons of Aplysia californica: immunolocalization of SCPA and SCPB to the contents of dense-core vesicles and the trans face of the Golgi apparatus

The subcellular distribution of two molluscan neuropeptides, the small cardioactive peptides A and B (SCPA and SCPB), has been determined in two identified Aplysia buccal ganglion neurons, B1 and B2. These neurons were previously shown to synthesize and release these neuropeptides. B1 and B2, identified by their size and location within the ganglion, were labeled by intrasomatic injection of an electron-dense particulate marker (ferritin or Imposil) permitting the unequivocal identification of their somata and proximal processes in thin sections. The somatic cytoplasm of both neurons had a conspicuous population of large dense-core vesicles along with a smaller number of compound vesicles and small lucent vesicles. All three vesicle types are found in the neurites within the neuropil and proximal axon in the esophageal nerve. Immunoreactivity was localized on the surface of thin sections by the indirect immunogold method. The primary antiserum was shown to recognize both SCPA and SCPB after the neuropeptides had been immobilized on protein-coated nitrocellulose membranes by means of glutaraldehyde, the primary fixative used to immobilize SCPA and SCPB in situ. SCP immunoreactivity was present in the lumens of the dense-core vesicles distributed throughout the cytoplasm of B1 and B2 and in dense-core regions of the Golgi apparatus in the somatic cytoplasm. Taken together with biochemical evidence that B1 and B2 synthesize and release SCPs, these data suggest that the neuropeptides are sequestered into the protein secretory pathway of B1 and B2, a distribution that supports the notion that the SCPs function physiologically as neurotransmitters or neuromodulators.     

Pharmacologic and metabolic dependence of the delayed inactivated potassium outward current in the somatic membrane of snail neurons

Peculiarities of pharmacological and metabolic sensitivities of delayed potassium outward current depending on extracellular calcium ions (IK(Ca(out)) have been studied in experiments on isolated intracellularly perfused Helix neurons. It is shown that verapamil depresses the amplitude and accelerates the inactivation of this current. Blocking effect of verapamil increases with extracellular Ca2+ concentration. Functioning of IK(Ca(out)) channels depends on the intracellular metabolic processes. The current amplitude decreases during the neuron perfusion. Lowering of the intracellular solution temperature to +10 degrees C brings about the analogous result. Addition of ATP (2 mmol/l) and Mg2+ (3 mmol/l) to the intracellular perfusate prevents a decrease of potassium current; intracellular introduction of the exogenous protein kinase C restores the amplitude of this current. Polymyxin B (10(-4) mol/l), a blocker of protein kinase C, depresses the potassium current sensitive to extracellular calcium ions. The possible mechanism of Ca2+ action on IK(Ca(out)) through phosphatidyl-inositol metabolism is discussed.     

Co-localization of SCPB-like and FMRFamide-like immunoreactivities in crustacean nervous systems

A monoclonal antibody to the molluscan small cardioactive peptide SCPB and a polyclonal antibody to FMRFamide were used to localize antigens in the stomatogastric nervous system and brain of two species of Cancer. Both antibodies labeled cell bodies, axons, and neuropilar processes in the brain and in the stomatogastric nervous system. All of the SCPB immunoreactive neurons were co-labeled with antibody to FMRFamide. However, antibody to FMRFamide labeled additional neurons of the commissural ganglion and the brain that were not immunoreactive to the monoclonal SCPB antibody.     

Blocking action of calmidazolium and chlorpromazine on the potassium outward current which depends on intracellular calcium ions

Effects of calmidazolium (R 24571) and chlorpromazine on the delayed potassium outward current in the somatic membrane were studied on nonidentified intracellularly perfused neurons of the snail Helix pomatia. Extracellular application of these substance evoked depression of the outward current. Inhibition of IK occurs at concentrations of calmodulin inhibitors 10(-9)-10(-8) mol/l. These agents inhibit primarily a component of the potassium current depending on the intracellular Ca2+ ions (IK(Ca in)). The inhibitory effect of these drugs can be explained by calmodulin-like structures of the receptor for intracellular calcium, providing modulation of IK(Ca in).     

Different types of potassium channels underlie the long afterhyperpolarization in guinea-pig sympathetic and enteric neurons

Ca(2+)-activated K(+) channels play an important role in the control of neuronal excitability via the generation of the afterhyperpolarization. While both small and large conductance Ca(2+)-activated K(+) channels underlie afterhyperpolarizations in different neuron types, the role of intermediate conductance Ca(2+)-activated K(+) channels (IK(Ca)) in the generation of afterhyperpolarizations remains unclear. The effects of blockade of IK(Ca) on guinea pig coeliac and ileal myenteric neurons were studied using single microelectrode current and voltage clamp. In coeliac neurons, TRAM-39, a selective blocker of IK(Ca), depressed the amplitude of the prolonged conductance underlying the slow afterhyperpolarization, (gKCa2) by 57%. In contrast, the conductance underlying the prolonged afterhyperpolarization in AH-type myenteric neurons was unaffected by TRAM-39, although it has been suggested that this AHP is mediated by IK(Ca). In both types of neurons, TRAM-39 did not alter the resting cell properties or the properties of the action potential. TRAM-39 had no effect on the amplitude of the fast component of the afterhyperpolarization present in sympathetic LAH neurons. The results of this study suggest that in sympathetic LAH neurons, activation of IK(Ca) underlies at least part of the prolonged afterhyperpolarization while the nature of the channel underlying the AHP in enteric neurons remains unclear.     

Edrophonium-induced inward membrane current in single neurons physically isolated from Aplysia californica

The action of edrophonium on Aplysia neurons was studied using a concentration clamp technique which combines internal perfusion and a rapid drug application. Edrophonium elicited a dose-dependent inward current in the concentration range 10(-6) to 10(-4) M. At higher concentrations (10(-3) and 10(-2) M), the amplitude of the current often decreased and there was a rapid decay of the current. At these high concentrations, the current increased immediately after washing the neuron with normal solution. These results suggest that edrophonium blocks the ion channel which it opens. Removal of Na+ from the external solution greatly reduced the current amplitude by more than 90%. Removal of Ca2+ also reduced the amplitude of the response; however an increase of Ca2+ did not augment the response. These results suggest that Ca2+ does not carry the current, but is necessary for generation of an Na+-dependent inward current. Edrophonium, 10(-2) M, which completely blocked the current it induced within 20 s, did not significantly affect the voltage-dependent Na+ current. Tetrodotoxin, 1 x 10(-6) M, did not affect the edrophonium response. Hexamethonium, 1 x 10(-4) M, did not change the response elicited by edrophonium, while it significantly reduced the ACh response mediated by Na+. In some neurons edrophonium elicited an inward current, but ACh induced an outward current. Therefore the Na+ channels opened by edrophonium appear to be distinct from both the voltage-gated and ACh receptor-operated Na+ channels.     

Vipoxin both activates and antagonizes three types of acetylcholine response inAplysia neurons

The effects of vipoxin, a 13,000 Dalton protein component of Russell's viper venom on responses of voltage-clamped Aplysia neurons to acetylcholine (ACh) and monoamines has been studied. At low doses vipoxin reversibly antagonizes all 3 types of ionic response to ACh or carbachol, the order of susceptibility to blockade being Na+ greater than K+ greater than Cl-. High doses of vipoxin directly evoke the same ionic response on a given cell as that evoked by ACh. Responses to vipoxin are reversibly antagonized by cholinergic antagonists (e.g. hexamethonium, tetraethylammonium), but not by monoamine antagonists (e.g. bufotenine, ergometrine, cimetidine). In addition to activation of cholinergic responses, high doses of vipoxin also produce a reversible potentiation of responses to dopamine and 5-hydroxytryptamine on some cells. In contrast to its effects on Aplysia neurons, vipoxin has neither agonist nor antagonist actions at the frog neuromuscular junction. These results suggest that this venom protein acts as a partial agonist at molluscan ACh receptors and provides evidence for some phylogenetic difference between molluscan and vertebrate ACh receptors.     

Effect of extracellular potassium ions on the potassium outward current which depends on extracellular calcium ions

Changes in the delayed potassium outward current induced by introduction of K+ ions into extracellular solution have been studied in experiments on isolated intracellularly perfused Helix neurons. It is shown that extracellular administration of 5-10 mmol/l K+ ions into the solution produces a reversible increase of the potassium outward current which depends on the extracellular Ca2+ ions (IK(Ca out)). Extracellular potassium increases this component of the potassium current as a result of weakening of its inactivation.     

Monoclonal antibodies to the molluscan small cardioactive peptide SCPB: immunolabeling of neurons in diverse invertebrates

We reported a development of murine monoclonal antibodies to a molluscan small cardioactive peptide (SCPB) and their application to immunolabeling of neurons in several molluscan and arthropod species. In vitro stimulations of mouse lymphocytes with SCPB conjugated to a carrier protein yielded exclusively IgM class antibodies; in vivo stimulation resulted in generation of both IgM and IgG classes of antibodies. Monoclonal antibodies of the IgM class labeled identified SCP-containing neuron B11 in the frozen sections of the buccal ganglia of Tritonia diomedia. These antibodies failed to stain any neurons in whole mount preparations. A monoclonal antibody of IgG1 subclass selectively labeled neurons in both frozen sections and whole mount preparations of diverse invertebrate species. Thus, neurons B11, B12, and GE1 and several other neurons of the buccal and gastroesophageal ganglia of T. diomedia bound the antibody, and a similar pattern of immunolabeling was found in the closely related gastropod Tritonia festiva. We also observed SCPB-like immunoreactivity in the central neurons of other nudibranch and pulmonate molluscs and in examples of insect (Acheta domesticus and Tehrmobia domestica) and crustacean (Semibalanus cariosus) classes of the Arthropoda. Our results suggest a specific pattern of distribution of SCPB-like immunoreactivity in the gastropod nervous system and a broad occurrence of SCPB-like antigenicity in the diverse invertebrates.     

Calcium-promoted translocation of protein kinase C to synaptic membranes: relation to the phosphorylation of an endogenous substrate (protein F1) involved in synaptic plasticity

The translocation of protein kinase C between membrane and cytosol has been implicated in several cellular processes (Kraft and Anderson, 1983; Wooten and Wrenn, 1984; Akers et al., 1985, 1986; Hirota et al., 1985; Wolf et al., 1986). We desired to identify potential trigger mechanisms underlying the translocation of protein kinase C activity to neural membranes following the synaptic plasticity observed after long-term potentiation (LTP; Akers et al., 1986). Takai et al. (1979) have suggested an important role for calcium in protein kinase C translocation; we have therefore studied the effects of Ca2+ on both the translocation of protein kinase C activity and the in vitro phosphorylation of its endogenous substrate, protein F1, in rat hippocampal synaptosomes. Since identical free Ca2+ levels were maintained in subsequent assays of synaptosomal membranes (SPM) and cytosol preparations, alterations in endogenous enzyme activity and in vitro phosphorylation were due to the Ca2+ present during treatment of synaptosomes, and not to the Ca2+ present during assays of enzymatic activity. This afforded the opportunity to relate directly such enzyme translocation to endogenous substrate phosphorylation. The major findings were as follows: 1. Following treatment of synaptosomes with Ca2+, protein kinase C activity in synaptic membrane and protein F1 in vitro phosphorylation were elevated in a dose-dependent manner. 2. The greatest increment in membrane protein kinase C activity and protein F1 in vitro phosphorylation occurred when Ca2+ was increased from 0.1 to 1.0 microM. Maximal levels of enzyme activity were seen following treatment with 10 microM Ca2+, and minimum levels were observed following treatment with EGTA.(ABSTRACT TRUNCATED AT 250 WORDS)     

The neuropeptide FMRF-amide decreases both the Ca2+ conductance and a cyclic 3',5'-adenosine monophosphate-dependent K+ conductance in identified molluscan neurons

The molluscan neuropeptide FMRF-amide (10 to 50 microM) decreases the duration of the Ca2+-dependent action potential recorded in the cell body of identified neurons of the snail Helix aspersa (cells D3 and E2). In these neurons, FMRF-amide evokes a decrease of the Ca2+ current resulting from a decrease in Ca2+ conductance. In another single neuron, cell E11, FMRF-amide, besides evoking a decrease of the Ca2+ conductance, induces a decrease of the S-current (Klein, M., J. S. Camardo, and E. R. Kandel (1982) Proc. Natl. Acad Sci. U. S. A. 79: 5713-5717), a K+ current controlled by cyclic AMP. However, in this E11 cell, FMRF-amide also evokes a decrease of the amplitude of the Ca2+ spike plateau. As discussed in the preceding paper (Paupardin-Tritsch, D., L. Colombaioni, P. Deterre, and H. M. Gerschenfeld (1985) J. Neurosci. 5: 2522-2532), it is suggested that these FRMF-amide-induced modulations of ionic conductances involved in the Ca2+-dependent spike recorded in these neuronal somata may intervene in processes of presynaptic inhibition and facilitation.