Monoamine pharmacology of the lobster cardiac ganglion

Monoamine agonists and antagonists were applied to the lobster cardiac ganglion in an attempt to clarify the different actions of 5-hydroxytryptamine (5HT) and dopamine (DA) on this rhythmic pattern generator. Experiments were designed to determine whether the similar responses to 5HT and DA applied to the anterior region of the ganglion could be separated by pharmacological approaches, and whether the different responses to 5HT applied to the anterior and posterior regions of the ganglion could be attributed to mediation by different receptors. A small number of the 5HT agonists which were tested mimic the effects of 5HT, in that they increase the frequency of bursting and decrease burst duration when applied to the whole ganglion, but decrease burst frequency and increase burst duration when applied only to the posterior half. Other 5HT agonists decrease frequency and prolong bursts when applied to the whole ganglion. Of the DA agonists tested, none acts as DA itself does. Rather, they mimic the effects of 5HT applied to the posterior ganglion, by slowing bursting and prolonging bursts. The actions of agonists do not correspond in any clear way to the receptor specificities as defined in vertebrates. Most antagonists tested do not show similar specificities to their effects in vertebrates. In particular, most of the DA antagonists tested are more effective in blocking exogenous 5HT than DA. One monoamine agonist directly alters the properties of endogenous burst-organizing potentials (driver potentials) in the motorneurons of the ganglion.     

Neurohormonal alteration of integrative properties of the cardiac ganglion of the lobster Homarus americanus.

The spontaneous burst discharges of isolated lobster (Homarus americanus) cardiac ganglia were recorded with a spaced array of electrodes. Small regions (less than 1 mm) of the ganglion were exposed to the cardioexcitor neurohormone in extracts of pericardial organs (XPO) or to 10(-5) M 5-hydroxytryptamine (5HT). All axons were excited (increased mean firing frequency, f) by both substances, but only by applications in the region between the soma (but excluding it) and proximal site of impulse initiation. Units not so exposed changed their f relatively little despite f increases of as much as threefold in exposed units and changes in burst rate and overall length. Regularity and grouping of all impulse activity into bursts was never disturbed. 5HT increases burst rate at any point of application. The increases are larger if small cells are affected than if only large cells are exposed. Burst length decreases except when the pacemaker is affected. In contrast, XPO affects neither burst rate or length unless small cells are affected. Length is increased if non-pacemaker small cells are affected; both rate and length increase if the pacemaker is affected. The pacemaker usually exhibits an f of intermediate value. Rate changes are not simply related to its f. A small cell can "burst" in the absence of impulses from any other cells. XPO may enhance endogenous "driver potentials," while 5HT may excite by depolarizing at limited sites.     

Effects of haloperidol and phentolamine on the crustacean cardiac ganglion

Haloperidol (a dopamine D₂ blocker in vertebrates) and phentolamine (an α-adrenergic blocker) alter the pattern of bursting by the isolated cardiac ganglion of the lobster when perfused at concentrations of 10^?6–10^?5 mol/l. Both drugs decrease the frequency of bursting and increase burst duration. They are most effective in slowing the ganglion when applied selectively to the anterior ganglionic trunk, the same region of the ganglion where dopamine (DA) and 5-hydroxytryptamine (5HT) are most effective in speeding up bursting. When exogenous monoamine transmitters are applied in the presence of 3×10^?6 mol/l haloperidol, the effect of 5HT, but not of DA, is significantly reduced. At the same concentration, phentolamine does not suppress the actions of DA, 5HT or noradrenaline (NA). Both haloperidol and phentolamine significantly alter the properties of endogenous burst-organizing potentials (driver potentials) generated by motorneurons in the ganglion. It is possible that the effects of these drugs on bursting reflect alteration of endogenous electrical properties of the constituent neurons, rather than receptor antagonism.     

Neural control of olfaction and tentacle movements by serotonin and dopamine in terrestrial snail

We investigated the role of serotonin (5HT) and dopamine (DA) in the regulation of olfactory system function and odor-evoked tentacle movements in the snail Helix. Preparations of the posterior tentacle (including sensory pad, tentacular ganglion and olfactory nerve) or central ganglia with attached posterior tentacles were exposed to cineole odorant and the evoked responses were affected by prior application of 5HT or DA or their precursors 5-hydroxytryptophan (5HTP) and l-DOPA, respectively. 5HT applications decreased cineole-evoked responses recorded in the olfactory nerve and hyperpolarized the identified tentacle retractor muscle motoneuron MtC3, while DA applications led to the opposite changes. 5HTP and l-DOPA modified MtC3 activity comparable to 5HT and DA action. DA was also found to decrease the amplitude of spontaneous local field potential oscillations in the procerebrum, a central olfactory structure. In vivo studies demonstrated that injection of 5HTP in freely moving snails reduced the tentacle withdrawal response to aversive ethyl acetate odorant, whereas the injection of l-DOPA increased responses to “neutral” cineole and aversive ethyl acetate odorants. Our data suggest that 5HT and DA affect the peripheral (sensory epithelium and tentacular ganglion), the central (procerebrum), and the single motor neuron (withdrawal motoneuron MtC3) level of the snail’s nervous system.     

The Sites of Action of Pericardial Organ Extract and 5-Hydroxytryptamine in the Decapod Crustacean Heart

Responses of isolated, perfused hearts of Homarm americanusto brief, internal application of extracts of pericardial organs(PO's) ofCancer borealis, or 5-hydroxytryptamine (5HT) are verysimilar over a thousand-told range of concentration: an increasein rate and amplitude of beating. These reach their maxima afterwashing out has begun, and recover within ten minutes. Externalapplication is ineffective and the substances do not interactwith effects of stretch stimulation. Intracellular recordingfrom heart muscle fibers reveals facilitation of depolarizationto bursts at heart beat frequencies. There may be some effectof 5HT directly on neuromuscular facilitation. Responses recordedfrom isolated cardiac ganglia show increased burst rate, burstduration, or both. Thresholds and the range of concentrationsfor which coordinated responses are recorded correspond to thosefor perfused hearts. It is concluded that the major sites ofaction of PO extract and 5HT are in the cardiac ganglion. 5HTtachyphlaxis and LSD block effects of 5HT, but not of PO extractor accelerator nerve stimulation. Intracellular recordings fromthe large ganglion cells show no effects on resting, synaptic,or spike potentials. Changes in membrane potential to currentpulses revealed no changes in membrane resistance or in theresistance of the electrotonic pathway between cells. Resultsof selective application to large or small cells suggested thatPO extract may contain a rate-increasing substance and one prolongingthe duration of bursts. The former, and 5HT, may influence pacemakerpotentials; the latter may increase the number of spikes a unitcan produce before becoming refractory.     

Dual effects of proctolin on the rhythmic burst activity of the cardiac ganglion

The neuropeptide proctolin has distinguishable excitatory effects upon premotor cells and motorneurons of Homarus cardiac ganglion. Proctolin's excitation of the small, premotor, posterior cells is rapid in onset (5–10 s) and readily reversible (< 3 min). Prolonged bursts in small cells often produce a “doublet” ganglionic burst mode via interactions with large motorneuron burst-generating driver potentials. In contrast to small cell response, proctolin's direct excitatory effects upon motorneuron are slow in onset (60–90 s to peak) and long-lasting (10–20 min). The latter include: (a) a concentration-dependent (10^?9–10^?7M) depolarization of the somatic membrane potential; (b) increases in burst frequency and (c) enhancement of the rate of depolarization of the interburst pacemaker potential. Experiments on isolated large cells indicate: (a) the slow depolarization is produced by a decrease in the resting G_K and (b) proctolin can produce or enhance motorneuron autorhythmicity. A two-tiered non-hierarchical network model is proposed. The differential pharmacodynamics exhibited by the two cell types accounts for the sequential modes of ganglionic burst activity produced by proctolin.     

Differential effects of various cAMP derivatives on the morphological and electrical maturation of neuroblastoma X glioma hybrid cells

The influence of adenosine 3′: 5′-cyclic monophosphate (cAMP) and some of its derivatives on the morphological differentiation and on the expression of electrical activity was investigated in neuroblastoma X glioma hybrid cells. This permanent cell line constitutes a well established culture system for studying neuronal properties in vitro. cAMP (1 mM) caused cell death. With 8-bromo-cAMP (0.1–1 mM) present giant multinuclear cells appeared, which were more obvious at 0.1 than at 1 mM 8-bromo-cAMP. 8-p-chlorophenylthio-cAMP (0.1–1 mM) induced an extension of neurites. These cellular processes were comparable to those elicited in the presence of db-cAMP (1 mM). However, only the cells treated with db-cAMP, but not those exposed to 8-p-chlorophenylthio-cAMP, were found to generate action potentials upon electrical stimulation. Neither dexamethasone nor carboxymethylcellulose, nor 8-bromo-cAMP could elicit the formation of processes in hybrid cells.     

Comparison of morphology and physiology of two plurisegmental sound-activated interneurones in a bushcricket

The unusual morphology of a sound-activated plurisegmental ascending interneurone (AN5-AG7) in an insect (Ancistrura nigrovittata, Ensifera, Phaneropteridae) is described. This neurone's soma is located in the penultimate abdominal ganglion. The most prominent arborisations with smooth endings are found in the prothoracic ganglion. The neurone terminates with numerous beaded endings in the brain (protocerebrum). All abdominal ganglia including the penultimate contain only tiny side branches of beaded appearance. The neurone's morphology is compared to the morphology of a `typical' sound-activated plurisegmental neurone of bushcrickets with its soma in the prothorax. In the prothoracic ganglion and in the brain the arborisations of the two cells are very similar. Graded potentials and action potentials are generated in the prothoracic portion of both neurones. Both receive excitation mainly by ultrasound, and inhibition by soma-ipsilateral stimuli. Neither wind, substrate vibration nor touch of the abdomen evoke responses in AN5-AG7. It is assumed that early in evolution this neurone had its dendrites in the ganglion which houses the cell body (like cercal interneurones of this neuromere). Profound evolutionary changes probably have taken place to bring about this neuron's modern morphology. Accepted: 12 June 1999     

A comparative analysis of the effect of an analog of vasopressin on functionally different neurons in the grape snail

Application of desglycine-argininvasopressin (DG-AVP) differently influenced different types of cells of snail isolated central nervous system. In neurosecretory cells an increase of spontaneous impulse activity took place and, as a rule, bursts of impulses appeared, most often of synaptic origin, excluding PPa1 neurones and one of the neurosecretory cells of the left parietal ganglion. The increase of the bursts activity in these cells was based on the increase of the amplitude of membrane potential waves. Under the influence of neurosecretory cells system activation, EPSPs frequency and amplitude in secondary-sensory neurones increased, which led to a greater probability of the action potentials appearance. At prolonged action the spontaneous EPSPs in these cells began to group in bursts. Excitability and membrane resistance of these cells remained unchanged. DG-AVP had no influence on primary-sensory neurones and motoneurones.     

Serotonin-induced changes in the excitability of cultured antennal-lobe neurons of the sphinx moth Manduca sexta

The modulatory actions of 5-hydroxy-tryptamine (5HT or serotonin) on a morphologically identifiable class of neurons dissociated from antennal lobes of Manduca sexta at stages 9–15 of the 18 stages of metamorphic adult development were examined in vitro with whole-cell patch-clamp recording techniques. Action potentials could be elicited from approximately 20% of the cells. These cells were used to examine effects of 5HT (5 × 10^–6 to 5 × 10^–4 M) on cell excitability and action-potential waveform. 5HT increased the number of spikes elicited by a constant depolarizing current pulse and reduced the latency of responses. 5HT also led to broadening of action potentials in these neurons and increased cell input resistance. Modulation of potassium channels by 5HT is likely to contribute to these responses. 5HT causes reversible reduction of at least 3 distinct potassium currents, one of which is described for the first time in this study. Because effects of 5HT on antennal-lobe neurons in culture mimic those observed in situ in the brain of the adult moth, in vitro analysis should contribute to elucidation of the cellular mechanisms that underlie the modulatory effects of 5HT on central olfactory neurons in the moth.     

Some effects of proctolin on the cardiac ganglion of the Maine Lobster, Homarus americanus (Milne Edwards)

The neuropeptide proctolin has excitatory effects on the isolated lobster cardiac ganglion. Selective application to the anterior cell body region produces a dose-dependent (10(-8)--10(-5) M) prolonged depolarization of large anterior cells as well as marked increases in burst frequency and/or duration. In ganglia which have been silenced with tetrodotoxin, proctolin application to anterior cells elicits long-lasting depolarizing responses which are accompanied by a 10-30% increase of the apparent membrane input resistance. Higher proctolin concentrations produce high-frequency trains of driver potentials. It is proposed that a proctolin like peptide may serve a neurohumoral role in the lobster cardiac ganglion and that the anterior motor neurons exhibit endogenous rhythmicity in its presence.     

The effects of cations upon the action potentials recorded from neurohaemal tissue of the stick insect

Summary The ionic requirement for the action potentials recorded from the neurohaemal tissue on the lateral branch of the median nerve inCarausius morosus has been studied using extracellular electrodes. Sodium-free, magnesium-free, or calcium-free salines produce irreversible block of the action potentials following prolonged exposure to the nerves. Reducing the sodium concentration to 4 mM has little effect on the amplitude of the action potentials, whilst increasing the sodium concentration to 100 mM reduces the amplitude by 50%. Neither tetrodotoxin nor procaine has any effect on these action potentials.Reducing the magnesium concentration to 1 mM increases the amplitude of the action potentials, whilst increasing the concentration of magnesium reduces the amplitude.The amplitude of the action potentials is linearly related to the log of the external calcium concentration, and the action potentials are blocked by both cobalt ions and lanthanum ions.It is concluded that calcium is the major charge carrier of the inward current in these neurosecretory axons which is the first report of calcium dependent action potentials in a nerve axon. Furthermore, small amounts of sodium and magnesium are necessary to maintain electrical activity. Magnesium is a competitive inhibitor of the calcium currents.We are grateful to the Science Research Council for financial support, and to Mrs. J. Birch for the printing of the electron micrographs.     

Ionic mechanisms underlying spontaneous CA1 neuronal firing in Ca2+-free solution

Hippocampal CA1 neurons exposed to zero-[Ca(2+)] solutions can generate periodic spontaneous synchronized activity in the absence of synaptic function. Experiments using hippocampal slices showed that, after exposure to zero-[Ca(2+)](0) solution, CA1 pyramidal cells depolarized 5-10 mV and started firing spontaneous action potentials. Spontaneous single neuron activity appeared in singlets or was grouped into bursts of two or three action potentials. A 16-compartment, 23-variable cable model of a CA1 pyramidal neuron was developed to study mechanisms of spontaneous neuronal bursting in a calcium-free extracellular solution. In the model, five active currents (a fast sodium current, a persistent sodium current, an A-type transient potassium current, a delayed rectifier potassium current, and a muscarinic potassium current) are included in the somatic compartment. The model simulates the spontaneous bursting behavior of neurons in calcium-free solutions. The mechanisms underlying several aspects of bursting are studied, including the generation of triplet bursts, spike duration, burst termination, after-depolarization behavior, and the prolonged inactive period between bursts. We show that the small persistent sodium current can play a key role in spontaneous CA1 activity in zero-calcium solutions. In particular, it is necessary for the generation of an after-depolarizing potential and prolongs both individual bursts and the interburst interval.     

Effect of caponization on central nervous system monoamines in the Japanese quail

Depletion of brain regional norepinephrine (NE), dopamine (DA) after alpha methyl-paratyrosine (AMT), and serotonin (5HT) were measured in intact and caponized adult male Japanese quail (Coturnix coturnix japonica). Telencephalon, diencephalon, and cerebellum DA was depleted by AMT treatment, but brain stem was not affected. AMT-induced depletion of NE was greatest in telencephalon, diencephalon, and brain stem of capons. Neither caponization nor AMT affected brain regional 5HT. The results from this work indicate that caponization will affect catecholamine dynamics in brain regions other than the hypothalamus.     

Intraduodenal serotonin elicits non-propagating spike potentials in the small intestine of the rat

Serotonin (5-hydroxytryptamine, 5-HT) is an endogenous signalling molecule capable of altering small intestinal motility. Serotonin is normally present in the intestinal lumen and released by enterochromaffin cells of the mucosal epithelium. We found that intraduodenal infusion of exogenous serotonin causes a dose-dependent myoelectric response in the smooth muscle of the small intestine in the conscious rat. The response consists of repetitive bursts of action potentials (RBAP) that are characterized as short bursts of non-propagative myoelectric spiking. RBAP occur intermittently and only during the first 15 min after intralumenal serotonin infusion. After the initial 15 min period, the frequency of RBAP declines, and the myoelectric pattern shifts to prolonged and continuous spiking, eliminating the interdigestive migrating myoelectric pattern. The effects of intralumenal serotonin are not replicated by parenteral or intraperitoneal infusion nor by intralumenal infusion of 5-hydroxytryptophan or 5-hydroxyindoleacetic acid. The response to intralumenal serotonin was eliminated by several specific 5-HT receptor antagonists. On repeated intralumenal administration of serotonin, the RBAP response decreased demonstrating a decreased sensitivity of the muscle contraction on re-exposure to serotonin. We conclude that intralumenal infusion of serotonin can temporarily initiate specific small intestinal muscle events that are not generated by serotonin from other non-lumenal administration sites. We speculate that an afferent neuro-pathway is necessary for the induction of RBAP, since RBAP are not observed from in vitro muscle preparations.     

Fluorescence marking of neuropile glial cells in the central nervous system of the leech Hirudo medicinalis

Summary Neuropile glial (NG) cells in the central nervous system of the medicinal leech, Hirudo medicinalis L., were studied by histological and intracellular electrophysiological methods. Potential profiles of single leech ganglia were mapped by advancing an electrolyte-filled microelectrode into the ganglion as far as the NG cell. A small negative potential usually appeared during or immediately after penetration of the ganglion sheath. Most of the ganglia in the chain (ganglia 1–4 and 7–21) have Retzius-cell-bodies of normal size; in these, the potential associated with the ganglion sheath was followed by a jump to a more negative potential. Superimposed action potentials were associated with entry of the electrode into a Retzius cell. When the electrode tip passed out of the cell into the center of the ganglion, another potential change was observed, namely that to the membrane potential of the anterior NG cell. This membrane potential averaged -60.2 mV and ranged from -50 to -73 mV. In ganglia 5 and 6 the Retzius-cell-bodies are particularly small, and no changes of potential associated with these cells were observed; the first potential to appear after the electrode passed through the sheath of the ganglion was the membrane potential of the NG cell. Potential profiles like those of ganglia 5 and 6 are recorded in the posterior parts of all ganglia.Potential profiles of single leech ganglia were also recorded with microelectrodes filled with the fluorescent dye Procion Yellow M4-RAN. When the presumed membrane potential of an NG cell appeared, the dye was injected into the ganglion. Subsequent histological examination with the fluorescence microscope revealed that all of the dye was contained in NG cells.Supported by a Fellowship (Heisenberg-Stipendium, Schl 169/5) and grants (Schl 169/2, 4) to W.R.S. from the Deutsche ForschungsgemeinschaftThe authors thank Gisela Geiger for excellent assistance during this work     

Neurophysiology of Ganglia of Auerbach's Plexus

The enteric plexuses of the automatic nervous system may beconsidered, on the basis of both function and morphology, tobe a simple integrative nervous system of vertebrate animals.Microelectrcde studies of single unit activity within entericganglia reveal four distinct types of ganglion cells distinguishedon the basis of pattern of spike discharge. These are (i) burst-typeunits which spontaneously discharge bursts of spikes at periodicintervals; (ii) fast- and slowly-adapting mechanoreceptors;(iii) tonic-type units which respond to mechanical stimulationwith prolonged, all-or-nothing trains of spikes; (iv) single-spikeunits which spontaneously discharge single action potentialsat variable intervals. The enteric plexuses are adapted forcontrol of the intestinal musculature which behaves as an electricalsyncytium activated by myogenic pacemaker potentials. The mechanismof neural control is integration of continuous neurogenic inhibitionof the inherently excitable musculature.     

Neuromodulation of flight initiation by octopamine in the cockroach Periplaneta americana

We have tested the effect of a known insect neuromodulator, octopamine, on flight initiation in the cockroach. Using minimally dissected animals, we found that octopamine lowered the threshold for windevoked initiation of flight when applied to either of two major synaptic sites in the flight circuitry: 1) the last abdominal ganglion, where wind-sensitive neurons from the cerci excite dorsal giant interneurons, or 2) the metathoracic ganglion, where the dorsal giant interneurons activate interneurons and motoneurons which are involved in producing the rhythmic flight motor pattern in the flight muscles (Fig. 2).Correlated with this change in flight initiation threshold, we found that octopamine applied to the last abdominal ganglion increased the number of action potentials produced by individual dorsal giant interneurons when recruiting the cereal wind-sensitive neurons with wind puffs (Figs. 3, 4, 5) or with extracellular stimulation of their axons (Fig. 6). Octopamine increases the excitability of the giant interneurons (Figs. 7, 8). Also, when we stimulated individual dorsal giant interneurons intracellularly, the number of action potentials needed to initiate flight was reduced when octopamine was applied to the metathoracic ganglion (Fig. 9).Abbreviations EMG electromyogram - dGIs dorsal giant interneurons - GI giant interneuron - A6 sixth abdominal ganglion - T3 third thoracic ganglion - EPSP excitatory postsynaptic potential