Presynaptic muscarinic receptors inhibiting active acetylcholine release in the bullfrog sympathetic ganglion

Depression of transmitter release at synapses in the rat superior cervical ganglion: the role of transmitter depletion

The characteristics of depression of the excitatory postsynaptic potential (EPSP) during a short train of impulses to the rat superior cervical ganglion (SCG) have been ascertained with the object of determining the relative contributions of transmitter depletion and autoreceptors to depression. Successive EPSPs in a short train were depressed after the first (Vo) up to about the fourth impulse when a steady-state depressed EPSP level (Vss) was reached. Vss increased with the stimulation frequency between 1 and 30 Hz. Vo recovered after a short train with a time constant of about 2.8 s in the frequency range from 5 to 30 Hz. In order to determine if depression was related to changes in calcium influx with successive impulses in the train. preganglionic boutons were loaded with the calcium indicator Oregon Green 488 BAPTA-1 and line scans taken through individual boutons with a confocal laser microscope. Successive calcium transients were of about the same amplitude in boutons during short trains of impulses at 5 Hz. The contribution of autoreceptors activated by the action of endogenously derived adenosine on the extent of depression of the EPSP during short trains was ascertained by blocking these receptors with 8-phenyltheophylline (10 microM). There was no change in the extent or time course of development of depression. Similar results were obtained with the opioid receptor antagonist naloxone (10 microM) and the adrenergic receptor antagonist yohimbine (10 microM). Factors, which increased the extent of transmitter release during a train, such as increasing the external calcium concentration from 0.8 to 2.5 mM, increased depression. Factors. which decreased the extent of transmitter release such as increasing the exogenous adenosine concentration between 1 and 200 microM decreased depression. These results are interpreted in terms of a model in which vesicles are mobilised by a calcium-dependent process from a store into an available pool of docked vesicles. Depletion of the docked vesicles during exocytosis then leads to depression of transmitter release during a train of impulses.

Synaptic inhibitory effects of edrophonium on sympathetic ganglionic transmission

PURPOSE

To evaluate the effect of edrophonium on synaptic transmission in the superior cervical ganglion.

METHODS

In anaesthetized rats the effect of edrophonium on synaptic transmission was studied in vitro by testing whether it blocks the compound action potential recorded from postganglionic fibres evoked by stimulation of preganglionic axons. The superior cervical ganglion was excised and the cervical sympathetic trunk and internal carotid nerve were used for stimulating and recording, respectively. Drugs superfused included edrophonium (0.1-500 microM), neostigmine (0.1-10 microM), and muscarinic M1 and M2 antagonists pirenzepine and AFDX-116 (200 nM-10 microM), respectively. To evaluate a presynaptic action, the effect of edrophonium on basal and high-K+ (35 mM) evoked release of [3H]ACh from the superior cervical ganglion was studied in vitro. To evaluate a postsynaptic action, edrophonium's effect on postganglionic nerve discharge in response to arterial injection of ACh (100 micrograms) into the superior cervical ganglion was determined in vivo.

RESULTS

Edrophonium (10-500 microM) decreased the compound action potential amplitude (ED50 163.5 microM). A decrease was not produced by neostigmine, nor was it reversed by pirenzepine or AFDX-116. Edrophonium blocked postganglionic cell firing in response to exogenously administered ACh. Although edrophonium did not affect basal or high-K+ evoked ACh release, when the evoked increase was calculated as a multiple of the basal release, it caused approximately a 30% (P < 0.005) reduction.

CONCLUSIONS

Edrophonium blocks ganglionic cholinergic transmission postsynaptically and, possibly, presynaptically. The mechanism(s) by which this occurs does not appear to involve inhibition of cholinesterase, or activation of M1 or M2 receptor subtypes.

Synaptic current at the rat ganglionic synapse and its interactions with the neuronal voltage-dependent currents

The membrane current activated by fast nicotinic excitation of intact and mature rat sympathetic neurons was studied at 37 degrees C, by using the two-microelectrode voltage-clamp technique. The excitatory postsynaptic current (EPSC) was modeled as the difference between two exponentials. A fast time constant (tau2; mean value 0.57 ms), which proves to be virtually voltage-independent, governs the current rise phase and a longer time constant (tau1; range 5.2-6.8 ms in 2 mM Ca2+) describes the current decay and shows a small negative voltage dependence. A mean peak synaptic conductance of 0.58 muS per neuron is measured after activation of the whole presynaptic input in 5 mM Ca2+ external solution (0.40 muS in 2 mM Ca2+). The miniature EPSCs also rise and decay with exponential time constants very similar to those of the compound EPSC recorded at the same voltage. A mean peak conductance of 4.04 nS is estimated for the unitary event. Deconvolution procedures were employed to decompose evoked macrocurrents. It is shown that under appropriate conditions the duration of the driving function describing quantal secretion can be reduced to <1 ms. The shape of the EPSC is accurately mimicked by a complete mathematical model of the sympathetic neuron incorporating the kinetic properties of five different voltage-dependent current types, which were characterized in a previous work. We show that IA channels are opened by depolarizing voltage steps or by synaptic potentials in the subthreshold voltage range, provided that the starting holding voltage is sufficiently negative to remove IA steady-state inactivation (less than -50 mV) and the voltage trajectories are sufficiently large to enter the IA activation range (greater than -65 mV). Under current-clamp conditions, this gives rise to an additional fast component in the early phase of membrane repolarization-in response to voltage pulses-and to a consistent distortion of the excitatory postsynaptic potential (EPSP) time course around its peak-in response to the synaptic signal. When the stimulation initiates an action potential, IA is shown to significantly increase the synaptic threshold conductance (up to a factor of 2 when IA is fully deinactivated), compared with that required when IA is omitted. The voltage dependence of this effect is consistent with the IA steady-state inactivation curve. It is concluded that IA, in addition to speeding up the spike repolarization process, also shunts the excitatory drive and delays or prevents the firing of the neuron action potential.

Autoradiographic localization of functional muscarinic receptors in the rat superior cervical sympathetic ganglion reveals an extensive distribution over non-synaptic surfaces of neuronal somata, dendrites and nerve endings

Fast synaptic transmission in sympathetic ganglia is mediated by acetylcholine, acting on nicotinic receptors, yet muscarinic receptors are also present and are involved in the production of slow postsynaptic potentials. In order further to elucidate the role of muscarinic receptors in ganglionic transmission their distribution in the rat superior cervical sympathetic ganglion was investigated autoradiographically by use of the tritiated irreversible muscarinic ligand propylbenzilylcholine mustard. It was observed that this agent blocked the carbachol-evoked hydrolysis of inositol phospholipids in the ganglion and that this response to carbachol is itself inhibitable by selective muscarinic antagonists with a potency sequence which indicates involvement primarily of M1 receptors. Light microscope autoradiography showed that labelling inhibitable by atropine and by the M1-selective muscarinic antagonist pirenzepine was essentially confined to the margins of neuronal somata and regions of dendritic arborization, which include synaptic contacts. Quantitative electron microscope autoradiography showed that binding of the radioligand, of which approximately 70% was inhibitable by atropine and 68% by pirenzepine, was associated predominantly with surface membranes of neuronal somata, dendrites, other neurites (including axons and uncharacterized dendrites) and nerve terminal profiles, in the approximate ratios 95:85:52:45. Of the inhibitable binding over neuronal membranes in the ganglion little more than 3% was found to be synaptically located, and this involved para- or peri-synaptic regions of nerve terminal contacts rather than the specialized synaptic zone. About 5% of the inhibitable binding over neuronal membranes involved non-synaptic surfaces of nerve terminals and preterminal axon segments; almost 70% was distributed over non-synaptic surfaces of neuronal somata and dendrites, and about 21% upon other neurites. Binding sites were found not to be more highly concentrated at or adjacent to synapses than over other regions of neuronal surface membranes. About 50%, possibly more, of the binding on non-synaptic surfaces of nerve endings, and about 7% of binding upon dendritic membranes, was of non-M1, possibly M2 type, inhibitable by atropine but not by pirenzepine. Non-synaptic neuro-neuronal appositions, which involve dendrites and somata and often lie adjacent to synapses, showed rather more than twice the binding expected for each membrane individually; and neuronal membrane exposed to basal lamina lining ganglionic tissue spaces showed high levels of binding. Little inhibitable binding was seen over membranes of satellite and Schwann cells, or over cytoplasmic territories or ganglionic interstitial tissue. A model was constructed of the distribution of label, which showed that the observed results for total binding could be approximately matched by assuming the following relative densities of ligand binding sites: interstitial tissue space and supporting cells 1, soma cytoplasm 3, cytoplasm of dendrites, neurites and nerve terminals 4.5, surfaces of mesodermal elements 15, surfaces of neurites and nerve endings including sites of synapse 45, surfaces of dendrites 90, surfaces of neuronal somata 120, non-synaptic neuro-neuronal appositions 180. It is concluded that functional muscarinic receptors in this sympathetic ganglion, predominantly of the M1 type linked with slow depolarizations, but including some non-M1 receptors, are widely distributed over non-synaptic surfaces of the neuronal somata and dendrites and are not concentrated at synapses. Presynaptic autoreceptors are also present, of which half or more are of non-M1, possibly M2, type which might be inhibitory. The presence of M4 receptors is not excluded...

Presynaptic muscarinic inhibition in bullfrog sympathetic ganglia

1. Muscarinic modulation of nicotinic transmission was studied in bullfrog sympathetic ganglia by recording synaptic currents from B and C neurones. 2. Bath-applied muscarine reduced the amplitude of EPSCs recorded at < 0.2 Hz from B neurones by up to 57%. The action was reversible, showed no apparent desensitization, and had an EC50 of 102 nM. Muscarine had no effect on EPSCs in C neurones. 3. Currents evoked by ionophoretic application of ACh to B neurones were unchanged by muscarine. Muscarine increased the coefficient of variation (c.v.) of EPSC amplitude. The effect upon the ratio of c.v.2control to c.v.2muscarine was proportional to the change in mean EPSC amplitude. 4. Activation of muscarinic receptors by ACh from nerve terminals was observed by comparing trains of EPSCs in normal Ringer solution and atropine. Inhibition of EPSC amplitude by 15-40% was seen as frequency was increased from 1 to 5 Hz. The minimal latency for onset of inhibition was approximately 2 s. Stimulation at 20 Hz did not produce inhibition. 5. The results indicate that presynaptic muscarinic receptors are selectively expressed by a functional subclass of preganglionic sympathetic nerve terminals. Physiological activation of the receptors occurs during repetitive activity. The extent of autoreceptor-mediated inhibition varies as a biphasic function of stimulus frequency.

Enhancement by atropine of the pancreatic exocrine secretions evoked by vagal stimulation in the pithed rat

1. Pancreatic secretions were collected in response to 15 min periods of bilateral stimulation of the cervical vagus nerves in the pithed rat. 2. The weight of juice, total HCO3- and total protein evoked by a second period of vagal stimulation were essentially similar to those of the first period of vagal stimulation. 3. When the second period of vagal stimulation was preceded by an intravenous bolus injection of atropine sufficient to block the vagally induced bradycardia, the weight of secretion and total protein were greatly potentiated over an extended time course far exceeding that of the period of vagal stimulation. Total HCO3- was unchanged. 4. By contrast, atropine was effective in antagonizing the stimulatory effects of the muscarinic agonist methacholine injected intravenously. 5. The putative VIP (vasoactive intestinal polypeptide) antagonist [D-p-chloro-Phe6, Leu17]-VIP injected intravenously also increased the vagally evoked weight of juice, with total HCO3- and total protein unchanged. This was explicable by a partial agonist effect which was additive to the stimulatory action of vagal stimulation. 6. To explain these results, it is proposed that endogenously released acetylcholine exerts a negative feedback effect on the postganglionic varicosities which release both acetylcholine and another cotransmitter which was not excluded as being VIP. In the presence of atropine, the cotransmitter is proposed to be released from the inhibitory feedback, thus enhancing the response to vagal stimulation.

Mechanisms of synaptic fatigue in a developing autonomic ganglion

Synaptic transmission in developing systems has often been noted to exhibit depression or failure at moderate frequencies of stimulation. While this is often presumed to be a transient, nonspecific inability of developing systems to meet the demands of synaptic transmission, this report demonstrates that such failure in the choroidal neurons of the embryonic ciliary ganglion is due to muscarinically mediated inhibition. Although the ganglion is composed of both choroid and ciliary neurons, only the choroid neurons exhibit the muscarinic depression, and only during embryonic development. The pharmacological properties of the relevant receptor are different from those of the muscarinic receptor involved in presynaptic inhibition in adult autonomic systems. Receptor-mediated, synaptic failure during development may serve to protect immature postsynaptic neurons from potentially toxic overstimulation.

The effects of irreversible acetylcholinesterase inhibitors on transmission through sympathetic ganglia of the bullfrog

The effects of soman, sarin and VX were examined on ganglionic transmission through paravertebral chain ganglia of the bullfrog, Rana catesbeiana. Low frequency (0.1 Hz), short (2 sec) and long (10 sec) trains of preganglionic stimulation, after exposure to the agents, induced repetitive activity in the extracellularly recorded compound action potential. An irreversible transient depression was observed after exposure to the agents during the first second of short and long stimulus trains. Long stimulus trains of high frequency were required to produce a rundown in the amplitude of the compound action potential, whether recorded in the presence of each agent (10 microM) or following a wash with agent-free solution. The rundown of the compound action potential was use-dependent and not blocked or reversed by atropine (10 microM). Intracellular recordings, in the presence of either soman or VX, demonstrated (1) an increase in the amplitude of the residual excitatory postsynaptic potential or current evoked by synaptic stimulation, (2) an increase in the amplitude and duration of the acetylcholine-induced potential, (3) no increase in either the amplitude or duration of the carbachol-induced potential, (4) repetitive firing with orthodromic but not antidromic stimulation and (5) a concentration- and frequency-dependent depolarization of individual ganglion neurons with orthodromic stimulation which resulted in a decrease in the generation of action potentials. These results suggest that the agent-induced decrease in the compound action potential occurred as a consequence of activity-dependent depolarization of ganglion neurons, which occurs after inhibition of cholinesterase.

Activity-dependent induction of facilitation, depression, and post-tetanic potentiation at an insect central synapse

In Manduca sexta larvae, sensory neurons innervating planta hairs on the tips of the prolegs make monosynaptic excitatory connections with motoneurons innervating proleg retractor muscles. Tactile stimulation of the hairs evokes reflex retraction of the proleg. In this study we examined activity-dependent changes in the amplitude of the excitatory postsynaptic potentials (EPSPs) evoked in a proleg motoneuron by stimulation of individual planta hair sensory neurons. Deflection of a planta hair caused a phasic-tonic response in the sensory neuron, with a mean peak instantaneous firing frequency of greater than 300 Hz, and a tonic firing rate of 10-20 Hz. Direct electrical stimulation was used to activate individual sensory neurons to fire at a range of frequencies including those observed during natural stimulation of the hair. At relatively low firing rates (e.g., 1 Hz), EPSP amplitude was stable indefinitely. At higher instantaneous firing frequencies (greater than 10 Hz), EPSPs were initially facilitated, but continuous stimulation led rapidly to synaptic depression. High-frequency activation of a sensory neuron could also produce post-tetanic potentiation, in which EPSP amplitude remained elevated for several min following a stimulus train. Facilitation, depression, and post-tetanic potentiation all appeared to be presynaptic phenomena. These activity-dependent changes in sensory transmission may contribute to the behavioral plasticity of the proleg withdrawal reflex observed in intact insects.

M1 and M2 muscarinic receptors mediate excitation and inhibition of guinea-pig intracardiac neurones in culture

1. The effects of muscarine upon intracardiac neurones cultured from ganglia within the atria and interatrial septum of the newborn guinea-pig heart were studied using intracellular recording techniques. 2. Muscarine applied to the neuronal soma typically produced a biphasic change in membrane potential which consisted of a small hyperpolarization followed by a depolarization. In addition, muscarine (0.01-10 microM) inhibited the calcium-dependent, after-hyperpolarization (AHP) and greatly increased the number of action potentials that could be evoked by a given depolarizing current. 3. The hyperpolarization was associated with a decrease in input resistance and it reversed to become a depolarization at a potential of -86.5 mV. This response was antagonized by 4-diphenylacetoxy-N-methyl-piperidine (4-DAMP; 100 nM) and AF-DX 116 (500 nM), but was unaffected by pirenzepine (0.1-5 microM). 4. Two types of slow depolarization were observed in the presence of muscarine. The most common was associated with an increase in input resistance in the potential range -70 to -40 mV. Pirenzepine (100 nM) selectively antagonized this response, 4-DAMP (100 nM) similarly antagonized the response, but was non-selective. AF-DX 116 (0.5-5 microM) showed no antagonist effect. The less common depolarization (5% of cells) had a long latency and was associated with a decrease in input resistance. 5. Muscarine reduced the duration of the action potential and inhibited the AHP. Cadmium chloride (100 microM) mimicked these actions of muscarine. Application of muscarine immediately following a train of action potentials did not inhibit the AHP, suggesting that muscarine did not directly inhibit the calcium-activated potassium current (IK(Ca)). Muscarine-induced depression of the slow AHP was antagonized by 4-DAMP (100 nM) but was not antagonized by either pirenzepine (0.1-0.5 microM) or AF-DX 116 (0.5-5 microM). 6. It is concluded that the muscarine-induced depolarization of guinea-pig intracardiac neurones results from reduction of a potassium conductance similar to the M-conductance, through activation of M1 muscarinic receptors. The hyperpolarization results from an increase in potassium conductance, through activation of M2 muscarinic receptors.

Presynaptic inhibition of cholinergic transmission by peptidergic neurons in bullfrog sympathetic ganglia

Intracellular recordings were made from sympathetic B neurons to investigate an interaction between peptidergic and cholinergic responses in bullfrog sympathetic ganglia. Simultaneous stimulations of 3rd-5th and 8th spinal nerves evoked the fast excitatory postsynaptic potential (EPSP) superimposed with the late slow EPSP at the same sympathetic neuron. The amplitude of fast EPSPs was reduced during the course of the late slow EPSP in a majority of sympathetic neurons. A nicotinic depolarization produced by an ionophoretic application of ACh (ACh potential) was not significantly affected during the late slow EPSP. The quantal content of the fast EPSP calculated by the variance method was depressed during the late slow EPSP. Luteinizing hormone-releasing hormone (LH-RH), a putative transmitter for the late slow EPSP decreased the amplitude and the quantal content of the fast EPSP. [D-Phe2,6, Pro3]-LH-RH, and [D-pGlu1, D-Phe2, D-Trp3,6]-LH-RH, antagonists for LH-RH receptors prevented the inhibition of the fast EPSP induced by the late slow EPSP and LH-RH. These results suggest that cholinergic nicotinic transmission is inhibited during the late slow EPSP by a decreased ACh-release from nerve terminals in bullfrog sympathetic ganglia.

Parasympathetic depression of vas deferens contraction in the guinea-pig involves adenosine receptors

1. In the guinea-pig pelvic plexus-vas deferens preparation, stimulation of the parasympathetic pelvic nerves contracted the vas deferens then depressed the contractile responses to stimulation of the sympathetic hypogastric nerves. 2. The contraction caused by stimulation of the pelvic nerves was initially phasic then tonic. The contractions were almost abolished by application of hexamethonium to the plexus. The phasic contraction was abolished by alpha,beta-methylene adenosine triphosphate applied to the vas deferens. 3. Conditioning stimulation of the pelvic nerves preferentially depressed the phasic component of test contractions evoked by hypogastric nerve stimulation but did not affect the compound action potentials in postganglionic nerves evoked by test stimulation. 4. When the pelvic plexus was divided into two parts, one with the pelvic nerves and the other with the hypogastric nerves, conditioning stimulation of the pelvic nerves still depressed test contractions evoked by hypogastric nerve stimulation. 5. In the de-ganglionated vas deferens preparation, conditioning stimulation of some postganglionic nerves also depressed contractions evoked by test stimulation of the other postganglionic nerves. 6. 8-Phenyltheophylline (5-20 microM) applied to the vas deferens antagonized the conditioning stimulation-induced depression in both the pelvic plexus-vas deferens and the de-ganglionated preparations. 7. N6-Cyclohexyladenosine (CHA) and N6-(L-2-phenylisopropyl)-adenosine at 0.5 microM preferentially inhibited phasic contractions evoked by the postganglionic nerve stimulation. The effect of CHA was antagonized by 8-phenyltheophylline (10 microM). 8. The results indicate that the mechanism underlying the conditioning stimulation-induced depression of phasic contractions operates not in the ganglia, but through activation of adenosine receptors in the vas deferens.

[Frequency potentiation of neuronal synaptic reactions in the medial tegmentum of the medulla oblongata to microstimulation of the inhibitory point of the pons Varolii]

Synaptic responses of medial medullary neurons to single (2 pps) and repetitive (30-50 pps) stimuli delivered to the pontine inhibitory point were recorded in decerebrated cats. Firing index, inhibitory to the less extent, excitatory postsynaptic potentials usually increased when repetitive stimulation was applied. Suppression of the background impulse activity was observed in some neurons. Frequency potentiation makes a substantial contribution to functional effect of stimulation of the inhibitory point (termination of elicited locomotion).

Nicotinic acetylcholine receptors on a cholinergic nerve terminal in the cockroach, Periplaneta americana

Intracellular microelectrode recording and ionophoretic application of carbamylcholine (CCh) were used to compare the cholinergic sensitivity of postsynaptic dendrites of an identified neurone with that of an identified presynaptic cholinergic axon. The axon of the lateral filiform hair sensory neurone (LFHSN) in the first-instar cockroach Periplaneta americana was found to be as sensitive to CCh as the dendritic regions of giant interneurone 3 (GI 3). The CCh response of both neurones was unaffected by replacing Ca2+ with Mg2+, confirming that the ACh receptors are present on the neurones under test. The CCh response of both neurones was mimicked by ionophoretic application of nicotine. The responses were blocked by 10(-5) M mecamylamine and 10(-6) M d-tubocurarine and were not affected by muscarinic antagonists, suggesting that the ACh receptors present on GI 3 and LFHSN are predominantly nicotinic. The muscarinic agonist oxotremorine and the antagonists atropine and quinuclidinyl benzilate had no modulatory effect on LFHSN-GI 3 synaptic transmission. The latency of the LFHSN response to CCh was consistent with the hypothesis that ACh receptors are situated on the main axon/terminal within the neuropil of the ganglion. It has previously been shown that this region of the axon does not form output synapses (Blagburn et al. 1985a). This indirect evidence indicates that presynaptic or extrasynaptic ACh receptors are present in the membrane of a cholinergic axon. LFHSN was depolarized by synaptically-released ACh after normal or evoked spike bursts, suggesting that the nicotinic ACh receptors act as autoreceptors. However, it was not possible to obtain direct evidence to support the hypothesis that these receptors modulate ACh release.

Mechanisms regulating the adrenaline-induced long-term potentiation in bullfrog sympathetic ganglia

Two regulatory mechanisms on the long-term potentiation of transmitter release induced by adrenaline (adr.-l.t.p.) in bullfrog sympathetic ganglia were studied by recording intracellularly the fast excitatory postsynaptic potentials. An increase in exposure time to adrenaline from 10 min to 60 min did not enhance the magnitude of adr.-l.t.p. However, increasing an exposure time to dibutyryl cyclic AMP (1 mM) up to 60 min progressively enhanced the magnitude of the nucleotide-induced potentiation, indicating the desensitization of the beta-adrenoceptor. The desensitization remained at 20 min after the removal of adrenaline in all the five cells but disappeared at 60-90 min in four cells out of eight. Under the latter condition, the second l.t.p. was summated on the first one. Dibutyryl cyclic GMP (100 microM) blocked the generation of the l.t.p. induced by dibutyryl cyclic AMP (1 mM) as well as that of adr.-l.t.p. Muscarine (10 microM) or adenosine (1 mM), a possible candidate for raising intraterminal cyclic GMP, did not significantly affect adr.-l.t.p. These results suggest that adr.-l.t.p. is regulated by the desensitization of beta-adrenoceptor and a process which involves endogenous cyclic GMP acting on a step subsequent to the cyclic AMP production.

Cholinergic excitatory synaptic potentials of neurones in mammalian lumbar paravertebral ganglia

Synaptic potentials and the electrophysiological properties of 201 cells in the 4th lumbar paravertebral ganglia of the rabbit were studied in vitro using intracellular electrophysiological recording techniques. Cells had a mean transmembrane potential of 55.1 +/- 0.8 mV, a mean input resistance of 37.0 +/- 6.6 M omega (range 29.9-61.1) and a mean membrane time constant of 6.0 +/- 0.6 ms. Synaptic potentials in ganglionic neurones were evoked by electrical stimulation of the rami communicantes, inferior lumbar splanchnic nerves and the paravertebral chain from segments both above and below the L4 ganglion. Synaptic responses consisted of a fast, hexamethonium-sensitive component and, following short periods of higher frequency stimulation, a slow, long lasting, pirenzepine and atropine-sensitive depolarization (slow-EPSP). No phenomenon corresponding to a late slow-EPSP was observed and, under our recording conditions no cells exhibited non-cholinergic slow excitatory or slow inhibitory postsynaptic potentials. It is concluded that fast excitatory synaptic events were mediated by nicotinic receptors whereas slow excitatory synaptic events were mediated by muscarinic m1 receptors. McNeil-A-343, a muscarinic agonist, produced membrane depolarization, a decrease in membrane input conductance and in some cells a repetitive discharge of action potentials. In 60% of cells tested substance P produced a depolarization of the membrane potential with an associated decrease in membrane input conductance.

Cholinergic agonist and antagonist interactions on motor nerve endings of the rat--evidence for the involvement of presynaptic receptors in the regulation of acetylcholine release

The effects of atropine and oxotremorine on the amplitude of contraction and on the release of Ach from rat isolated diaphragm were examined. Atropine (14-112 microM) induced a dose-related increase in the amplitude of contractions, the effect being potentiated by neostigmine (10 and 100 nM) or by increasing the rate of nerve stimulation and was accompanied by no change in the twitch evoked by retrograde injection of Ach. Atropine (112 microM) depressed the post-tetanic twitch response in muscles incubated in nutrient solution containing or not non-paralyzing concentration of d-tubocurarine (1 nM). Atropine (28 and 56 microM) enhanced and d-tubocurarine (1 nM) reduced the carbachol-induced neuromuscular facilitation. Atropine (28 and 56 microM) enhanced the evoked release of Ach, the effect being potentiated by increasing the rate of nerve stimulation. Oxotremorine (5-20 microM) inhibited the muscle contraction and depressed the evoked release of Ach. The effects were both prevented by atropine. The oxotremorine-induced blockade was potentiated by d-tubocurarine (1 nM), the effect being accompanied by no change in the twitch induced by retrograde injection of Ach. These results suggest the presence of muscarinic and nicotinic presynaptic receptors participating in a mechanism which might regulate the release of Ach.

Presynaptic suppression of excitatory postsynaptic potentials in rat ventral horn neurons by muscarinic agonists

In addition to depolarizing the ventral horn cells including antidromically identified motoneurons in thin transverse neonatal rat spinal cord slice preparations, exogenously applied acetylcholine (ACh) suppressed the amplitude of excitatory postsynaptic potentials (EPSPs) either occurring spontaneously or elicited by stimulation of dorsal rootlets. A reduction of EPSPs could still be detected when the ACh-induced depolarization was nullified by hyperpolarizing current. Atropine but not D-tubocurarine effectively antagonized the depolarization and synaptic depression caused by ACh. While depressing the EPSPs, ACh had no appreciable effect on membrane depolarizations elicited by glutamate. Methacholine mimicked the depolarizing and synaptic depressant effects of ACh. The results suggest that muscarinic agonists inhibit synaptic transmission of ventral horn neurons including motoneurons by a presynaptic mechanism in reducing the output of excitatory transmitters.

Mechanism of long-term potentiation of transmitter release induced by adrenaline in bullfrog sympathetic ganglia

A mechanism of the long-term potentiation of transmitter release induced by adrenaline (ALTP) was studied by recording intracellularly the fast excitatory postsynaptic potentials (fast EPSPs). The ALTP was produced during the blockade of K+ channels at the presynaptic terminals by tetraethylammonium (TEA). The synaptic delay, possibly reflecting a relative change in the duration of an action potential at the presynaptic terminal, was not changed during the course of the ALTP. By contrast, it was significantly lengthened by TEA and other K+ channel inhibitors (4-aminopyridine and Cs+) that markedly enhanced the evoked release of transmitter. The magnitude of facilitation of the fast EPSP, induced by a conditional stimulus to the preganglionic nerve, was decreased during the generation of the ALTP, but was unchanged during the potentiation of transmitter release caused by TEA. These results, together with theoretical considerations applying the residual Ca2+ hypothesis to the facilitation, suggest that the enhancement of transmitter release during the ALTP is not caused by an increased Ca2+ influx during a presynaptic impulse owing to the blockade of K+ channel or the modulation of Ca2+ channel, but presumably is induced by a rise in the basal level of free Ca2+ in the presynaptic terminal.

Long-term potentiation of transmitter release induced by adrenaline in bull-frog sympathetic ganglia

Long-term potentiation (l.t.p.) of transmitter release induced by adrenaline in bull-frog sympathetic ganglia was studied using intracellular recording techniques. The quantal content of the fast excitatory post-synaptic potentials (fast e.p.s.p.s: evoked by the nicotinic action of acetylcholine) was potentiated for more than several hours after treatment with adrenaline (1-100 microM). A similar l.t.p. of quantal content was produced consistently by isoprenaline (10 microM) and only in a certain fraction of cells by dopamine (10 microM). The l.t.p. induced by adrenaline (10 microM) was blocked by a beta-antagonist, propranolol (1 microM), but not by an alpha-antagonist, phenoxybenzamine (1 microM). Dibutyryl adenosine 3',5'-phosphate (dibutyryl cyclic AMP) (0.8-1.0 mM), adenosine 3',5'-phosphate (cyclic AMP) (4 mM), 3-isobutyl-1-methylxanthine (10 microM), caffeine (1-2 mM), and cholera toxin (2 micrograms ml-1) applied for 20-30 min, all caused the l.t.p. of quantal content. By contrast, adenosine 5'-phosphate (AMP) (4 mM) and adenosine (4 mM) had no potentiating action. Treatment of the ganglion with adrenaline (2.5-160 microM) or dibutyryl cyclic AMP (4 mM) for 15-30 min resulted in the l.t.p. of the frequency of miniature e.p.s.p.s. The l.t.p. of quantal content induced by adrenaline was markedly suppressed by lowering temperature from 20-25 degrees C to 11-13 degrees C, and blocked by dibutyryl guanosine 3',5'-phosphate (dibutyryl cyclic GMP) (100 microM) consistently when applied together, but inconsistently when given after adrenaline. The post-synaptic sensitivity to acetylcholine was unchanged for at least 1 h after exposure to adrenaline (2.5-160 microM) or dibutyryl cyclic AMP (0.8-4 mM). It can be concluded that adrenaline produces l.t.p. of transmitter release by activating a cyclic-AMP-dependent metabolic process through the activation of beta-adrenoceptors, and that this mechanism is presumably regulated by a process involving endogenous guanosine 3',5'-phosphate (cyclic GMP).

The effects of hemicholinium-3 (Hc-3) during tetanic (TP) and posttetanic potentiation (PTP) on sympathetic ganglion

An electrophysiological analysis has been made of the synaptic plasticity in the eighth sympathetic ganglion of the toad. The mean amplitude of Compound Action Potential (CAP) recorded extracellularly was taken as a measure of the synaptic transmission. Repetitive stimulation of the preganglionic axonal fibers at 50 Hz for 40 seconds in the presence of Hc-3 led to facilitatory and depressant actions on ganglionic synaptic transmission. Hc-3 in the presence of elevated extracellular Ca2+ concentration (5.4 mM) increased Tetanic Potentiation (TP) and Posttetanic Potentiation (PTP) on eighth sympathetic ganglion. Hc-3 plus 3,4-diaminopyridine (3,4-DAP) increased synaptic transmission, TP, and PTP from postganglionic CAP responses to supramaximal preganglionic stimulation.

Muscarinic M1 and M2 receptors mediate depolarization and presynaptic inhibition in guinea-pig enteric nervous system

Intracellular recordings were made from guinea-pig myenteric and submucous plexus neurones. Nicotinic excitatory post-synaptic potentials (fast e.p.s.p.s) and slow e.p.s.p.s were recorded in both plexuses; adrenergic inhibitory post-synaptic potentials (i.p.s.p.s) were recorded from submucous plexus neurones. The effects of muscarinic agonists and antagonists were examined on the synaptic potentials in those neurones in which these substances did not change the membrane potential. Muscarine, oxotremorine, methylfurmethide and McNeil A343 reversibly depressed the amplitude of the fast e.p.s.p. in a concentration-dependent way. Hyoscine, pirenzepine and 4-diphenylacetoxy-N-methyl-piperidine (4-DAMP) caused a parallel shift to the right of the agonist dose-response curves. These muscarinic antagonists themselves did not alter the amplitudes of fast e.p.s.p.s evoked by low frequency (0.05-0.1 Hz) stimulation. Antagonist pA2 values (the negative logarithm of the dissociation equilibrium constant) were determined while recording from individual neurones. pA2 values were: pirenzepine 7.0, hyoscine 8.9, and 4-DAMP 8.7. I.p.s.p.s in the submucous plexus were also depressed by muscarinic agonists, and this was competitively reversed by pirenzepine and 4-DAMP, with apparent pA2 values of 6.9 and 8.7 respectively. Muscarinic antagonists alone increased the amplitude of the i.p.s.p. evoked either by single or repeated stimuli. This enhancement was observed with low concentrations of antagonists and did not become greater when the concentrations were increased. Muscarinic agonists depolarized about one-quarter of myenteric and submucous plexus neurones. Low concentrations of pirenzepine antagonized these depolarizations; the pA2 value was 8.4. Cholinergic slow e.p.s.p.s recorded in some myenteric neurones were depressed or abolished by pirenzepine; concentrations that caused 50% inhibition (IC50) for this action ranged from 10 to 60 nM. It is concluded that presynaptic muscarinic receptors, activation of which inhibits the release of acetylcholine and noradrenaline, are the m2 type. Post-synaptic muscarinic receptors, activation of which depolarizes the membrane, are of the m1 type. The results also suggest that acetylcholine may exert a tonic inhibition of noradrenaline release in the submucous plexus through m2 receptors, and mediates the slow e.p.s.p. in the myenteric plexus through m1 receptors.

Differential effects of metoclopramide and zetidoline on gastrointestinal motility

There is a recently formulated hypothesis that metoclopramide (MCP) may stimulate gastrointestinal (GI) motility via an antagonistic action on presynaptic, release modulating muscarinic receptors. We have tested this hypothesis by comparing MCP and zetidoline (ZTD), another putative presynaptic muscarinic antagonist, in various GI motility assays. The muscarinic and dopamine receptor binding affinity was also measured. Both MCP and ZTD acted as stimulants of electrically induced twitches of the isolated guinea-pig ileum and as antagonists of the inhibitory effects of intermittent exposure to cholinomimetics on the same preparation. In vivo, MCP significantly accelerated GI transit in mice and gastric emptying in rats. In contrast, ZTD had no effect on these in vivo parameters. Thus MCP and ZTD seem to act on the isolated guinea-pig ileum as presynaptic muscarinic antagonists. However, this mechanism apparently does not contribute to stimulation of GI motility in vivo.

Noncholinesterase actions of an irreversible acetylcholinesterase inhibitor on synaptic transmission and membrane properties in autonomic ganglia

Superfusion of the organophosphorous acetylcholinesterase inhibitor soman (pinacolyl methylphosphonofluoridate; 0.01-25 microM) produced a dose-dependent reduction of extracellularly and intracellularly recorded synaptic responses in the isolated rat superior cervical ganglia at frequencies of orthodromic stimulation that do not normally produce synaptic depression. The magnitude of depression was dependent upon the frequency of stimulation (0.02-1 Hz), was maintained after the removal of soman from the superfusion solution, and recovered by over 65% during periods of inactivity. The depression of synaptic transmission produced by soman was not dependent upon the inhibition of acetylcholinesterase (AChE) activity by this agent. Transmission was increasingly depressed by doses of soman greater than those needed to inactivate all measurable ganglionic AChE activity. Dose-dependent depression of synaptic transmission in soman also occurred after pretreatment with the irreversible AChE inhibitor diisopropylphosphofluoridate (DFP; 100 microM), which inhibited greater than 98% of the AChE activity in the ganglia. Soman produced a decline in the input resistance, resting potential, spike amplitude, and spike threshold and a reduction in the hyperpolarizing afterpotential. Soman-induced depression of synaptic transmission was not due primarily to a blockade of postsynaptic nicotinic receptors. At concentrations of soman which produced significant depression in transmission, ganglionic depolarization produced by bath-applied carbamylcholine (carbachol) was either slightly depressed or facilitated. In the presence of soman, repetitive focal application of acetylcholine or carbachol did not reveal use-dependent desensitization. Muscarinic antagonists, atropine and pirenzepine, protected against the use-dependent depression of synaptic transmission induced by soman. These results suggest that a principal site of action for soman is at the presynaptic terminal and that this site is sensitive to muscarinic receptor blockade.

Presynaptic muscarinic modulation of nicotinic excitation in the rat neostriatum

In rat neostriatal slices, cholinergic agents were tested for their effects on endogenous ACh release and on electrical activity. ACh release was evoked by 25 mM K+ during two 5-min periods between which a slice was allowed to rest for 20 min; drugs were present during the second stimulation period. In the absence of a cholinesterase inhibitor, only Ch outflow was monitored. For the recording of electrical activity, intrastriatal stimulation evoked field potentials which were monitored in the absence and presence of drugs in the perfusate. Atropine (1-100 microM) increased endogenous ACh release by 32-91% and effective doses were 10-fold lower in the presence of a cholinesterase inhibitor. Atropine also increased the amplitudes of synaptic population spikes in the field potentials. The muscarinic agonists muscarine (100 microM) and oxotremorine (25 and 100 microM) decreased endogenous ACh release. Atropine (10 microM) blocked the depressant effect of muscarine (100 microM). Muscarine (100 microM-1 mM) and oxotremorine (10-100 microM) decreased the electrically evoked excitation in the rat neostriatal slices, and their effects were reversed by atropine. Only higher concentrations of nicotine (1 and 5 mM) decreased the synaptic population spikes, but potassium-stimulated Ch outflow was not affected. It is concluded that in the neostriatum presynaptic muscarinic receptors modulate nicotinic excitation since potassium-stimulated ACh release and intrinsically evoked synaptic excitation are influenced by muscarinic drugs in the same way.

Restoration of the nicotinic receptor-channel activity from the blockade by atropine in bullfrog sympathetic ganglia

Atropine (3 microM) reduced both the nicotinic and muscarinic acetylcholine (ACh) potentials of the bullfrog sympathetic ganglion cell. However, the former was completely restored within 1 h during a sustained exposure to atropine, while the latter remained blocked. Similar restorations were observed for the depressant effects on both the amplitude and decay phase of a nerve-induced postsynaptic current. The results suggest that the sustained or repetitive binding of atropine to this site results in a new conformational state capable of passing ions almost normally, but resistant to the blockade by atropine.

Hyperpolarization following activation of K+ channels by excitatory postsynaptic potentials

We have postulated that an excitatory postsynaptic potential (e.p.s.p.) may open voltage-sensitive K+ ('M') channels, in an appropriate depolarizing range, and that this could alter the e.p.s.p. waveform. Consequently, the fast e.p.s.p. in neurones of sympathetic ganglia, elicited by a nicotinic action of acetylcholine (ACh), could be followed by a hyperpolarization, produced by the opening of M channels during the depolarizing e.p.s.p. and their subsequent slow closure (time constant-150 mg). This introduces the concept that transmitter-induced p.s.ps may trigger voltage-sensitive conductances other than those initiating action potentials, and that in the present case this could produce a true post-e.p.s.p. hyperpolarization. (Some hyperpolarizations other than inhibitory postsynaptic potentials (i.p.s.ps) have been reported to follow e.p.s.ps.) We show here that this is so.