Facilitation and inhibition of cell groups within the superior cervical ganglion of the rabbit

Short-term facilitation and depression of transmitter release at amphibian sympathetic ganglionic cells - Mathematical/computational modeling

There have been few investigations of the short-term plasticity of synaptic transmission at amphibian sympathetic ganglionic cells where the frequency of miniature excitatory postsynaptic potentials is too low to measure an accurate quantum size. This has made it difficult to investigate the mechanism of synaptic transmission at the ganglionic cells by quantal analysis. A theoretical equation, therefore, is proposed. This equation is based on the premise that transmitter release is due to the product of two factors: intracellular calcium ([Ca²⁺]_i) and acetylcholine (ACh), which is a readily releasable transmitter. The equation accounts for the mechanism of synaptic facilitation and depression of transmitter release at the ganglionic cells in the paired-pulse experiments. The purpose of the present experiment is to investigate whether the equation accounts for the mechanism of short-term plasticity of synaptic transmission produced by a train of pulses at the ganglionic cells. Trains of excitatory postsynaptic current (EPSC) were recorded, and the ratios of the n^th EPSC induced by the n^th pulse to the initial EPSC were analyzed by the equation. The results indicated that the mechanism of short-term facilitation and depression was interpreted by the equation, which met the following two requirements: [Ca²⁺]_i consisting of two components of residual Ca²⁺ and the mobilization rate of ACh which accelerated as stimulus frequencies increased. The findings were consistent with those clarified by the quantal analysis. It is suggested that the theoretical equation is also useful for the investigation of the effect of chemical substances on synaptic transmission.

Burst-patterned stimulation promotes nicotinic transmission in isolated perfused rat sympathetic ganglia

1. Intracellular recordings of small nicotinic excitatory postsynaptic potentials (EPSPs) were made from rostral cells in superior cervical ganglia (SCG) of rats during and after test stimulation of small preganglionic fibre bundles, while perfusing the isolated ganglia via their arterial vasculature. Perfusion, in contrast to superfusion of desheathed ganglia, (a) produced much more rapid and complete equilibration of drugs and ions at synaptic sites, (b) greatly reduced depression of EPSPs during high-frequency stimulation, and (c) largely prevented slowing of conduction, presumably by minimizing accumulation of K+ in the intercellular spaces surrounding these sites. 2. Preganglionic inputs were found to fall into two major groups: those in which the EPSP amplitude during 200 pulse trains was facilitated and others in which it was depressed as stimulation frequency in the train was increased from 2 to 20 Hz or from 0.2 to 1.25 Hz. Both the facilitation and the depression were presynaptic, since they occurred without changes in miniature EPSP amplitude. 3. The maximum maintained facilitation was reached at 5-10 Hz with a value 1.26 times the 1.0 Hz control. This was associated with an increase in the binomial parameter n. While long 20 Hz trains produced a similar facilitation to an early plateau, and an increase in n, EPSP amplitude declined as the train progressed. This was associated with a decrease in the binomial parameter p. 4. Unlike the 20 Hz trains, stimulation with 0.5 s long, 20 Hz bursts given every 8 s produced a marked potentiation in facilitating units and this was maintained for as long as the stimulation was continued (3-11 min). Burst-patterned potentiation was 1.66 times larger than the facilitation evoked by tonic stimulation at the same average frequency (1.25 Hz), and more than twice that achieved with long, 200 pulse trains. The potentiation was associated with increases in both n and p in the first EPSP of the burst and mainly with an increase in n at the end of the burst. Potentiation persisted unchanged for about 30 s following the return to control 0.2 Hz stimulation, before declining to control levels over the next 2-3 min. Depressing units on average showed neither burst-patterned potentiation nor post-burst-patterned potentiation. 5. All inputs tested in Locke solution in which Ca2+ was reduced to 0.5 mM with addition of 1.2 mM-Mn2+ or 3.8 mM-MgCl2 exhibited a pronounced facilitation within each burst but no extension of potentiation into ensuing bursts. Both burst-patterned potentiation and the post-burst-patterned potentiation were abolished.(ABSTRACT TRUNCATED AT 400 WORDS)

Modification of nicotinic ganglionic transmission by muscarinic slow postsynaptic potentials in the in vitro rabbit superior cervical ganglion

The influence of slow muscarinic postsynaptic potentials, i.e., the s-IPSP and s-EPSP, on synaptic transmission mediated through nicotinic receptors was studied in the superior cervical ganglion of the rabbit. Postganglionic spikes and synaptic potentials were elicited by delivery of conditioning and test stimulus pulses to afferent fibers. When paired stimulus volleys were separated by brief intervals (20-100 msec) or long intervals (1,000-8,000 msec), the population spike elicited by the test stimulus was larger in amplitude than that elicited by the conditioning volley. When paired stimulus volleys were separated by 250-500 msec, the amplitude of the population spike elicited by the test volley was smaller than that elicited by the conditioning stimulus. Gallamine, which selectively blocks the s-IPSP, reduced the suppression of the test spike which occurred when stimulus IPIs ranged between 250-500 msec. Pirenzepine, which selectively blocks the s-EPSP, reduced the late facilitation of test postganglionic spikes which occurred with stimulus IPIs greater than 1,000 msec. The non-selective muscarinic antagonist QNB, produced changes in postganglionic spike amplitude that were similar to the combined effects of gallamine and pirenzepine. The evidence indicates that the s-IPSP and s-EPSP modified the excitability state of the ganglionic neurons and subsequent synaptic transmission that was mediated through nicotinic receptors.

Clonidine inhibits electrodermal potentials induced by preganglionic stimulation

The electrodermal potential (EDP) recorded with surface electrodes between the palm and the shaven back of the right forepaw of anaesthetized and vagotomized cats was taken as a measure of the activity of cholinergic-sympathetic sudomotor nerves. EDPs were induced by preganglionic electrical stimulation of the stellate ganglion for 2 s with trains of DC pulses (2 ms duration, 0.5-128 Hz) at regular intervals of 60 s. The EDPs amounted to 12 mV and increased little with stimulation rate (14 mV). The i.v. injection of 30 micrograms/kg of the alpha 2-adrenergic agonist clonidine did not change the EDPs significantly. A consistent result was obtained in cats pretreated i.p. with 5 mg/kg reserpine 18 h beforehand for depletion of catecholamines. Three hours after the i.v. injection of 3 mg/kg guanethidine, clonidine (30 micrograms/kg i.v.) induced significant reduction of EDPs in the lower range of the stimulation rate but did not affect those at 16 and 32 Hz. Partial blockade of ganglionic nicotinic receptors by i.v. infusion of 0.08-0.3 mg/kg per min hexamethonium diminished EDPs (1 Hz) by 30-50%. Under these conditions the i.v. injection (30 micrograms/kg) or topical application of 1 microgram clonidine to the right stellate ganglion inhibited EDPs at all rates of stimulation. The inhibitory effects of clonidine could be antagonized by 200 micrograms/kg yohimbine i.v. Partial ganglionic blockade by i.v. infusion of the depolarizing blocker suxamethonium (0.2-0.4 mg/kg per min) decreased EDPs. However, the topical application of 1 microgram clonidine to the stellate ganglion during infusion of suxamethonium caused no further decrease.(ABSTRACT TRUNCATED AT 250 WORDS)

Orthodromic production of non-cholinergic slow depolarizing response in the superior cervical ganglion of the rabbit

1. A late slow depolarization in the rabbit superior cervical ganglion, recorded extracellularly as ;late late negative' (l.l.n.) response, can be elicited by suitably repetitive stimulation of cervical sympathetic nerve. The l.l.n. response is not blocked by strong nicotinic, muscarinic or adrenergic antagonists; it appears with latencies in seconds, rise times in minutes, durations of up to 20 min or more, and extracellular amplitudes that can exceed 1 mV when recorded in an air-gap chamber.2. The l.l.n. component is a graded post-synaptic response that decreases with a length constant similar to those of the known p.s.p.s (fast e.p.s.p., slow i.p.s.p., and slow e.p.s.p.). This and its other characteristics indicate that the l.l.n. response is neuronally generated and represents a non-cholinergic late slow depolarization. The term ;slow slow e.p.s.p.' is suggested for this response, to replace both ;slow depolarization' and ;late slow e.p.s.p.'.3. The amplitudes, evaluated relative to the compound action potentials, and the durations of l.l.n. responses recorded from intact neurones of rabbit superior cervical ganglion were considerably greater and more consistently producible than the non-cholinergic slow depolarizations recorded by others from impaled neurones of guinea-pig inferior mesenteric ganglion.4. The l.l.n. response does not exhibit the special sensitivity to sodium azide previously found for the muscarinic ;late negative' or slow e.p.s.p. response.5. The total number of orthodromic volleys is the chief determinant of the amplitude and duration of the l.l.n. response. Increases in pulse frequency, with no change in pulse number, exert only a minor influence on amplitude and duration of the l.l.n. response but can markedly decrease latency and rise time.6. Even very low pulse frequencies (e.g. 1/sec) are almost as effective as higher frequencies if a sufficiently large number of stimulus pulses is applied.7. The features of orthodromic production of the l.l.n., slow slow e.p.s.p. response, as well as the amplitudes and durations of this depolarization, indicate that this non-cholinergic post-synaptic response could, like the muscarinic slow e.p.s.p., play a significant role in mediating physiological activities of sympathetic ganglia.

Post-tetanic potentiation in ganglia which are blocked with hexamethonium

1 Post-tetanic potentiation (p.t.p.) of the compound action potential in the presence of hexamethonium was observed in the isolated stellate ganglion of the hamster using extracellular postganglionic recordings. 2 The magnitude of the p.t.p. was small (less than a 20% increase) in the control solution, but increased as the depth of blockade with hexamethonium was increased. 3 The magnitude of the p.t.p. was frequency-dependent between 1 and 40 Hz. 4 Atropine partially blocked the p.t.p. 5 McN-A-343, a muscarinic agonist, potentiated ganglionic transmission which had been partially blocked by hexamethonium. 6 Repetitive stimulation in the presence of hexamethonium potentiated the discharges induced by DMPP, a nicotonic agonist. The potentiation was blocked by atropine. 7 It was concluded that the p.t.p. in the presence of hexamethonium has the same characteristics as p.t.p. in the control solution. There appears to be both a muscarinic component and a presynaptic component of the p.t.p.

Facilitation and depression of synaptic transmission in amphibian sympathetic ganglia

There have been few reports concerning facilitation and depression in sympathetic ganglia9,17,40. In the present investigation, pairs of excitatory postsynaptic potentials (EPSPs) were recorded intracellularly from bullfrog paravertebral sympathetic ganglia for an analysis of the site and mechanism responsible for the phenomena of facilitation and depression of ganglionic transmission. The ratio of the amplitude of the second of a depression of ganglionic transmission. The ratio of the amplitude of the second of a pair of EPSPs divided by the first was compared to the time interval between each pair of EPSPs divided by the first was compared to the time interval between each pulse. These ratios demonstrated two phases: an earlier phase of facilitation (20-500 msec pulse intervals) and a later phase of depression (500 msec-10 sec). Additional parameters-rate of rise of synaptic potentials (dV/dt), synaptic currents (EPSCs), and synaptic conductances (Gtr)-were determined and all confirmed the results obtained with EPSPs. Furthermore, the degree of facilitation or depression could be modulated by altering the extracellular concentration of calcium. On the other hand, comparison of the amplitude of pairs of presynaptic terminal spikes did not show any variability over similar stimulus intervals, nor were the amplitudes of miniature EPSPs significantly different before or after an evoked EPSP. Therefore, the processes of facilitation and depression of ganglionic transmission occur as a result of normal nerve terminal activity. The processes are occurring simultaneously, such that one or the other may predominate depending upon the interval between pulses, as well as the relative concentration of extracellular calcium.

Characteristics of the sympathetic innervation of the nictitating membrane and of the vasculature of the nose and tongue of the cat

Vasomotor responses from the nasal mucosa and tongue, and contractions of the nictitating membrane, were recorded on stimulation of the cervical sympathetic or internal carotid nerves. Preganglionic sympathetic nerve fibres which elicited a membrane response possessed a lower threshold than those which evoked nasal vasoconstriction, while the latter displayed a lower threshold than fibres which evoked tongue vasoconstriction. The sympathetic vasodilator fibres to the tongue whose activity was revealed after alpha-receptor blockade, had a similar threshold to the vasoconstrictor fibres. Membrane contraction, nasal vasoconstriction and occasionally tongue vasoconstriction could be evoked by stimulating the internal carotid nerve. The postganglionic fibres innervating the nasal mucosa had a similar threshold to those of the nictitating membrane, which may indicate that there are small myelinated fibres innervating the mucosa. The preganglionic compound nerve action potential had four major components, S1-S4. S1, S2 and usually S3 fibres were associated with membrane contraction; S2, S3 and sometimes S1 fibres were associated with nasal vasoconstriction; and S3, usually S2 and occasionally S1 fibres were associated with vasoconstriction in the tongue. It is concluded that each of these three groups of nerve fibres, but not S4 fibres, may include fibres associated functionally with the three effectors. There was a considerable difference between the relative amplitude of the responses of the three effectors elicited by stimulation of the cervical sympathetic nerve at frequencies between 0.2 and 2 Hz. Vasoconstrictor responses were relatively larger than membrane contractions suggesting differences in the mechanisms of neurotransmission at the neuroeffector junctions.

Synaptic transmission in parasympathetic ganglia in the urinary bladder of the cat

1. Electrophysiological techniques were used to study the sacral para-sympathetic input to pelvic ganglia located on the surface of the urinary bladder of the cat. 2. Synaptic transmission in pelvic ganglia was mediated primarily via nicotinic receptors although muscarinic excitatory receptors were present. 3. The most prominent characteristic of transmission in pelvic ganglia was the marked recruitment elicited by increasing frequencies of preganglionic nerve stimulation. Post-ganglionic action potentials were of low amplitude at low frequencies of stimulation (0-1-0-5c/s), but commonly increased to five to twenty times control amplitudes during continuous stimulation at frequencies between 5 and 10c/s. Thus, it is proposed that vesical ganglia may act as "filters" in the micturition pathway; blocking the excitatory input to the bladder when intravesical pressure and parasympathetic firing is low and facilitating the neural input to the bladder during micturition when preganglionic activity is high. 4. Information was also obtained about the characteristics of the parasympathetic post-ganglionic neurones innervating the bladder. Stimulation of the preganglionic fibres in the pelvic nerve elicited a bimodal contraction consisting of an initial phasic response, which was atropine-resistant and a tonic response which was blocked by atropine. This suggests that two types of neurones, cholinergic and non-cholinergic, may mediate the sacral input to the vesical smooth muscle.

Detachment of structurally intact nerve endings from chromatolytic neurones of rat superior cervical ganglion during the depression of synaptic transmission induced by post-ganglionic axotomy

1. Electrophysiological studies showed that injury of post-ganglionic nerve fibres leads to severe and prolonged depression of synaptic transmission through the rat superior cervical ganglion, beginning within 24 h. This is in line with the results of previous studies in other species and upon other neurones. 2. electron microscopy after post-ganglionic axotomy revealed nerve endings of presynaptic type with all the specialized membrane-related features of a synaptic zone, but which were not apposed to any post-synaptic nervous element. These umusual profiles were interpreted as detached presynaptic nerve endings. In normal and control ganglia, such profiles formed at most 0-5% of all vesicle-containing profiles of presynaptic type; in ganglia with all major post-ganglionic branches cut the proportion rose to approximately 7%, between 3 and 7 d post-operatively. Over this period, the mean incidence of chromatolytic neurones was 74-6%. 3. Concomitantly, the incidence of synapses within the ganglion fell by about 75%, reaching its lowest levels between 3 and 7 d post-operatively. There was strikingly little evidence of persistence of post-synaptic membrane specializations ('membrane thickenings') following detachment of synapses. 4. At longer survival intervals the incidence of synapses gradually increased, and that of detached nerve endings gradually decreased; recovery was well advanced by 42 d. 5. The fall in the incidence of synapses was closely paralleled by a fall in the incidence of desmosome-like attachments in the ganglion; the incidence of such attachments was found to be correlated to a significant degree with that of synapses. 6. It is concluded that most or all of the synapses upon sympathetic neurones become physically dissociated during the chromatolytic reaction of these neurones to axotomy. The failure to persist of ultrastructurally specialized post-synaptic sites, and the loss of desmosomes (particularly marked for those involving purely post-ganglionic nervous elements) suggest that the post-ganglionic neurone is losing all its specializations for attachment. 7. Some evidence suggests that the satellite cells may effect the final separation between pre- and post-synaptic structures.

Observation on the localization of mechanoreceptors in the kidney and afferent nerve fibres in the renal nerves in the rabbit

1. The distribution and localization of mechanoreceptors in the kidney were studied by recording afferent impulses from the renal nerve bundle or from single nerve fibres in the isoloted kidney preparation in the rabbit. 2. It was observed that mechanoreceptors are distributed in the cranial, central and caudal portions as well as the pelvic portion of the kidney. Diameter range of single nerve fibres from which afferent impulses were recorded was from 2 to 8 mum. 3. Histological studies show that the renal nerve possesses abundant non-myelinated nerve fibres with a relatively small number of myelinated nerve fibres. The myelinated axons had diameters ranging from 0-5 to 13-4 mum and the peak of the unimodal distribution curve was 1-5--2-4 mum.

The facilitatory actions of 5-hydroxytryptamine and bradykinin in the superior cervical ganglion of the rabbit

1 The effects of 5-hydroxytryptamine (5-HT) on ganglionic transmission and on intrinsic modulation of transmission have been re-examined and compared with the effects of bradykinin by means of electrophysiological techniques.2 Early facilitation, which is maximal 40-75 ms after a conditioning stimulus, was considerably enhanced by 5-HT. This enhancement was concentration-dependent, the threshold concentration lying between 0.1 and 1 muM. With concentrations of 5-HT 10 muM or greater, there was some depression of the Sa response to the conditioning stimulus.3 5-HT reduced or abolished the inhibition of a test response induced by a conditioning response 100-300 ms earlier. Facilitation was observed at these intervals at concentrations of 5-HT of 25 muM or greater.4 Late facilitation, which is maximal 700-2000 ms after a conditioning stimulus, was increased by 5-HT, but the effect was not as great as on early facilitation and was not always seen with a concentration of 1 muM.5 Bradykinin reduced early facilitation but increased the amplitude of the transmitted action potential in response to a single stimulus. The threshold concentration producing these effects was between 1 and 2 muM.6 5-HT produced a rapid depolarization of the ganglion cell membrane which was followed by an after-hyperpolarization.7 Bradykinin either produced no measurable change in ganglion cell resting potential or only very small, transient depolarizations.8 The depression of transmission, enhancement of intrinsic facilitation and the depolarization of the ganglion cell membrane induced by 5-HT may indicate more than one mode of action of this amine at the ganglionic synapse.