Electrophysiology of neurones of the inferior mesenteric ganglion of the cat

Paracrine control of vascular innervation in health and disease

Proper vascular regulation is of paramount importance for the control of blood flow to tissues. In particular, the regulation of peripheral resistance arteries is essential for several physiological processes, including control of blood pressure, thermoregulation and increase of blood flow to central nervous system and heart under stress conditions such as hypoxia. Arterial tone is regulated by the periarterial autonomic nervous plexus, as well as by endothelium-dependent, myogenic and humoral mechanisms. Underscoring the importance of proper vascular regulation, defects in these processes can lead to diseases such as hypertension, orthostatic hypotension, Raynaud's phenomenon, defective thermoregulation, hand-foot syndrome, migraine and congestive heart failure. Here, we review the molecular mechanisms controlling the development of the periarterial nerve plexus, retrograde and localized signalling at neuro-effector junctions, the molecular and cellular mechanisms of vascular regulation and adult plasticity and maintenance of periarterial innervation. We particularly highlight a newly discovered role for vascular endothelial growth factor in the structural and functional maintenance of arterial neuro-effector junctions. Finally, we discuss how defects in neuronal vascular regulation can lead to disease.

Neurotrophins and target interactions in the development and regulation of sympathetic neuron electrical and synaptic properties

The electrical and synaptic properties of neurons are essential for determining the function of the nervous system. Thus, understanding the mechanisms that control the appropriate developmental acquisition and maintenance of these properties is a critical problem in neuroscience. A great deal of our understanding of these developmental mechanisms comes from studies of soluble growth factor signaling between cells in the peripheral nervous system. The sympathetic nervous system has provided a model for studying the role of these factors both in early development and in the establishment of mature properties. In particular, neurotrophins produced by the targets of sympathetic innervation regulate the synaptic and electrophysiological properties of postnatal sympathetic neurons. In this review we examine the role of neurotrophin signaling in the regulation of synaptic strength, neurotransmitter phenotype, voltage-gated currents and repetitive firing properties of sympathetic neurons. Together, these properties determine the level of sympathetic drive to target organs such as the heart. Changes in this sympathetic drive, which may be linked to dysfunctions in neurotrophin signaling, are associated with devastating diseases such as high blood pressure, arrhythmias and heart attack. Neurotrophins appear to play similar roles in modulating the synaptic and electrical properties of other peripheral and central neuronal systems, suggesting that information provided from studies in the sympathetic nervous system will be widely applicable for understanding the neurotrophic regulation of neuronal function in other systems.

Morphology and electrophysiology of neurons in dog paraventricular nucleus: in vitro study

The paraventricular nucleus (PVN) of the hypothalamus plays an important role in regulating gut motility. To date, there have been no intracellular electrophysiological studies of dog PVN neurons in vitro. The aims of this study were to: (1) adapt brain slice methods developed for studies of rodent CNS tissue to canine CNS tissue; and (2) study the electrophysiology and morphology of single neurons of the dog paraventricular nucleus (PVN). Coronal hypothalamic slice preparations (400 microm thick) of dog brain were used. Three groups of PVN neurons were classified based on their firing pattern. Continuous firing neurons (n=32) exhibited continuous ongoing action potentials (APs). Burst firing neurons generated bursts of APs (n=19). Intermittent firing neurons had only a few spontaneous APs. In contrast to continuous firing neurons, 14 of 19 burst firing neurons and 3 of 7 intermittent firing neurons responded to depolarizing current with a Ca2+-dependent low-threshold potential. Twenty-one PVN neurons studied electrophysiologically were filled with biocytin. Continuous firing neurons (n=12) had oval-shaped soma with two or three sparsely branched dendrites. Branched axons were found in two continuous firing neurons, in which one branch appeared to terminate locally. Burst firing neurons (n=8) generally had triangular soma with 2 to 5 branched dendrites. In summary, the brain slice technique was used to study the morphology and electrophysiology of single neurons of the dog brain. Electrophysiological and morphological properties of the three neuron groups were identified and discussed.

The three-dimensional structure of neurons in the guinea pig inferior mesenteric and pelvic hypogastric ganglia

The three-dimensional (3-D) morphology of sympathetic inferior mesenteric ganglion (IMG) neurons and sympathetic-parasympathetic pelvic hypogastric ganglion (PHG) neurons was studied using confocal laser scanning microscopy. Cell bodies of IMG neurons were disc-shaped and were arranged orderly in layers. The dendritic arbor of individual neurons was confined to a plane with a thickness that did not exceed the thickness of the parent cell body. The actual dendritic surface area (71,400 micron 2) and volume (81,500 micron 3) of the IMG neurons were up to 100-fold larger than previously reported for similar sympathetic neurons using data of 2-D measurements and estimations of the third dimension. PHG neurons had a much smaller dendritic surface area (4100 micron 2) and volume (2400 micron 3) compared to IMG neurons. The ratio dendritic/somal surface area for individual IMG and PHG neurons ranged from 5:1 to 14:1 and from 0.1:1 to 6:1, respectively. The total dendritic path-length was 8-42 times greater for IMG than for PHG neurons. Neurons in the IMG were either stellate with radiating dendrites or bipolar-shaped with dendrites emerging from the two poles of the cell body. Neurons in the PHG were of two morphological types. One type (nearly 2/3 of all the imaged PHG neurons) had two to seven relatively long dendrites and an axon; the other type had only one to three short unbranched dendrites and an axon. The spatial organization of neurons within the ganglia and the structural features of individual neurons are likely to have important implications regarding connectivity patterns between neurons within the ganglion as well as on how information is processed by the ganglion.

Electrophysiological properties of lumbosacral preganglionic neurons in the neonatal rat spinal cord

The electrophysiological properties of parasympathetic preganglionic neurons (PGN) in L6 and S1 spinal cord slices from neonatal rats were studied using the patch clamp techniques. PGN were identified by retrograde axonal transport of a fluorescent dye (Fast Blue) injected intraperitoneally before the experiment. PGN in the intermediolateral region of the spinal cord were divided into two classes (tonic PGN and phasic PGN) on the basis of firing properties during prolonged (300 ms) depolarizing current pulses. Tonic neurons exhibited a prolonged discharge (average maximum: 5.6); whereas phasic PGN fired on average only 1.4 spikes during depolarizing pulses. PGN were usually oval in shape. The mean long axis of tonic PGN (20.7+/-0.5 microm) was significantly (P<0.05) larger than that of phasic PGN (16.7+/-0.3 microm). Tonic and phasic PGN had similar resting membrane potentials, thresholds for spike activation, input resistances and action potential durations. The duration of the after-hyperpolarization (AHP) in tonic PGN (200.5+/-11.9 ms) was longer than in phasic PGN (137.6+/-9.8 ms). 4-aminopyridine (4-AP, 0. 5 mM) reduced the threshold for spike activation in tonic and phasic PGN. 4-AP also unmasked tonic firing in phasic PGN (average maximum: 5.5 spikes during 300 ms depolarizing current pulses) and increased firing frequency by 19% in tonic PGN. These data indicate that the different discharge patterns of parasympathetic PGN are dependent in part on differences in the expression of 4-AP-sensitive K(+) channels. The two types of PGN may provide an innervation to different targets in the pelvic viscera.

PACAP27 and other neuropeptides in the inferior mesenteric ganglion

The presence and location of PACAP27-like immunoreactivity (PACAP27-LI) in the colon-inferior mesenteric ganglion (IMG) reflex pathway and the effect of exogenously administered PACAP27 on the excitability of IMG are reported. The results provide morphological and electrophysiological support for the hypothesis that PACAP modulates reflex activity between the large intestine and IMG. The intense excitatory effect would be expected to increase the rate of action potential discharge in IMG neurons, increasing sympathetic drive to the colon thereby decreasing of colonic activity.

Integrative properties of the major pelvic ganglion in the rat

The integrative properties of the major pelvic ganglion were investigated in the male rat on an in vitro preparation consisting of the ganglion connected to the hypogastric, pelvic and cavernous nerves. The electrical activity of ganglionic neurones was recorded using intracellular recording techniques. The neurones never displayed any spontaneous activity and were found to be only of the phasic type. Fast synaptic activation could be evoked in the same neurone by stimulating the hypogastric, pelvic and cavernous nerves with a single pulse. This activation was not affected by hexamethonium plus D-tubocurarine but was abolished by mecamylamine. During nerve stimulation with a train of pulses, a gradual depression of the fast synaptic responses occurred. This phenomenon increased with the frequency of stimulation. Our results show that the neurones of the major pelvic ganglion can integrate central inputs from both the sympathetic and parasympathetic systems as well as peripheral inputs. This activation is modulated by a rate limiting mechanism. Thus the major pelvic ganglion should not be considered as a simple relay but as a true integrative nervous centre which opens new perspectives concerning its role in the nervous control of the urogenital and gastrointestinal tracts.

The mammalian sympathetic prevertebral ganglia: integrative properties and role in the nervous control of digestive tract motility

The prevertebral ganglia which are a constitutive part of the sympathetic system have long been considered as a simple relay on this efferent pathway. In fact, these ganglia must be considered as true peripheral nervous centres. They possess various integrative properties, such as projections of central and peripheral inputs onto the ganglionic neurones, gating of these projections and pacemaker activity of the ganglionic neurones. These properties explain the ability of these ganglia to participate in the regulation of various visceral functions, including digestive tract motility.

Synaptically activated low-threshold muscarinic inward current sustains tonic firing in rabbit prevertebral sympathetic neurons

Whole-cell patch-clamp experiments were performed on non-dissociated rabbit coeliac sympathetic neurons in the presence of nicotinic blockers. Coeliac neurons were classified as either silent or spontaneously active (pacemaker) cells. Under voltage-clamp conditions, pacemaker cells exhibited a steady-state N-shaped current-voltage relationship due to the presence of a persistent voltage-dependent inward current in the potential range of -100 to approximately -20 mV. This inward current sustained the regular firing activity of pacemaker cells and was absent from quiescent neurons. It disappeared in the presence of tetrodotoxin and in low Ca(2+)-high Mg2+ external solutions and was enhanced by eserine. Splanchnic nerve stimulation induced slow regenerative depolarizations and firing discharges in silent neurons by activating a low-threshold voltage-sensitive inward current. The synaptic current had a U-shaped voltage-dependence from -96 to approximately -20 mV and exhibited the dynamic properties of the muscarinic voltage-dependent inward current INa,M. It gave the current-voltage relationship an N shape similar to that observed in spontaneously active cells. The muscarinic antagonists atropine and pirenzepine abolished the inward current present in pacemaker cells and that induced by nerve stimulation in silent neurons. These data provide evidence that both spontaneous firing activity and nerve-evoked depolarizing responses in coeliac neurons are sustained by the activation of the muscarinic Na,M current. The tonic activation of INa,M in spontaneously firing cells results from a sustained Ca(2+)-dependent tetrodotoxin-sensitive release of acetylcholine. This study provides evidence that the role of the muscarinic receptors is not purely a neuromodulatory one, but that these receptors are directly involved in ganglionic neurotransmission.

Adrenergic mechanisms in the control of gastrointestinal motility: from basic science to clinical applications

Over the years, a vast literature has accumulated on the adrenergic mechanisms controlling gut motility, blood flow, and mucosal transport. The present review is intended as a survey of key information on the relevance of adrenergic mechanisms modulating gut motility and will provide an outline of our knowledge on the distribution and functional role of adrenoceptor subtypes mediating motor responses. alpha1-Adrenoceptors are located postsynaptically on smooth muscle cells and, to a lesser extent, on intrinsic neurons; alpha2-adrenoceptors may be present both pre- and postsynaptically, with presynaptic auto- and hetero-receptors playing an important role in the modulation of neurotransmitter release; beta-adrenoceptors are found mainly on smooth muscle cells. From a clinical standpoint, adrenoceptor agonists/antagonists have been investigated as potential motility inhibiting (antidiarrheal/antispasmodic) or prokinetic agents, although at present their field of application is limited to select patient groups.

Lack of evidence for P2X-purinoceptor involvement in fast synaptic responses in intact sympathetic ganglia isolated from guinea-pigs

Recordings were made from neurons in intact pre- and paravertebral guinea-pig sympathetic ganglia using intracellular microelectrodes. Fast excitatory synaptic responses were evoked by stimulation of preganglionic and peripheral nerve trunks. Suramin (0.1-1 mM) did not affect passive or active membrane properties, nor the amplitude or decay time-course of either synaptic potentials or synaptic currents. Synaptic responses were reversibly reduced in amplitude by hexamethonium (98.7 +/- 0.8%, 50-1000 microM) and d-tubocurarine (95.3 +/- 2.6%, 10-280 microM). ATP (0.5-1 mM) and alpha,beta-methylene ATP (1-40 microM) applied in the bathing solution produced no significant changes in resting membrane potential or input resistance. Prolonged application (up to 25 min) of either compound was also without effect on synaptic responses. These substances also did not affect ganglion cells axotomized one to five days in vivo. These data suggest that activation of P2X-purinoceptors is not involved in the generation of fast excitatory synaptic responses in intact guinea-pig sympathetic ganglia. It appears that dissociation of these neurons must markedly increase their sensitivity to purine nucleotides.

Sub-nanomolar concentrations of ciguatoxin-1 excite preganglionic terminals in guinea pig sympathetic ganglia

The actions of low concentrations of ciguatoxin-1 (CTX-1, 0.2-0.8 nM) in guinea-pig sympathetic ganglia have been analysed using intracellular recording techniques in vitro. The effects of CTX-1 were graded with concentration but sensitivity varied markedly between neurones in the same preparation. Other than an initial transient (approximately 10 min) depolarization of some ganglion cells accompanied by an increase in input resistance, passive electrical properties did not significantly differ from controls. Amplitude and threshold of action potentials evoked by depolarizing current and threshold, latency and form of the initial responses to nerve stimulation were also not affected. Exposure to CTX-1 generated marked increases in the frequency of spontaneous excitatory synaptic potentials which often occurred in bursts (15-66 Hz) of similar amplitudes. Single stimuli to incoming nerves produced repetitive synaptic responses arising from preganglionic, but not from peripheral afferent, axons. Following brief (< 5 min) exposure to CTX-1, these effects declined over 30 min but, after longer exposure (> 15 min), they persisted for several hours despite continuous washing. All activity generated by CTX-1 was significantly reduced or abolished by d-tubocurarine (10(-5)-10(-4) M), hexamethonium (10(-5) M), tetrodotoxin (10(-7)-10(-6) M), omega-conotoxin (10(-7) M), reduced Ca2+ (0.1 mM)/raised Mg2+ (10 mM), raised Ca2+ (6 mM) or raised Mg2+ (25 mM). The data suggest that CTX-1 activates preganglionic axons by modifying the voltage sensitivity of a subpopulation of Na+ channels. Effects on these unmyelinated axons occur at much lower concentrations than have been reported to affect myelinated ones. Many of the symptoms of ciguatera poisoning might be explained by activity in autonomic and perhaps other unmyelinated nerve terminals.

Different types of ganglion cell in the cardiac plexus of guinea-pigs

1. Intracellular recordings were made from the parasympathetic ganglion cells that lie in the epicardium of the left atrium of guinea-pig heart near the interatrial septum. 2. Three distinct types of neurone were identified on the basis of their electrophysiological properties. In one group of neurones, S cells, somatic action potentials were followed by brief after-hyperpolarizations. In the other two sets of neurones, somatic action potentials were followed by prolonged after-hyperpolarizations. The neurones with prominent after-hyperpolarization were further subdivided: one group of neurones, P cells, showed inward rectification at membrane potentials near the resting membrane potential whilst neurones in the other group, SAH cells, did so only at more negative potentials. 3. In the group of neurones that displayed inward rectification at potentials near rest, rectification resulted from the activation of an inward current, which resembled the hyperpolarization-activated inward current present in cardiac muscle pacemaker cells. 4. The three different types of neurone received different patterns of synaptic input. Each SAH cell received a synaptic excitatory connection from the vagus which in most cells released sufficient transmitter to initiate an action potential in that cell; several SAH cells also received a separate connection, which could be activated by local stimulation. Although most S cells failed to receive a synaptic input from the vagus, all of those tested received an excitatory synaptic input which could be activated by local stimulation. Virtually all P cells failed to receive a synaptic input from the vagus; in addition, local stimulation failed to initiate synaptic potentials in P cells. 5. When the structure of cardiac ganglion cells was determined, by loading the cells with either biocytin or neurobiotin, it was found that most cells lacked extensive dendritic processes. S cells were invariably monopolar, most P cells were dipolar or pseudodipolar, whereas many SAH cells were multipolar. 6. In many neurones an on-going discharge of action potentials was detected in the absence of obvious stimulation. In S and SAH cells, the action potentials resulted from an on-going discharge of excitatory synaptic potentials. However, when a spontaneous discharge of action potentials was detected in P cells a discharge of excitatory synaptic potentials was not detected. 7. The results are discussed in relation to the idea that the three different types of cell may have different functions and that some of the cells may be organized in such a way as to permit the local handling of neuronal information within the heart.

Potassium currents in rat prevertebral and paravertebral sympathetic neurones: control of firing properties

1. Intracellular recordings were made from rat sympathetic neurones in isolated superior cervical ganglia (SCG), coeliac ganglia (CG) and superior mesenteric ganglia (SMG). 2. Based on their response to a maintained depolarizing current stimulus, neurones were classified as 'phasic' or 'tonic'. All neurones in the SCG were phasic, 85% of the neurones in the SMG and 58% of the neurones in the CG were tonic, and the remainder were phasic. 3. The voltage response of phasic and tonic neurones around threshold to a constant current step was markedly different. The response of phasic neurones was biphasic with an initial depolarizing response followed by significant repolarization of the membrane potential. In contrast, tonic neurones became more depolarized during a prolonged current step. 4. The underlying currents were studied using single-electrode voltage-clamp recording. The M-current was present in all phasic neurones, but was very weak or absent in tonic neurones. 5. An A-current was apparent in both phasic and tonic neurones. The voltage-dependent activation, steady- state inactivation, and current density of the A-current were all similar in phasic and tonic cells. 6. A low- threshold, slowly inactivating outward current (D2-current) was observed exclusively in tonic neurones. The slow inactivation of this current appeared to underlie the slow depolarizing ramp seen in response to a maintained depolarizing current step. 7. Computer simulations, based on the voltage-clamp data, suggested that the different firing properties of phasic and tonic neurones could be accounted for by differential expression of the M-current.

New insights into the organization of a gastroduodenal inhibitory reflex by the coeliac plexus

The mechanisms involved at the prevertebral ganglionic level in a gastroduodenal inhibitory reflex were investigated in the rabbit on an in vitro preparation of the coeliac plexus connected to the stomach and duodenum. Intraluminal gastric and duodenal pressures were measured using water-filled balloons. Gastric distension inhibited duodenal motility via a nerve reflex which was abolished by section of the nerves connecting the coeliac plexus to the viscera. Superfusion of the coeliac plexus with a low Ca(2+)-high Mg2+ solution abolished the gastroduodenal inhibitory reflex, indicating a synaptic link at the ganglion level. The reflex was unaffected by superfusion of the coeliac plexus with hexamethonium and tubocurarine, ruling out a nicotinic mechanism. The reflex persisted when the coeliac plexus was superfused with tetrodotoxin or when the nerves connecting the coeliac plexus to the viscera were superfused with a Na(+)-free solution; these results indicate that the reflex does not involve sodium-dependent action potentials. Moreover, superfusion of the nerves connecting the coeliac plexus to the viscera with a calcium blocker or with a Ca(2+)-free solution also failed to abolish the reflex, suggesting that calcium-dependent action potentials are not involved. Our study demonstrates that a gastrointestinal inhibitory reflex via the coeliac ganglion is not based on fast synaptic inputs or action potentials. These results provide new insights concerning the physiology of the sympathetic prevertebral ganglia.

Changes in enkephalin immunoreactivity of sympathetic ganglia and digestive tract of the cat after splanchnic nerve ligation

The aim of the present study was to analyze changes in the enkephalin immunoreactivity of sympathetic prevertebral ganglia coeliac plexus and inferior mesenteric ganglion) and intestinal tract (myenteric plexus and external muscle layers) in cats 2 days after left thoracic splanchnic nerve ligation, using radioimmunoassay and immunohistochemical techniques. Specific polyclonal antibodies directed against methionine- and leucine-enkephalin were used. The nerve ligation led to a considerable increase in the enkephalin immunoreactivity in the cranial part of the ligated nerves. This finding confirms the presence, in the cat, of an enkephalin output originating from thoracic spinal structures which are probably enkephalin-containing preganglionic neurons. In prevertebral ganglia the nerve ligation induced a marked decrease in the enkephalin immunoreactivity, which was probably due to the interruption of thoracic enkephalin efferents projecting towards both the coeliac plexus and the inferior mesenteric ganglion. In the digestive tract, the nerve ligation depressed the methionine-enkephalin immunoreactivity only in the gastro-duodenal region, and had no effect on the ileo-colonic region. The results of the present study add to the growing evidence that the sympathetic nervous system is involved in regulating the enteric enkephalinergic innervation, which is probably involved in controlling the intestinal motility.

Electrical and integrative properties of rabbit sympathetic neurones re-evaluated by patch clamping non-dissociated cells

1. Voltage recordings were performed on non-dissociated sympathetic neurones from rabbit coeliac ganglia using the whole-cell configuration of the patch clamp technique. 2. Cells were classified depending on their firing pattern as silent cells (63%) producing either phasic (24%) or tonic (76%) spike discharge in response to depolarizing currents, and pacemaker cells (37%). 3. All the cells produced large overshooting spikes and prolonged postspike after-hyperpolarization. The peak-to-peak spike amplitude was 113.8 +/- 1 mV. Spikes were shortened and the after-hyperpolarization was suppressed when calcium channel blockers (Cd2+ and La3+) were added. 4. Silent cells have a resting potential of -58.8 +/- 1.5 mV. At potentials ranging from -50 to -90 mV, the input impedance was 490 +/- 27 M omega at 22-24 degrees C and 426 +/- 47 M omega at 35-36 degrees C. The time constant at voltages corresponding to the high input impedance region was 126 +/- 7 ms at 22-24 degrees C and 86 +/- 7 ms at 35-36 degrees C. 5. The firing frequency of the pacemaker cells was 3.2 +/- 0.5 Hz at 35-36 degrees C in the presence of nicotinic blockers. Evidence is given that the firing did not result from cell injury but was induced by an intrinsic pacemaker mechanism. Input impedance of pacemaker neurones was 580 +/- 47 M omega at 22-24 degrees C and 473 +/- 56 M omega at 35-36 degrees C. 6. Most of the pacemaker cells (63%) were motoneurones, since they were antidromically fired by stimulating post-ganglionic nerves. In addition, they received synaptic inputs from both preganglionic fibres (splanchnic nerves) and the periphery (postganglionic nerves). Long-lasting depolarizations were induced in either silent or pacemaker cells by single shocks applied to pre- and postganglionic nerves. 7. Slowly rising voltage ramps revealed the presence of an N-shaped current-voltage relationship in voltage clamped pacemaker cells. The negative slope was located in a subthreshold voltage range, between -83.4 +/- 1.4 and -59.0 +/- 1.8 mV. It was induced by the activation of a low threshold persistent inward current. Although it was tiny (22 +/- 3 pA at its peak level) this current brought the null-current voltage up to -41.0 +/- 1.4 mV, which resulted in continuous firing. 8. Due to the instability introduced by the N-shaped I-V relationship, pacemaker cells can display bistable behaviour characterized by hyperpolarizing responses.(ABSTRACT TRUNCATED AT 400 WORDS)

Single-channel and whole-cell recordings from non-dissociated sympathetic neurones in rabbit coeliac ganglia

A procedure is described for performing patch-clamp recordings on mammalian sympathetic neurones within intact ganglia. The plasma membrane of superficial neurones was cleaned by blowing (1.5-3 h) a gentle stream of Ringer saline onto ganglia, the connective sheath of which was previously softened by a short protease treatment. This procedure preserved the intraganglionic connectivity so that the neurones could be activated either synaptically or antidromically by stimulating the appropriate nerves. Depending on the duration of the mechanical cleaning step, recordings were performed on either the neurones or the satellite glial cells covering the neuronal cell bodies. The applicability of the various configurations of the patch-clamp technique to studying sympathetic neurones is illustrated by recordings of whole-cell voltage, whole-cell currents and single-channel currents in cell-attached and excised patches. With these techniques, the resolution of the membrane current recordings is higher than with conventional microelectrodes. The results obtained show that mammalian sympathetic neurones have a very high input resistance (0.5 G omega), are electronically compact and may display pacemaker activity. These techniques provide a useful tool for studying the synaptic transmission and neuromodulation mechanisms operating within the sympathetic ganglia.

Differentiation of sympathetic neurones projecting in the hypogastric nerves in terms of their discharge patterns in cats

1. Sympathetic neurones that project in the hypogastric nerves (HGNs) were analysed for their discharge patterns in anaesthetized cats. The activity of these neurones was recorded from their axons. Afferents from the pelvic organs (urinary bladder, colon, anal canal), and arterial baro-and chemoreceptors were stimulated. 150 postganglionic and nine preganglionic neurones were analysed. 2. The postganglionic neurones exhibited reflex patterns that were typical of visceral vasoconstrictor neurones and various types of motility-regulating neurones. Most motility-regulating neurones and all visceral vasoconstrictor neurones had ongoing activity. 3. Postganglionic motility-regulating neurones were not influenced by stimulation of arterial baro-and chemoreceptors, but showed distinctive reflexes on stimulation of afferents from pelvic organs. Three subgroups of motility-regulating neurones were identified: type 1 neurones (34% of the sample of postganglionic neurones) were excited from the urinary bladder and inhibited or not influenced from the colon. Type 2 neurones (14%) exhibited a reflex pattern reciprocal to that of the type 1 neurones. Anal motility-regulating neurones (8%) were only influenced from the anal canal. The most powerful reflexes in these types of motility-regulating neurones were elicited by mechanical stimulation of the anal mucosa. 4. Postganglionic visceral vasoconstrictor neurones (16% of the sample) were under powerful inhibitory control from the arterial baroreceptors and weakly excited by stimulation of arterial chemoreceptors. Visceral stimuli had little or no effect on most of these neurones. Some visceral vasoconstrictor neurones exhibited some overlap in their functional properties with motility-regulating neurones. 5. Twenty-eight per cent of our sample of postganglionic neurones showed no reflexes to the afferent stimuli used. About half of these neurones had on-going activity. 6. Nine preganglionic neurones with on-going activity were identified. Most of these neurones behaved like visceral vasoconstrictor or motility-regulating neurones. 7. This study shows that the majority of postganglionic neurones that project in the HGNs can be divided into the same functional types as the lumbar preganglionic neurones that project to the inferior mesenteric ganglion. The proportions of the different types of neurones are similar at pre- and postganglionic levels. Thus the centrally generated patterns of activity are most likely faithfully transmitted from the spinal cord to the target organs in the pelvic cavity in functionally separate pathways.

Modulation of synaptic transmission in the rabbit coeliac ganglia by gastric and duodenal mechanoreceptors

The involvement of duodenal and gastric mechanoreceptors in the modulation of synaptic transmission was investigated in a rabbit sympathetic prevertebral ganglion. The present study was performed in vitro on the coeliac plexus connected to the stomach and the duodenum. The electrical activity of ganglionic neurons was recorded using intracellular recording techniques. The patterns of synaptic activation of these ganglionic neurons in response to the activation of mechanoreceptors by gastric or duodenal distension were investigated. Although gastric or duodenal distension was unable to elicit any fast synaptic activity in ganglionic neurons, it produced either an inhibition or a facilitation of the fast nicotinic excitatory postsynaptic potentials elicited by stimulation of the thoracic splanchnic nerves. In addition, this distension triggered long-lasting (3-11 min) modifications in the electrical properties of the ganglionic neurons, i.e. slow depolarizations (6-18 mV) or slow hyperpolarizations (3-6 mV), which were sometimes associated with a decrease in the input membrane resistance. After cooling of the nerves connecting the coeliac ganglia to the stomach, the activation of gastric or duodenal mechanoreceptors was no longer able to modify the fast synaptic activation or the electrical properties of the ganglionic neurons. The results demonstrate that gastric and duodenal mechanoreceptors project onto neurons of the coeliac ganglia and change their excitability as well as the central inputs they receive. The long duration of these modifications suggests that gastric and duodenal mechanoreceptors can modulate the activity of the neurons of the coeliac ganglia.

Enkephalins in the inferior mesenteric ganglion of the cat and in the area of the lower digestive tract innervated by this ganglion: quantification by radio-immunoassay and characterization by high pressure liquid chromatography

Met-enkephalin, Leu-enkephalin and Met-enkephalin-Arg-Gly-Leu were quantified and characterized in the cat inferior mesenteric ganglion and in the area of the lower digestive tract innervated by this ganglion, including the proximal colon, distal colon and internal anal sphincter. In the structures studied, the concentrations of enkephalins expressed as femtomole/mg of wet tissue ranged from 66 to 160 with Met-enkephalin, from 15 to 45 with Leu-enkephalin and from 2 to 12 for Met-enkephalin-arg-gly-leu. In the lower digestive tract, the Met- and Leu-enkephalin content decreased from the proximal colon to the internal anal sphincter. The Met-enkephalin versus Leu-enkephalin ratio of the structures investigated were as follows: inferior mesenteric ganglion 3.2, proximal colon 4.4, distal colon 5, internal and sphincter 4.5. In individual samples of all the structures assayed the results of high pressure liquid chromatography (HPLC) analysis pointed to the presence of authentic Met- and Leu-enkephalin. HPLC analysis could not be carried out on Met-enkephalin-Arg-Gly-Leu due to the very low concentrations of this peptide in all the structures assayed. Our results, combined with those of previous immunohistochemical and physiological studies, support the idea that enkephalins are involved in the nervous control of the motility of the lower digestive tract.

Effects of potassium channel-blocking agents on neurons in the inferior mesenteric ganglion in guinea-pig

Intracellular recordings were made from neurons (n = 121) in the inferior mesenteric ganglion (IMG) in guinea-pig. The pharmacological actions of 4-aminopyridine (4-AP), barium ions (Ba2+) and tetraethylammonium ions (TEA) were studied on IMG cells which received an excitatory, cholinergic input from mechanosensory nerves in the gastrointestinal tract. 4-AP mediated an excitatory action which involved two separate effects. Firstly, 4-AP increased the incidence of spontaneously occurring, fast EPSPs which gave rise to a spontaneous discharge of action potentials. This indirect, excitatory effect was attributed to an increase in the spontaneous release of acetylcholine from excitatory nerves to the IMG. Secondly, 4-AP altered the excitability of IMG cells and brought about burst discharges and continuous discharges of action potentials. This direct, excitatory effect was not dependent on the spontaneous release of acetylcholine; instead, it was attributed to the blockade of a potassium current similar to the A-current (IA). The excitatory action of Ba2+ also involved two separate effects. Firstly, Ba2+ increased the incidence of spontaneously occurring, fast EPSPs which gave rise to a spontaneous discharge of action potentials. This indirect, excitatory effect was interpreted as Ba2+ mimicking the actions of Ca2+ to facilitate the spontaneous release of acetylcholine. Secondly, Ba2+ altered the excitability of IMG cells and brought about a continuous discharge of action potentials. This excitatory effect was attributed to the blockade of a potassium current similar to the M-current (IM). TEA exerted an excitatory, then inhibitory, action on IMG cells. Initially, TEA brought about the continuous discharge of action potentials; firing gradually arrested as IMG cells depolarized slowly and a depolarizing block of excitation (i.e. inhibition) developed. The block on excitation was relieved by first restoring the resting membrane potential of IMG cells with hyperpolarizing current-clamp. Thereafter, action potentials were elicited by anode-break excitation by temporarily removing the hyperpolarizing current-clamp. The durations of action potentials and afterspike hyperpolarizations were prolonged in the presence of TEA. The effect of TEA on the action potential of IMG cells was attributed to the blockade of the delayed rectifier (IK). The effect on the afterspike hyperpolarization was considered the indirect consequence of a blockade of IK; it allowed the development of an inward calcium current which enhanced the calcium-activated, potassium current (IKCa) mediating afterhyperpolarizations.

Electronic characteristics and membrane properties of neurons in the inferior mesenteric ganglion in guinea-pig

Intracellular recordings were made from neurons (n = 75) in the inferior mesenteric ganglion (IMG) in guinea-pig to study the electronic characteristics and membrane properties of IMG cells which receive an excitatory, cholinergic input from mechanoreceptors in the gastrointestinal tract. An excitatory, cholinergic innervation from the periphery served as an index to identify the sympathetic neurons involved in the reflex inhibition of muscle tone when the gut is distended. Functionally identified neurons in the IMG were categorized into 4 subclasses (I, II, III and IV). Subclasses I and II comprised neurons which fired phasically (rapidly adapting), with the neurons in subclass II showing a voltage relaxation in the electronic potentials elicited by depolarizing current-clamps. Subclasses III and IV comprised neurons which fired tonically (slow adapting), with the neurons in subclass III also showing relaxation of electronic potentials. Active and passive membrane properties were determined for neurons in each of the 4 subclasses of IMG cells. Measured values for the charging time-constant, the threshold current and the voltage threshold for firing (as well as calculated values for the input capacitance, specific membrane resistance, total surface area, cell diameter and cell space-constant) distinguished the neurons classed as phasic-firing from the neurons classed as tonic-firing. There were no statistical differences between the membrane properties of subclass I and II phasic neurons, or the membrane properties of subclass III and IV tonic neurons, to explain why the neurons in subclasses II and III showed a relaxation in electrotonic potentials during current-clamp. In the light of recent voltage-clamp data on the IMG cells the actions of time conductances for potassium ions are discussed to account for the variations in the electrotonic behavior of these IMG cells.

Persistent firing of splenic and renal nerves after acute decentralization but failure to produce ganglionic reflexes

Experiments were done to evaluate the contribution of peripheral neural circuits to generation of ongoing splenic and renal sympathetic discharge as well as to the reflex alteration of this discharge by chemical stimulation of receptors of intestinal afferent nerves. After decentralization of the celiac and superior mesenteric ganglia, low amplitude spikes with low discharge rates still were observed in both nerves. Stimulation of intestinal receptors with bradykinin or capsaicin did not alter this residual firing. Cholinergic blockade eliminated most of this discharge. The source of the residual firing and its contribution to basal discharge of splenic and renal nerves remains to be determined.

The immunohistochemical distribution of neuropeptide Y in lumbar pre- and paravertebral sympathetic ganglia of the guinea pig

Neuropeptide Y (NPY)- like immunoreactive nerve cell bodies and nerve fibres have been studied in normal and colchicine-treated ganglia of the caudal lumbar sympathetic chain (LSC) and the inferior mesenteric ganglion (IMG) of the guinea pig. The great majority of noradrenergic ganglion cells in the LSC (defined as containing tyrosine hydroxylase immunoreactivity), but less than 20% of those in the IMG, were NPY-positive. These proportions correspond well to the proportions of neurones that have been found to discharge phasically in electrophysiological experiments on the same ganglia. As noradrenergic terminals innervating blood vessels contain NPY, the data are consistent with the idea that phasic discharge is a characteristic of vasoconstrictor neurones.

Venous mechanoreceptor input to neurones in the inferior mesenteric ganglion of the guinea-pig

Intracellular recordings were made in vitro from neurones of guinea-pig inferior mesenteric ganglia (i.m.g.) attached to the mesenteric vasculature of the distal colon region. The inferior mesenteric vein was cannulated for distension. Non-evoked continuous excitatory post-synaptic potentials (e.p.s.p.s) and action potentials were recorded from 38% of neurones in the absence of the colon or any imposed perturbation. Continuous e.p.s.p.s were blocked by hexamethonium, tetrodotoxin and by transection of the lumbar colonic nerves. Distension of the inferior mesenteric vein altered the frequency of continuous activity in 23% of cells which exhibited continuous activity. Venous distension was associated with a depolarization in 31% of cells tested. The depolarization averaged 2.8 mV and in 89% of these was associated with an increase in membrane resistance. A further 14% of cells exhibited an increase in membrane resistance in the absence of depolarization. Venous distension increased the amplitude of fast e.p.s.p.s generated by stimulation of the lumbar splanchnic nerve or the intermesenteric nerve in 38% of cells tested. The results of this study demonstrate the existence of a mechanosensory pathway from the venous bed of the distal mesenteric region to the i.m.g. of the guinea-pig and suggest that distension may enhance neural transmission by increasing the excitability of ganglionic cells.

The effect of a transient outward current (IA) on synaptic potentials in sympathetic ganglion cells of the guinea-pig

The responses to stimulation of preganglionic fibres have been studied in sympathetic neurones in ganglia of the caudal lumbar sympathetic chain (l.s.c.) and in the distal lobes of inferior mesenteric ganglia (i.m.g.) isolated from guinea-pigs. Most l.s.c. neurones were classified as 'phasic' and i.m.g. neurones as 'tonic' (see Cassell, Clark & McLachlan, 1986). The types of preganglionic inputs received by l.s.c. and i.m.g. neurones differed: l.s.c. cells almost invariably received at least one suprathreshold ('strong') input, in addition to several subthreshold ones; i.m.g. neurones more commonly received only subthreshold inputs via the lumbar splanchnic nerves. Prolonged discharges were evoked in some i.m.g. cells by stimulation of lumbar splanchnic nerves at strengths just supramaximal for the conventional fast synaptic responses. These appeared to arise from repetitive discharges evoked in other neurones intrinsic to the i.m.g. The time constants of decay of subthreshold synaptic currents recorded under voltage clamp in l.s.c. neurones (4.9 +/- 0.2 ms) were significantly shorter on average than those recorded in tonic i.m.g. cells (7.1 +/- 0.3 ms), although the values of time constant for the two populations overlapped. In phasic neurones, excitatory synaptic potentials (e.s.p.s) evoked at resting membrane potential by stimulation of preganglionic axons decayed with the same exponential time course as an electrotonic potential. In tonic neurones, the time course of decay of the e.s.p. was briefer, but always followed an exponential with the same time constant as the cell input time constant over the final part of the response. If tonic neurones were hyperpolarized by the passage of current through the recording micro-electrode, the time course of decay of the e.s.p. was prolonged and became the same as that of the electrotonic potential. The shape of e.s.p.s in phasic and tonic neurons could be mimicked in a computer model of the neurones incorporating the different activation/inactivation characteristics of the A current (IA) (Cassell et al. 1986) for each neurone type. It is concluded that, in addition to the contribution of IA to the rhythmic firing properties of tonic sympathetic neurones, this current also markedly inhibits the effects of excitatory synaptic conductance changes in this type of ganglion cell.

Characteristics of phasic and tonic sympathetic ganglion cells of the guinea-pig

Intracellular recording techniques have been used to determine the electrophysiological properties of sympathetic neurones in ganglia of the caudal lumbar sympathetic chain (l.s.c.) and in the distal lobes of inferior mesenteric ganglia (i.m.g.) isolated from guinea-pigs. Passage of suprathreshold depolarizing current initiated transient bursts of action potentials in 97% of l.s.c. neurones, but only 13% of i.m.g. cells ('phasic' neurones). Most i.m.g. neurones fired continuously during prolonged depolarizing pulses ('tonic' neurones). Passive membrane properties varied; mean cell input resistance was similar between groups, but phasic neurones had smaller major input time constants on average than had tonic cells. Current-voltage relations determined under both current clamp and voltage clamp were linear around resting membrane potential (approximately 60 mV), where membrane conductance was lowest. Instantaneous and time-dependent rectification varied in the different neurone types. The current underlying the after-hyperpolarization following the action potential was significantly larger on average in tonic i.m.g. cells than in phasic neurones, although its time course (tau = 100 ms) was similar. Phasic neurones fired tonically when depolarized after adding the muscarinic agonist, bethanechol (10(-5) M to 10(-4) M), to the bathing solution. Bethanechol blocked a proportion of the maintained outward current (presumably the M-current, IM, Adams, Brown & Constanti, 1982) in phasic neurones; this current was small or absent in tonic neurones. Transient outward currents resembling the A-current (IA, Connor & Stevens, 1971 a) were evoked in tonic but not in phasic neurones by depolarization from resting membrane potential. IA could only be demonstrated in phasic neurones after a period of conditioning hyperpolarization. After a step depolarization to approximately --50 mV, IA reached peak amplitude at about 7 ms and then decayed with a time constant of about 25 ms in both neurone types. Activation characteristics of IA were similar for phasic and tonic neurones, but inactivation curves, although having the same shape, were shifted to more depolarized voltages in tonic neurones. That is, IA was largely inactivated at resting membrane potential in phasic, but not tonic neurones. It is concluded that the discharge patterns of the two populations of sympathetic neurones result from differences in the voltage-dependent potassium channels present in their membranes. The anatomical occurrence of the different cell types suggests that phasic neurones are vasoconstrictor and tonic neurones are involved with visceral motility.

On the anatomical organization of the lumbosacral sympathetic chain and the lumbar splanchnic nerves of the cat--Langley revisited

The anatomy of the sympathetic nervous pathways from the spinal cord to the lumbosacral spinal nerves and to the inferior mesenteric ganglion has been studied systematically in a series of 37 cats. Details of the arrangements of white and grey rami communicantes and the lumbar splanchnic nerves are summarized, and similarities and differences between individuals noted. The description largely follows that of Langley [13] but differs in many ways from those of Harris [6] and Pick [21]. An alternative nomenclature for the segmental ganglia of the paravertebral sympathetic chain is defined, and its rationale presented.

Patterns of innervation of neurones in the inferior mesenteric ganglion of the cat

The patterns of peripheral and central synaptic input to non-spontaneous, irregular discharging and regular discharging neurones in the inferior mesenteric ganglion of the cat were studied in vitro using intracellular recording techniques. All three types of neurones in rostral and caudal lobes received central synaptic input primarily from L3 and L4 spinal cord segments. Since irregular discharging neurones received synaptic input from intraganglionic regular discharging neurones, some of the central input to irregular discharging neurones may have been relayed through the regular discharging neurones. In the rostral lobes of the ganglion, more than 70% of the non-spontaneous and irregular discharging neurones tested received peripheral synaptic input from the lumbar colonic, intermesenteric and left and right hypogastric nerves. Most of the regular discharging neurones tested received synaptic input from the intermesenteric and lumbar colonic nerves; none of the regular discharging neurones received synaptic input from the hypogastric nerves. Some of the peripheral synaptic input from the lumbar colonic and intermesenteric nerves to irregular discharging neurones may have been relayed through the regular discharging neurones. Axons of non-spontaneous and irregular discharging neurones located in the rostral lobes travelled to the periphery exclusively in the lumbar colonic nerves. Antidromic responses were not observed in regular discharging neurones during stimulation of any of the major peripheral nerve trunks. This suggests these neurones were intraganglionic. In the caudal lobes, irregular discharging neurones received a similar pattern of peripheral synaptic input as did irregular discharging neurones located in the rostral lobes. The majority of irregular discharging neurones in the caudal lobes projected their axons to the periphery through the lumbar colonic nerves. Non-spontaneous neurones in the caudal lobes, in contrast to those located in the rostral lobes, received peripheral synaptic input primarily from the hypogastric nerves. Axons of the majority of non-spontaneous neurones located in the caudal lobes travelled to the periphery through hypogastric nerves. The results suggest that non-spontaneous neurones and irregular discharging neurones in the rostral lobes and the majority of irregular discharging neurones in the caudal lobes transact and integrate neural commands destined for abdominal viscera supplied by the lumbar colonic nerves. Non-spontaneous neurones in the caudal lobes transact and integrate neural commands destined for pelvic viscera supplied by the hypogastric nerves.