Characteristics of synaptic input to three classes of sympathetic neurone in the coeliac ganglion of the guinea-pig

Potassium channel mRNA expression in prevertebral and paravertebral sympathetic neurons

The expression of eighteen different voltage-activated potassium channel genes in rat sympathetic ganglia was quantitatively analysed using an RNase protection assay. Eleven alpha-subunit genes and two beta-subunit genes were expressed in sympathetic ganglia. The relative level of potassium channel mRNA expression was compared between the superior cervical ganglion (SCG) and two preverteabral sympathetic ganglia, the coeliac ganglion (CG) and the superior mesenteric ganglion (SMG). Four mRNAs were differentially expressed: Kv1.2, Kv1.4, Kv2.2 and Kv beta 1. Transcripts from all four genes were more abundant in the prevertebral ganglia. From comparisons with previous electrophysiological studies it was concluded that genes encoding the channels underlying the M-current and D2-current, which are both prominent in sympathetic neurons, have yet to be identified. It was also concluded that members of the Kv4 family are likely to underlie the low-threshold A-current in sympathetic neurons.

Chemical coding of neurons that project from different regions of intestine to the coeliac ganglion of the guinea pig

The chemical codings of neurons that project from the small intestine, caecum, proximal colon, distal colon and rectum to the coeliac ganglion of the guinea pig were investigated. The coeliac ganglion was injected with the retrogradely transported dye Fast Blue, and each of the regions was examined 6 days later in wholemounts that had been prepared for immunohistochemical localisation of pairs of antigens. In both the small and large intestines, all intestinofugal neurons were immunoreactive (IR) for choline acetyltransferase (ChAT). In each region of the large intestine, the largest population, representing 50-60% of retrogradely labelled neurons in each region, was immunoreactive for ChAT, bombesin (BN), calbindin (Calb) and nitric oxide synthase (NOS). Most intestinofugal neurons in the small intestine contain bombesin and VIP-IR along with ChAT-IR but none contain either Calb or NOS. Thus, nerve endings of enteric origin in the coeliac ganglion that contain NOS-IR or Calb-IR come from the large intestine and those with bombesin-IR but not NOS-IR are from the small intestine. The gastric wall was injected with Fast Blue in order to label noradrenergic (NA) neurons in the coeliac ganglion and to determine, by localisation of NOS and bombesin-IR, whether they receive inputs from the small and large intestine. Some NA neurons received inputs from the large intestine (and perhaps also from the small intestine) and some received inputs exclusively from the small intestine. Most NA neurons that received intestinofugal inputs had the chemical code NA/-; some were immunoreactive for somatostatin (NA/SOM neurons), but those with IR for neuropeptide Y (NA/NPY) rarely received intestinofugal inputs.

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.

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.

Membrane properties and synaptic potentials in rat sympathetic preganglionic neurons studied in horizontal spinal cord slices in vitro

Intracellular recordings were made from neurons in the intermediolateral column and adjacent white matter in horizontal slices of upper thoracic spinal cord from rats aged 21-28 days. Membrane properties were studied in the presence of picrotoxin (100 microM) to block ongoing inhibitory synaptic potentials. 37 neurons were identified as sympathetic preganglionic neurons (SPNs) by their electrical behaviour, anatomical location and/or morphology. SPNs had resting potentials of -57 +/- 2 mV and input resistances of 254 +/- 31 M omega (n = 14). Following a hyperpolarising voltage step, a transient outward current was activated which had a time constant of decay of approx. 400 ms. The inflection in the repolarising phase of the action potential and the following prolonged AHP were both abolished by Cd2+ (50 microM). The current underlying the AHP had two components with kinetic properties similar to the two calcium-activated potassium conductances, gKCa1, and gKCa2, characterized in other autonomic neurons. Noradrenaline (10-100 microM) caused a small depolarization and blocked the calcium component of the action potential suppressing the AHP. This revealed an afterdepolarization (ADP) with an underlying inward current with a decay time constant of approx. 150 ms. All effects of noradrenaline were blocked by phentolamine (10 microM). Graded stimulation of the lateral funiculus 0.5-1 mm rostral to the recording site evoked in all cells monosynaptic fast excitatory synaptic potentials (fEPSPs) which were graded in amplitude. fEPSPs decayed with a time constant identical to the cell input time constant and were reduced in amplitude by CNQX (10-20 microM). In 7 cells, higher stimulus voltages elicited slow EPSPs with a time to peak of 1.1 +/- 0.1 s and a half decay of 2.8 +/- 0.3 s (n = 7) which were not reduced by alpha-adrenoceptor antagonists. The AHP was not blocked when the action potential was initiated during the slow EPSP. We conclude that excitatory bulbospinal inputs to SPNs involve at least one fast transmitter which is likely to be glutamate and one slow transmitter which is not noradrenaline.

Subtypes of tachykinin receptors on tonic and phasic neurones in coeliac ganglion of the guinea-pig

1. Intracellular recording techniques were used to investigate the characteristics of tachykinin receptors and their subtypes in tonic and phasic neurones, which constituted two major neuronal populations in the coeliac ganglion of the guinea-pig. 2. In 95% of phasic neurones a long-lasting after-hyperpolarization (LAH), 5-8 s in duration and 10-20 mV in amplitude, was observed following action potentials evoked by passing a train of depolarizing current pulses into the neurones. In contrast, LAH was observed in only 4% of tonic neurones. 3. In most tonic neurones, substance P (SP), neurokinin A (NKA) and senktide induced depolarizations, whereas in phasic neurones they usually inhibited LAH but rarely induced depolarization. 4. Tonic and phasic neurones were further classified into three groups based on their responses (depolarization for tonic neurones and LAH inhibition for phasic neurones) to these tachykinin receptor agonists: (1) neurones responsive to SP, NKA and senktide (71-78%); (2) those responsive to senktide but not to SP and NKA (12-23%) and (3) those not responsive to any of the three agonists (7-11%). 5. GR71251 (5 microM), an NK1-selective tachykinin receptor antagonist, depressed the depolarization in tonic neurones and the LAH inhibition in phasic neurones induced by SP and NKA, but not those induced by senktide. 6. Selective NK2 receptor agonists, [Nle10]NKA4-10, [beta-Ala8]NKA4-10 and GR64349, were without effect in both tonic and phasic neurones. Furthermore, an NK2 receptor antagonist, L659,877, did not inhibit the depolarization induced by NKA, SP or senktide in tonic neurones. 7. It is suggested that NK1 and NK3 receptors are present on a large proportion of coeliac ganglion neurones. In tonic neurones both subtypes of tachykinin receptors are coupled to membrane depolarization,whereas in phasic neurones activation of these receptors leads to inhibition of LAH. The present study also suggests that NKA evokes the depolarization in tonic neurones and the LAH inhibition in phasic neurones via NK1, but not NK2 receptors.

Currents caused by the spontaneous release of quanta of acetylcholine onto chromaffin cells in guinea-pig adrenal medulla

Membrane potentials were recorded from chromaffin cells in isolated bisected adrenal glands from guinea-pigs. Spontaneous excitatory synaptic potentials (SESPs) were recorded whose frequency was increased following brief (up to 10 s) periods of presynaptic nerve stimulation at 10-30 Hz. The single electrode voltage-clamp method was used to record the currents underlying all but the largest SESPs. Spontaneous excitatory synaptic currents (SESCs) decayed according to a single exponential with a time constant of about 8 ms at 30 degrees C. Thus the neuronal nicotinic receptor-channels giving rise to SESCs in chromaffin cells are probably very similar to those that are opened by quanta of acetylcholine in sympathetic ganglion cells.

Effects of axotomy, deafferentation, and reinnervation on sympathetic ganglionic synapses: a comparative study

The main physiological and morphological features of the synapses in the superior cervical ganglia of mammals and the last two abdominal ganglia of the frog sympathetic chain are summarized. The effects of axotomy on structure and function of ganglionic synapses are then reviewed, as well as various changes in neuronal metabolism in mammals and in the frog, in which the parallel between electrophysiological and morphological data leads to the conclusion that a certain amount of synaptic transmission occurs at "simple contacts." The effects of deafferentation on synaptic transmission and ultrastructure in the mammalian ganglia are reviewed: most synapses disappear, but a number of postsynaptic thickenings remain unchanged. Moreover, intrinsic synapses persist after total deafferentation and their number is strongly increased if axotomy is added to deafferentation. In the frog ganglia, the physiological and morphological evolution of synaptic areas is comparable to that of mammals, but no intrinsic synapses are observed. The reinnervation of deafferented sympathetic ganglia by foreign nerves, motor or sensory, is reported in mammals, with different degrees of efficiency. In the frog, the reinnervation of sympathetic ganglia with somatic motor nerve fibers is obtained in only 20% of the operated animals. The possible reasons for the high specificity of ganglionic connections in the frog are discussed.

Properties of putative cardiac and non-cardiac neurones in the rat stellate ganglion

Intracellular recordings were made from isolated left or right stellate ganglia of Wistar rats and the morphology of neurones studied after intracellular injection of hexammine cobaltic chloride or back-filling from the post-ganglionic nerve with cobalt lysine complex. The experiments attempted to identify the location, electrophysiological properties, morphology and chemosensitivity of putative cardiac neurones in the ganglion. These were identified by antidromic activation of the axon in a cardiac nerve and compared with neurones projecting towards the brachial plexus (non-cardiac neurones). Putative cardiac neurones were localized in the ganglion around the postganglionic nerve entry zone and showed considerable morphological diversity. They had complex dendritic trees with, on average, seven dendrites. They included both phasic and tonic neurones and were depolarized by muscarinic agonists, angiotensin and substance P; they invariably had a synaptic input from the sympathetic trunk and from a T1 or T2 ramus and, in 16% of cells, from a cardiac nerve. Non-cardiac neurones were more widely scattered through the stellate ganglion but were not clearly different in morphology, resting membrane potential or the proportion of phasic and tonic cells from putative cardiac neurones. They also showed depolarizing responses to muscarinic agonists, angiotensin and substance P. Angiotensin responses of stellate ganglion cells were blocked by the peptide antagonist, saralasin (1 microM).

Expression of the trk gene family of neurotrophin receptors in prevertebral sympathetic ganglia

When the phenotype of neurons in pre- and paravertebral sympathetic ganglia are compared, there are marked differences in NGF dependence, neuropeptide content, connectivity and electrophysiological properties. The trophic interactions that induce these differences are currently poorly understood. One explanation is that prevertebral neurons receive a second neurotrophic signal, other than NGF, from their target of innervation. If this is the case, neurons in the prevertebral ganglia should express another neurotrophin receptor, in addition to the NGF receptor (trkA). To test this prediction, the level of expression of three neurotrophin receptors, trkA, trkB and trkC, were examined in one paravertebral sympathetic ganglia, the SCG, and two prevertebral ganglia, the celiac and superior mesenteric ganglia. It was found that mRNA encoding the full-length form of the trkB receptor was barely expressed in the SCG. Significantly higher levels of full-length trkB mRNA expression were found in the prevertebral ganglia. Ligands of the trkB receptor may, therefore, contribute to the differentiation and/or survival of some prevertebral sympathetic neurons.

Electrophysiological analysis of the convergence of peripheral inputs onto neurons of the coeliac ganglion in the guinea pig

The convergence of intestinofugal axons from different intestinal regions onto individual neurons in the coeliac ganglion of the guinea pig was investigated using intracellular recording methods in vitro. Peripheral nerve trunks from the distal ileum, the most proximal colon and the colon near the colonic flexure were electrically stimulated along with preganglionic fibres running in the splanchnic nerve. Fast cholinergic excitatory synaptic potentials (EPSPs) were seen in ganglion cells in response to stimulation of each nerve trunk. Roughly half of 78 neurons impaled received inputs from stimulation of peripheral nerves, and almost all of these received input from the proximal colon. Most cells responded to stimulation of more than one peripheral nerve indicating that coeliac neurons receive converging inputs from intestinofugal neurons located in more than one intestinal region. In a second series of experiments, segments of intestine were left attached to the ganglion and distended with saline to stimulate peripheral mechanosensory input to the coeliac ganglion. In each experiment, two segments were stimulated. A subgroup of ganglion cells exhibited spontaneous fast EPSPs and the frequency of these potentials was increased by distension of one or other of the attached intestinal segments. However, few neurons responded to distension of both of the attached intestinal segments suggesting that some of the intestinofugal inputs to the coeliac ganglion identified by electrical stimulation may be sensitive to sensory modalities other than distension. Hexamethonium (0.5 mM) applied to the intestine, and not to the coeliac ganglion, reduced the frequency of the spontaneous synaptic potentials seen in coeliac ganglion cells, but did not abolish the response to distension of the colon (n = 8). When the Ca2+ concentration of the solution bathing the proximal colon was reduced to block all synaptic transmission in the enteric plexuses the background synaptic input was further depressed, but again the response to distension was little changed (n = 4). This suggests that at least some of the neurons projecting from the colon to the coeliac ganglion are first order mechanosensory neurons.

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.

On the excitatory effects of ATP and its role as a neurotransmitter in coeliac neurons of the guinea-pig

1. The effects of ATP on neurons from guinea-pig coeliac ganglia were studied to evaluate the possibility that this nucleotide acts as an excitatory neurotransmitter substance. 2. In experiments with intracellular microelectrodes, ATP (> or = 10 nM) depolarized coeliac neurons from the resting potential and produced an increase in the membrane conductance. These excitatory effects of ATP were observed in isolated coeliac ganglia, in acutely dissociated neurons or in cultured neurons. ATP also produced membrane conductance increases in neurons clamped at the resting potential using a single electrode voltage clamp. 3. When studied in the whole-cell configuration of the patch clamp (intracellular Cs+ to block K+ currents; -50 mV holding potential), ATP evoked inward currents in a manner more potent and efficacious than acetylcholine (ACh). 4. Whole-cell currents induced by ATP were inwardly rectifying and reversed at -13 mV in normal Na+ solutions. Changes in extracellular Na+ concentration altered the reversal potential in a manner predicted by the Goldman-Hodgkin-Katz bi-ionic equation with a ratio of Na+ to Cs+ permeability (PNa/PCs) = 0.6. 5. Single channel currents were evoked by ATP in excised (outside-out) patches. Current-voltage relationships for single channel currents exhibited inward rectification. The mean single channel conductance was 22 pS at -50 mV. 6. Antagonists of ATP-gated channels (suramin, Reactive Blue 2) reduced the effects of ATP but not ACh. 7. Antagonists at nicotinic receptors/ion channels (hexamethonium or tubocurarine) reduced the effects of ACh but not ATP. 8. Excitatory synaptic currents were observed in cultures of coeliac neurons. Synaptic currents possessed similar current-voltage relationships to currents produced by ATP, were increased in frequency by K+ depolarization in a Ca(2+)-dependent manner, and were selectively antagonized by ATP antagonists. 9. Local K+ depolarization of the ends of neurites evoked single channel currents characteristic of ATP in outside-out patches when patches were positioned near the region of apparent synaptic contact but not when patches were positioned at remote regions. 10. The results suggest that ATP receptors are linked to ion channels and mediate excitatory synaptic transmission between coeliac neurons.

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)

Characteristics of function-specific pathways in the sympathetic nervous system

The autonomic nervous system enables all of our body systems to operate in an external environment that is both physically and emotionally challenging. Despite voluntary and involuntary interventions, the composition of the internal environment is maintained. Autonomic dysfunction, particularly in aging people, reveals the importance of this efferent neural control for the wellbeing of our bodies and minds. Although the sympathetic component of this system has been widely thought to be concerned only with the body's response to stress, we discuss here how a range of neuroscientific techniques has started to reveal the specialized properties of functional pathways in the sympathetic system at molecular, cellular and integrative levels. The diversity observed is not compatible with a simple neuroendocrine role of this system.

Specialized functional pathways are the building blocks of the autonomic nervous system

The autonomic nervous system supplies each type of target organ via separate pathways which consist of sets of pre- and postganglionic neurones with distinct patterns of reflex activity. This has been firmly established for the lumbar sympathetic nervous system to skin, skeletal muscle and viscera, for the thoracic sympathetic outflow to the head and for several parasympathetic systems. In principle, that was already known by Langley. The specificity of the messages that these pathways transmit from the central nervous system arises from integration within precisely organized pathways in the neuraxis. The messages travel along discrete functional pathways and are transmitted to the target tissues via close neuroeffector junctions. Integration in the periphery occurs within each pathway, both in ganglia and at the level of the effector organs. We still need to understand how the central messages get through without distortion and how they control the diverse functions of the vasculature and viscera.

ATP mediates excitatory synaptic transmission in mammalian neurones

Adenosine 5'-triphosphate (ATP, 0.1-100 microM), produced inward currents in patch-clamped coeliac neurones from guinea-pig when studied in either the whole cell configuration or in excised (outside-out) patches. The P2-purinoceptor antagonists suramin (80-230 microM) or reactive blue 2 (2-20 microM) depressed the ATP-induced currents but not those produced by acetylcholine. Excitatory post-synaptic currents (e.p.s.cs) were observed in cultured neurones. E.p.s.cs had similar current-voltage relationships to currents evoked by ATP in excised patches and were reduced by suramin or reactive blue 2 to a similar extent as ATP currents. The results suggest that ATP is the excitatory neurotransmitter in cultures of these neurones.

Electrophysiological properties of in vitro intrinsic cardiac neurons in the pig (Sus scrofa)

Physiological properties and synaptically mediated responses of 34 ganglionated plexus neurons from the right atrium of the pig heart were studied with in vitro intracellular recording techniques. Whole-cell input resistance of these neurons was lower, time constant was shorter, and threshold for directly evoked action potentials was higher than the same properties in extracardiac autonomic neurons. Long intracellular depolarizing current pulses (400-500 ms) failed to generate more than one or two action potentials. Nicotinic and non-nicotinic synapses were present on neurons in cardiac ganglia and neuronal properties could be modified by norepinephrine. Based on their physiological properties, cardiac ganglionated plexus neurons in the pig appear to represent a distinct population of autonomic neurons that may be capable of intracardiac integration of efferent information to the heart.

The cytosolic calcium transient modulates the action potential of rat ventricular myocytes

1. The modulation of the action potential by the cytosolic Ca2+ (Cai2+) transient was studied in single isolated rat ventricular myocytes loaded with the acetoxymethyl ester form of the Ca(2+)-sensitive fluorescent dye Indo-1. Stimulation following rest and exposure to ryanodine were used to change the amount of Ca2+ released from the sarcoplasmic reticulum and thus the size of the Cai2+ transient. The Cai2+ transient was measured as the change, upon stimulation, in the ratio of Indo-1 fluorescence at 410 nm to that at 490 nm (410/490) and action potentials or membrane currents were recorded using patch-type microelectrodes. 2. When stimulation was initiated following rest, the magnitude of the Cai2+ transient decreased in a beat-dependent manner until a steady state was reached. The negative staircase in the Cai2+ transient was accompanied by a similar beat-dependent decrease in the duration of the action potential, manifested primarily as a gradual loss of the action potential plateau (approximately -45 mV). A slow terminal phase of repolarization of a few millivolts in amplitude was found to parallel the terminal decay of the Cai2+ transient. 3. The terminal portion of phase-plane loops of membrane potential (Vm) vs. Indo-1 ratio from all of the beats of a stimulus train followed a common linear trajectory even though the individual beats differed markedly in the duration and amplitude of the action potential and Cai2+ transient. 4. When the stimulation dependence of the Cai2+ transient was titrated away with submaximal exposure to ryanodine, the stimulation-dependent changes in the action potential plateau and terminal phase of repolarization were also eliminated. The same effect was noted in cells which, fortuitously, did not show a staircase in the Cai2+ transient following a period of rest. 5. When action potentials were triggered immediately following spontaneous release of Ca2+ from the sarcoplasmic reticulum, which results in a small depolarization at the resting potential, phase-plane loops (Vm vs. Indo-1 ratio) of the spontaneous events followed the same linear trajectory as the terminal phase of repolarization in the loops of the stimulated beats. 6. Following repolarization from brief voltage clamp pulses (to minimize time and voltage-dependent currents associated with depolarization), an inward current was observed that rose and fell in phase with the Cai2+ transient. This current was present at -70 mV, near the resting potential, and at -40 mV, a potential relevant to the plateau of the action potential.(ABSTRACT TRUNCATED AT 400 WORDS)