Visual identification of two kinds of nerve cells and their synaptic contacts in a living autonomic ganglion of the mudpuppy (Necturus maculosus)

Identification of glucocorticoid receptors as potential modulators of parasympathetic and sympathetic neurons within rat intracardiac ganglia

Background

Emerging evidences indicate that glucocorticoid receptors (GR) play a regulatory role in cardiac function, particularly with regard to the autonomic nervous system. Therefore, this study aimed to demonstrate the expression and the precise anatomical location of GR in relation to the parasympathetic and sympathetic innervations of the heart.

Methods

The present study used tissue samples from rat heart atria to perform conventional reverse-transcriptase polymerase chain reaction (RT-PCR), Western blot, and double immunofluorescence confocal analysis of GR with the neuronal markers vesicular acetylcholine transporter (VAChT), tyrosine hydroxylase (TH), calcitonin gene-related peptide (CGRP) as well as the mineralocorticoid receptor (MR).

Results

Double immunofluorescence labeling revealed that GRs were co-expressed with VAChT in parasympathetic principal neuronal somata and nerve terminals innervating atrium. Also, GR colocalized with the sympathetic neuronal marker TH in a cluster of small intensely fluorescent (SIF) cells, on intracardiac nerve terminals and in the atrial myocardium. GR immunoreactivity was scarcely identified on CGRP-immunoreactive sensory nerve terminals. Approximately 20% of GR immunoreactive neuronal somata co-localized with MR. Finally, conventional RT-PCR and Western blot confirmed the presence of GR and MR in rat heart atria.

Conclusion

This study provides evidence for the existence of GR predominantly on cardiac parasympathetic neurons and TH-immunoreactive SIF cells suggesting a functional role of cardiac GR on cardiovascular function by modulation of the cardiac autonomic nervous system.

Functional anatomy of the vagus system: How does the polyvagal theory comply?

Due to its pivotal role in autonomic networks and interoception, the vagus attracts continued interest from both basic scientists and therapists of various clinical disciplines. In particular, the widespread use of heart rate variability as an index of autonomic cardiac control and a proposed central role of the vagus in biopsychological concepts, e.g., the polyvagal theory, provide a good opportunity to recall basic features of vagal anatomy. In addition to the "classical" vagal brainstem nuclei, i.e., dorsal motor nucleus, nucleus ambiguus and nucleus tractus solitarii, the spinal trigeminal and paratrigeminal nuclei come into play as targets of vagal afferents. On the other hand, the nucleus of the solitary tract receives and integrates not only visceral but also somatic afferents.

Identification of Mineralocorticoid Receptors, Aldosterone, and Its Processing Enzyme CYP11B2 on Parasympathetic and Sympathetic Neurons in Rat Intracardiac Ganglia

Recent interest has focused on the mineralocorticoid receptor (MR) and its impact on the myocardium and the performance of the heart. However, there is a lack of evidence about MR expression and its endogenous ligand aldosterone synthesis with specific regard to the intrinsic cardiac nervous system. Therefore, we looked for evidence of MR and aldosterone in sympathetic and parasympathetic neurons of intracardiac ganglia. Tissue samples from rat heart atria were subjected to conventional reverse-transcriptase polymerase chain reaction (PCR), Western blot, and double immunofluorescence confocal analysis of MR, corticosterone-inactivating enzyme 11β-hydroxysteroid-dehydrogenase-2 (11β-HSD2), aldosterone, and its processing enzyme CYP11B2 together with the neuronal markers vesicular acetylcholine transporter (VAChT) and tyrosine hydroxylase (TH). Our results demonstrated MR, 11β-HSD2, and CYP11B2 specific mRNA and protein bands in rat heart atria. Double immunofluorescence labeling revealed coexpression of MR immunoreactivity with VAChT in large diameter parasympathetic principal neurons. In addition, MR immunoreactivity was identified in TH-immunoreactive small intensely fluorescent (SIF) cells and in nearby VAChT- and TH-immunoreactive nerve terminals. Interestingly, the aldosterone and its synthesizing enzyme CYP11B2 and 11β-HSD2 colocalized in MR– immunoreactive neurons of intracardiac ganglia. Overall, this study provides first evidence for the existence of not only local expression of MR, but also of 11β-HSD2 and aldosterone with its processing enzyme CYP11B2 in the neurons of the cardiac autonomic nervous system, suggesting a possible modulatory role of the mineralocorticoid system on the endogenous neuronal activity on heart performance.

Developmental expression of δ-opioid receptors during maturation of the parasympathetic, sympathetic, and sensory innervations of the neonatal heart: early targets for opioid regulation of autonomic control

Evidence is accumulating regarding the local opioid regulation of heart function. However, the exact anatomical location of δ-opioid receptors (DORs) and expression during maturation of the autonomic and sensory innervations of the neonatal heart is unknown. Therefore, we aimed to characterize target sites for opioids in neonatal rat heart intracardiac ganglia at postnatal day (P)1, P7 and adulthood (P56-P84). Rat heart atria were subjected to reverse-transcriptase polymerase chain reaction, Western blot, radioligand binding, and immunofluorescence confocal analysis of DORs with the neuronal markers vesicular acetylcholine transporter (VAChT), tyrosine hydroxylase (TH), calcitonin gene-related peptide (CGRP), and substance P (SP). Our results demonstrated DOR mRNA, protein, and binding sites that gradually increased from P1 toward adulthood. Immunofluorescence confocal microscopy showed DOR co-localized with VAChT in large-diameter principal neurons, TH-immunoreactive (IR) small intensely fluorescent (SIF) catecholaminergic cells, and CGRP- or SP-IR afferent nerve terminals arborizing within intracardiac ganglia and atrial myocardium. Co-expression of DOR with VAChT-IR neurons was observed from the first day of birth (P1). In contrast, DORs on TH-IR SIF cells or CGRP-IR fibers were not observed in intracardiac ganglia of P1, but rather in P7 rats. The density of nerve fibers in atrial myocardium co-expressing DORs with different neuronal markers increased from neonatal age toward adulthood. In summary, the enhanced DOR expression parallel to the maturation of cardiac parasympathetic, sympathetic, and sensory innervation of the heart suggests that the cardiac opioid system is an important regulator of neonatal and adult heart function through the autonomic nervous system.

Identification of mu- and kappa-opioid receptors as potential targets to regulate parasympathetic, sympathetic, and sensory neurons within rat intracardiac ganglia

Recent interest has been focused on the opioid regulation of heart performance; however, specific allocation of opioid receptors to the parasympathetic, sympathetic, and sensory innervations of the heart is scarce. Therefore, the present study aimed to characterize such specific target sites for opioids in intracardiac ganglia, which act as a complex network for the integration of the heart's neuronal in- and output. Tissue samples from rat heart atria were subjected to RT-PCR, Western blot, radioligand-binding, and double immunofluorescence confocal analysis of mu (M)- and kappa (K)-opioid receptors (ORs) with the neuronal markers vesicular acetylcholine transporter (VAChT), tyrosine hydroxylase (TH), calcitonin gene-related peptide (CGRP), and substance P (SP). Our results demonstrated MOR- and KOR-specific mRNA, receptor protein, and selective membrane ligand binding. By using immunofluorescence confocal microscopy, MOR and KOR immunoreactivity were colocalized with VAChT in large-diameter parasympathetic principal neurons, with TH-immunoreactive small intensely fluorescent (SIF) cells, and on nearby TH-IR varicose terminals. In addition, MOR and KOR immunoreactivity were identified on CGRP- and SP-IR sensory neurons throughout intracardiac ganglia and atrial myocardium. Our findings show that MOR and KOR are expressed as mRNA and translated into specific receptor proteins on cardiac parasympathetic, sympathetic, and sensory neurons as potential binding sites for opioids. Thus, they may well play a role within the complex network for the integration of the heart's neuronal in- and output.

Structure of peripheral synapses: autonomic ganglia

Final motor neurons in sympathetic and parasympathetic ganglia receive synaptic inputs from preganglionic neurons. Quantitative ultrastructural analyses have shown that the spatial distribution of these synapses is mostly sparse and random. Typically, only about 1%-2% of the neuronal surface is covered with synapses, with the rest of the neuronal surface being closely enclosed by Schwann cell processes. The number of synaptic inputs is correlated with the dendritic complexity of the target neuron, and the total number of synaptic contacts is related to the surface area of the post-synaptic neuron. Overall, most neurons receive fewer than 150 synaptic contacts, with individual preganglionic inputs providing between 10 and 50 synaptic contacts. This variation is probably one determinant of synaptic strength in autonomic ganglia. Many neurons in prevertebral sympathetic ganglia receive additional convergent synaptic inputs from intestinofugal neurons located in the enteric plexuses. The neurons support these additional inputs via larger dendritic arborisations together with a higher overall synaptic density. There is considerable neurochemical heterogeneity in presynaptic boutons. Some synapses apparently lack most of the proteins normally required for fast transmitter release and probably do not take part in conventional ganglionic transmission. Furthermore, most preganglionic boutons in the ganglionic neuropil do not form direct synaptic contacts with any neurons. Nevertheless, these boutons may well contribute to slow transmission processes that need not require conventional synaptic structures.

Catecholamines are present in larval Xenopus laevis: a potential source for cardiac control

Changes in noradrenaline (NA), adrenaline (A), and dopamine (DA) levels in the heart, kidneys, and whole body (without heart and kidneys) during embryonic development were investigated in the frog, Xenopus laevis using high-performance liquid chromatography (HPLC). In addition, the presence of cells immunoreactive to tyrosine hydroxylase (TH), dopamine-beta-hydroxylase (DBH) and/or phenylethanolamine-N-methyltransferase (PNMT) in the heart of Xenopus larvae was investigated using immunohistochemical techniques. The presence of nerve fibers was visualized using antibodies against acetylated tubulin (AcT). NA and DA concentrations in the heart were low and steady in NF 40-56, showed an increased value at NF 57, and decreased again in froglets. A trend toward higher concentrations of A was observed at NF 43-49 and NF 57. Cells immunoreactive to TH, DBH, and PNMT were found in the heart from NF 40, and the TH immunoreactive cells became more abundant in the whole heart at later stages. The presence of catecholamines in the non-innervated larval heart together with the finding of TH/DBH/PNMT immunoreactive cells suggests that catecholamines are synthesized and stored in the heart and could therefore have a paracrine role in cardiac control in Xenopus larvae. Detectable concentrations of catecholamines were also found in kidneys and whole bodies (except heart and kidneys). Therefore, catecholamine-producing cells outside the heart can be an important source of circulating catecholamines involved in adrenergic cardiac control in Xenopus larvae.

Pituitary adenylate cyclase-activating polypeptide innervation of the mudpuppy cardiac ganglion

The presence and potential origin of the neuropeptide pituitary adenylate cyclase-activating polypeptide (PACAP) was determined in cardiac ganglia of the mudpuppy, Necturus maculosus. Although PACAP has been implicated in the regulation of cardiac function in several mammalian species, the presence of this peptide in the autonomic nervous system (ANS) of other species is unclear. Thus, this study is the first to characterize this highly conserved peptide in the ANS of a non-mammalian species. PACAP-immunoreactivity was observed in nerve fibers throughout the mudpuppy cardiac ganglia and often was co-localized with the sensory neuropeptides substance P and calcitonin gene-related peptide. Removal of all extrinsic inputs to the ganglia by organ culture eliminated PACAP-immunoreactivity in the cardiac ganglia, whereas bilateral vagotomies only partially reduced PACAP-labeling. PACAP-immunoreactive neurons were observed in both high thoracic dorsal root ganglia and in vagal sensory ganglia. While no PACAP-positive neurons were observed in caudal medulla brainstem regions, PACAP-containing nerve fibers were found in the region of the nucleus solitarius. These results suggest that, in the mudpuppy, PACAP is found primarily in visceral afferent fibers, originating from cells in either the dorsal root ganglia or vagal sensory ganglia. Based on their anatomic localization, these afferent fibers may function to transmit important sensory information to cardiovascular centers in the brain as well as serving as local reflex inputs to modulate postganglionic parasympathetic output within the cardiac ganglion itself.

Vagal afferent innervation of the atria of the rat heart reconstructed with confocal microscopy

We have used confocal microscopy to analyze the vagal afferent innervation of the rat heart. Afferents were labeled by injecting 1,1'-dioleyl-3,3,3',3'-tetramethylindocarbocyanine methanesulfonate (DiI) into the nodose ganglia of animals with prior supranodose de-efferentations, autonomic ganglia were stained with Fluoro-gold, and tissues were examined in whole mounts. Distinctively different fiber specializations were observed in the epi-, myo-, and endocardium: Afferents to the epicardium formed complexes associated with cardiac ganglia. These ganglia consisted of four major ganglionated plexuses, two on each atrium, at junctions of the major vessels with the atria. Ganglionic locations and sizes (left > right) were consistent across animals. In addition to principal neurons (PNs), significant numbers of small intensely fluorescent (SIF) cells were located in each of these plexuses, and vagal afferents provided dense pericellular varicose endings around the SIF cells in each ganglionic plexus, with few if any terminations on PNs. In the myocardium, vagal afferents formed close contacts with cardiac muscles, including conduction fibers. In the endocardium, vagal fibers formed "flower-spray" and "end-net" terminals in connective tissue. With three-dimensional reconstruction of confocal optical sections, a novel polymorphism was seen: Some fibers had one or more collaterals ending as endocardial flower sprays and other collaterals ending as myocardial intramuscular endings. Some unipolar or pseudounipolar neurons within each cardiac ganglionic plexus were retrogradely labeled from the nodose ganglia. In conclusion, vagal afferents form a heterogeneity of differentiated endings in the heart, including structured elements which may mediate chemoreceptor function, stretch reception, and local cardiac reflexes.

Synaptic organization of amphibian sympathetic ganglia

The synaptic organization of the amphibian sympathetic ganglia was studied, especially in the last two abdominal paravertebral ganglia of the frog. These ganglia appear to form a monosynaptic relay, not containing interneurons. They consist of two systems working in parallel: the principal neurons, by far the most numerous, and a small number of chromaffin (i.e., SIF) cells, usually arranged in clusters. Each principal neuron is innervated by a preganglionic branch forming a set of cholinergic synapses which exhibit classical ultrastructure. The only peculiarity is the presence of a subsynaptic apparatus in a variable percentage of synaptic complexes. Electrophysiological studies have demonstrated that synaptic transmission is due to ACh release and involves several postsynaptic potentials. Moreover, the principal neurons are of two types, B and C, whose preganglionic axons and their own axons have different conduction velocities. C neurons tend to be small in diameter, and B neurons are larger, but the size distribution of the two populations overlaps. More recently, it was demonstrated that these two neuronal systems have different immunocytochemical features. The C preganglionic fibers contain an LHRH-like peptide, which is responsible for late synaptic events. The B preganglionic fibers contain CGRP, whose role has not yet been established. The principal neurons all contain adrenaline, but neuropeptide Y is also present in C neurons and could be a second transmitter at peripheral junctions. SP-containing fibers also pass through the ganglia, but give rise to intraganglionic synapses only rarely, except in the celiac plexus. Galanin can coexist with neuropeptide Y in certain C neurons. Numerous principal neurons are immunoreactive for VIP. Chromaffin cells contain noradrenaline and metenkephalin, and some contain SP or LHRH; they are endocrine cells controlled by preganglionic fibers and can have a modulatory effect on principal neurons endowed with appropriate receptors. The accessibility of frog abdominal ganglia and the anatomical separation of B and C preganglionic fiber pathways provide interesting systems in which to carry out experimentation on the stability and specificity of synaptic contacts. After postganglionic axotomy, the majority of synapses disappear by disruption of synaptic contacts. There is a certain discrepancy between the recovery of synaptic transmission and the reappearance of morphologically identifiable synapses, suggesting that a certain amount of transmission is possible at contacts devoid of synaptic complexes. The selective deafferentation of B or C neurons showed that the subsynaptic apparati are mainly found at B neuron synapses. The course of reinnervation following selective deafferentation reveals the existence of different specificities at B and C synapses: C neurons are easily reinnervated by B preganglionic fibers, whereas C fibers appear fairly ineffective at reinnervating B neurons, even after a long interval. Attempts were made to reinnervate ganglionic neurons with somatic motor nerve fibers. Reinnervation was achieved only rarely, and it is concluded that the ganglionic synapses in the frog have a higher specificity and lower plasticity than in mammals.

Arachidonic acid may mediate the galanin-induced hyperpolarization in parasympathetic neurons from Necturus maculosus

The effects of arachidonic acid (AA) and compounds that inhibit intracellular signalling pathways on membrane potential and galanin-induced hyperpolarizations were investigated in parasympathetic neurons from Necturus maculosus. Treatment for 10-90 min with 10-20 microM 4-bromophenacylbromide or 10 microM cyclosporin A caused a progressive decrease in the amplitude of galanin-induced hyperpolarizations without any change in resting membrane potential. The galanin-induced hyperpolarization was not altered following a 10-120 min treatment with the protein kinase inhibitor H-7. These results indicated that phospholipase A2 activation, but not protein kinase activation, may be required for the galanin-induced hyperpolarization. Arachidonic acid (20-100 microM) caused a concentration-dependent membrane hyperpolarization of the parasympathetic neurons and a decrease in the amplitude of the galanin-induced hyperpolarization. These data indicate that phospholipase A2-catalyzed liberation of AA may be involved in the galanin-induced membrane hyperpolarization observed in mudpuppy parasympathetic neurons.

Immunocytochemical localisation of substance P in vagal ganglion cells and pericellular arborisations in the monkey

The quantitative cell count showed the presence of about 20,000 ganglion cells with associated satellite elements in the nodose ganglion in the monkey. Among these closely packed cells, at least one-third were substance P (SP) immunoreactive, ranging from faint or moderate to intense staining. Substance P immunoreactivity (SP-IR) was localised in the cell bodies and their long extending neurites. Ultrastructural study showed that SP-IR was not associated with any particular organelles or inclusions. A striking feature of the nodose ganglion was the occurrence of SP-positive pericellular arborisations associated with about 0.5% of the ganglion cells which were almost exclusively SP-negative. The pericellular arborisation displayed diverse morphological forms from a simple tortuous fibre to complex glomerular networks or plexuses encircling the soma of SP-negative ganglion cells. The varicose nerve fibres forming the pericellular arborisations appeared to terminate as 'boutons' contacting the soma of the ganglion cells. Electron microscopic study demonstrated the close spatial relation between the SP-IR profiles and the ganglion cell but there was no direct synaptic contact. In some instances, the SP-IR profiles containing agranular and dense-cored vesicles penetrated the cytoplasm of satellite cells, almost reaching the surface of the soma of the ganglion cell. The sources of origin of the nerve plexuses in the pericellular arborisation were either from the small and sparsely distributed jugular ganglion cells which were intensely SP-IR or from the intrinsic SP-IR nodose ganglion cells. The possibility that the efferent neurons in the dorsal motor nucleus of the vagus could also contribute to the pericellular arborisation was also considered. The function of the pericellular arborisations may be related to the modulation of the SP-deficient ganglion cells with which they associate through the release of SP and probably by way of the satellite cells.

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.

Histochemical study of the heart of the axolotl (Ambystoma mexicanum)

We have investigated the presence of cells containing monoamines, substance P, and neuron-specific enolase (NSE) in the heart and in the pericardial wall of a urodele amphibian, the axolotl. Fibers containing substance P-like immunoreactivity were present in the heart but not in the pericardial wall. Also present in the heart were small branched cells, which stained metachromatically with toluidine blue. Similar cells were found in the peritoneum and were tentatively identified as mast cells. NSE-immunoreactive fibers were found both in the heart and in the pericardial wall. Small intensely fluorescent (SIF) cells of the pericardial wall contained a high concentration of norepinephrine but no other monoamines, substance P, or NSE. Comparison with data available for the mudpuppy, Necturus maculosus, a closely related amphibian species, suggests that the innervation of the heart in the axolotl is substantially different.

Morphology of intracellularly labeled canine intracardiac ganglion cells

The purpose of this study was to determine the morphological organization and structure-function correlation of mammalian intracardiac ganglion cells. Conventional intracellular microelectrode techniques were applied to the tissue whole mount preparation of canine intracardiac ganglia. Forty neurons were intracellularly recorded and labeled by means of horseradish peroxidase iontophoresis. Cell morphology was quantitatively analyzed by light microscopy and camera lucida technique. Somata were elongated (mean 62 x 40 microns) and had 2-12 primary dendrites restricted within the ganglion. Almost half of the neurons had either a short axon that was traced only within the ganglion or no axon distinguishable. These neurons may have perhaps been intraganglionically active neurons. The other cells had a long axon that either coursed out of the ganglion to peripheral cardiac tissue or exited the ganglion via interganglionic nerve to innervate more remote cardiac tissue or cells in other intracardiac ganglia. Interaction between neurons was suggested by the close proximity of processes from different neurons. Previously defined electrophysiological cell types (R-, S-, and N-cells), which were significantly different in their passive and active membrane properties, had different morphological features of the somata but not the axonal or dendritic processes. Intraganglionic or long axon neurons were not associated with a particular electrophysiological cell type. These findings provide the possibility of ganglionic modulation of vagal efferent activity in mammalian heart and also provide some morphological basis for the electrophysiological cell types.

Biogenic amine localization in cardiac ganglion intrinsic neurons: electron microscopic histochemistry of SIF cells

The parasympathetic cardiac ganglion in the mudpuppy, N. maculosus, contains postganglionic nerve cells and intrinsic neurons, many of which are small intensely fluorescent (SIF) cells. Several bioactive substances have been localized in the intrinsic nerve cells which may have integrative effects at synapses within the ganglion. Ganglionic intrinsic neurons can be identified electron microscopically by the presence of numerous cytoplasmic granular vesicles 80-120 nm in diameter. Throughout the ganglion there are bundles of unmyelinated fibers some of which are filled with granular and agranular vesicles and axosomatic terminals with similar vesicles synapsing on principal parasympathetic nerve cells. To understand the aminergic contribution to ganglionic synaptic circuitry the chromaffin reaction was used. The intrinsic neurons (i.e., SIF cells) were readily identified by their characteristic intracellular granule population. All intrinsic nerve cells identified showed granules which were positively labelled by the chromaffin reaction. Granular vesicles in synaptic profiles on principal cells (P cells) were also labelled indicating a direct aminergic synaptic innervation to these cells. The cell bodies of intrinsic neurons, ensheathed with supportive glial-like cellular processes, rarely received synapses. Elemental microanalysis was used to verify the chromium content of the electron dense product within the granular vesicles. These studies demonstrated direct aminergic synaptic input to at least a subpopulation of principal parasympathetic cells in the cardiac ganglion of mudpuppy.

Morphogenesis of adrenergic cells in a frog parasympathetic ganglion

The development of the parasympathetic cardiac ganglion of the frog Xenopus laevis was marked by the differentiation of a population of adrenergic small intensely fluorescent (SIF) cells. The neural crest contributes precursors for both SIF cells and the well-studied cholinergic cardiac ganglion neurons; this situation provided an opportunity to determine whether morphogenesis of the two cell types was correlated. Accordingly, we examined the initial differentiation, developmental regulation, and territorial domain of cardiac SIF cells for comparison with their cholinergic neuron neighbors. Adrenergic SIF cells were present during the time when the first cholinergic precursors were becoming postmitotic. Although SIF cells were present first, cholinergic neurons differentiated almost 16 times faster during the first week of embryonic and larval development and outnumbered SIF cells at all subsequent stages. Nonetheless, the accumulation of both cell types were correlated, since the ratio of cholinergic neurons to SIF cells remained at approximately 10 to 1 up to adult life. Early in development, SIF cells and cholinergic neurons were clustered in the sinus venosus portion of the atrium. The asymmetric distribution of cholinergic neurons within the atrium was lost but that of the SIF cells was maintained throughout life. These results identify relationships between the morphogenesis of two cell types in an autonomic ganglion and place constraints upon the cellular mechanisms that could produce the cells from their neural crest precursors.

Intracellular recordings from canine intracardiac ganglion cells

Stable transmembrane potentials were recorded from 60 canine intracardiac ganglion cells taken from 10 dogs, which had intact synaptic connections: mean resting membrane potential, input resistance and time constant were 61.5 mV, 70 M omega and 3.3 ms. Action potentials could be evoked by intrasomal current injection and by orthodromic and antidromic stimulation of interganglionic nerves. Orthodromic action potentials were initiated by excitatory postsynaptic potentials and mediated by nicotinic receptors. All action potentials could be blocked by tetrodotoxin. Intracellular labeling revealed large cell bodies and long dendritic and axonal processes. Thus, the functional and anatomical properties of canine cardiac ganglion cells and their synaptic connections can be elucidated using this preparation.

Microtubule-associated protein-2 and neurofilament immunoreactivity in neurons and small, intensely fluorescent cells of an amphibian cardiac ganglion

The localization of two cytoskeletal proteins was analysed in the cell bodies and processes of ganglionic neurons and small, intensely fluorescent cells of the parasympathetic cardiac ganglion of Necturus maculosus (mudpuppy). Antibodies against microtubule-associated protein-2 and against the highly phosphorylated isoforms of high and middle molecular weight neurofilament subunits were used as somatodendritic and axonal markers, respectively. The ganglionic neurons, which usually have only one major process, and small, intensely fluorescent cells, which have several processes, showed distinctly different staining patterns with the two antibodies. In control and denervated ganglia, the ganglionic cell bodies and several hundred micrometers of the proximal processes were labeled with the antibody against microtubule-associated protein-2, whereas small, intensely fluorescent cells and processes showed a paucity of immunoreactivity. The neurofilament antibody labeled numerous axons in the ganglion but did not label the proximal part of the postganglionic process or small, intensely fluorescent cell processes. Denervation resulted in the presence of phosphorylated neurofilament subunit immunoreactivity in the soma and proximal process of the ganglionic neuron. These data suggest that (i) small, intensely fluorescent cells and ganglionic neurons in the mudpuppy cardiac ganglion contain distinctly different cytoskeletal proteins, (ii) the proximal part of postganglionic "axons" contains dendrite-like and not axon-like cytoskeletal proteins, and (iii) deafferentation promotes the localization of phosphorylated forms of neurofilament subunits in the soma and proximal process of parasympathetic ganglionic neurons.

Analysis of the galanin-induced decrease in membrane excitability in mudpuppy parasympathetic neurons

Previously, we showed that the neuropeptide galanin hyperpolarizes and decreases membrane excitability of mudpuppy parasympathetic neurons [Konopka L. M., McKeon T. W. and Parsons R. L. (1989) J. Physiol. 410, 107-122]. We also demonstrated that membrane excitability remains depressed when the agonist-induced potential change is negated electrotonically. We hypothesized that galanin inhibits the membrane conductances associated with spike generation. However, we cannot rule out the possibility that the decreased excitability is due to a galanin-induced increase in membrane potassium conductance which reduces the effectiveness of subsequent depolarizing stimuli. Therefore, in the present study we tested, with the galanin-induced hyperpolarization negated, whether the galanin-induced increased membrane potassium conductance was responsible for the decreased excitability. The results showed that the galanin-induced decreased excitability was not dependent on the peak amplitude of the galanin-induced hyperpolarization. Furthermore, the decreased excitability occurred in cells in which there was no measurable galanin-induced hyperpolarization. Moreover, in most cells the galanin-induced decrease in input resistance, measured at the peak of the hyperpolarization (3-25 mV), was less than 15% and when the hyperpolarization was negated electronically, the decrease was even less (approximately 2%). These results indicated that when the hyperpolarization was negated, the galanin-induced increase in potassium conductance was not responsible for the decreased excitability. In preparations pretreated with 5 mM tetraethylammonium, galanin decreased excitability which indicated that a galanin-induced decrease in the calcium-dependent potassium current was not necessary for the decreased excitability. Galanin also decreased excitability in preparations exposed to either 1-3 microM tetrodotoxin or 100-200 microM cadmium. Following galanin application, the threshold for initiation of tetrodotoxin-insensitive spikes was shifted to more positive membrane potentials. Galanin also decreased the amplitude and hyperpolarizing afterpotential of barium spikes in the absence of any agonist-induced hyperpolarization. These observations confirmed that galanin decreased the voltage-dependent calcium conductance. In the present study, we showed that when the hyperpolarization was negated, galanin decreased excitability by shifting the threshold for spike generation regardless of whether voltage-dependent sodium or calcium currents were primarily responsible for the depolarizing component of the action potential.

Galanin immunoreactivity in the mudpuppy cardiac ganglion

The source of galanin-immunoreactive fibers in the cardiac ganglion and on cardiac muscle in mudpuppy (Necturus maculosus) has been determined utilizing immunohistochemical techniques. The galanin-immunoreactive fibers are not processes of afferent fibers originating in either the rostral four dorsal root ganglia or vagal sensory ganglia. Following colchicine treatment, all of the postganglionic parasympathetic neurons and a subpopulation of the small intrinsic neurons in the cardiac ganglion exhibit galanin immunoreactivity. The majority of the galanin-immunoreactive fibers that form complexes on the parasympathetic postganglionic neurons are derived from galanin-immunoreactive small intrinsic neurons, although some of these connections may represent collateral processes from other parasympathetic postganglionic neurons. All of the galanin-immunoreactive processes that innervate cardiac muscle are derived from postganglionic parasympathetic neurons in the cardiac ganglion.

Electrophysiology of parasympathetic neurones isolated from the interatrial septum of bull-frog heart

1. Whole-cell voltage-clamp techniques were used to study the voltage-dependent membrane conductances in parasympathetic neurones enzymatically isolated from the interatrial septum of bull-frog heart and maintained in short-term (1-10 day) tissue culture. 2. The resting potential of the isolated neurones averaged -55.4 +/- 1.1 mV (+/- S.E.M., n = 11). Action potentials evoked in the isolated cells by brief (1-2 ms) current injections were similar to those recorded from neurones in the 'intact' septum. The amplitude of action potentials of isolated neurones averaged about 113 mV, with a peak depolarization of +32.8 +/- 2.8 mV and after-hyperpolarization of -80.0 +/- 2.8 mV. 3. The pattern of membrane currents recorded using voltage clamp with 'normal' external (containing 110 mM-Na+) and internal (110 mM-K+) solutions consisted of a rapidly activating and inactivating inward current followed by a slower, sustained outward current. 4. The inward components of current were isolated by using an internal solution in which Cs+ and TEA+ (tetrathylammonium) ions replaced K+. Depolarizations from holding potentials of -50 to -70 mV produced inward currents which had an initial transient phase followed by a maintained, or very slowly inactivating, component. The current-voltage relation for the initial transient phase reached a peak at membrane potentials near 0 mV, while the maintained phase, measured, for example, at the end of 50 ms voltage-clamp steps, had its peak near +10 mV. 5. The transient component of inward current was carried primarily by Na+ ions, as replacement of Na+ by TEA+ in the external solution abolished the transient. This current was thus identified as a voltage-dependent Na+ current, INa. The maintained component was greatly attenuated by removing 80-90% of the external Ca2+ ions, and it was abolished by divalent cations such as Cd2+ (0.2-0.4 mM), Ni2+ (0.5 mM) and La3+ (10-100 microM). This maintained component was thus a voltage-dependent calcium current, ICa. 6. About 80% of INa recorded in the presence of low (0.2-0.5 mM) external Ca2+ and 2 microM-LaCl3 was blocked by tetrodotoxin (TTX) with an apparent Kd of about 8 nM. The remaining 20% of INa was resistant to block by 2-10 microM-TTX. However, the 'TTX-resistant' component of INa was blocked by Cd2+ (0.2-0.4 mM). 7. The voltage-dependent calcium current, ICa, measured in saline in which Na+ was replaced by N-methyl-D-glucamine, activated near -40 mV and reached a peak near +10 to +15 mV.(ABSTRACT TRUNCATED AT 400 WORDS)

Galanin-induced hyperpolarization and decreased membrane excitability of neurones in mudpuppy cardiac ganglia

1. Membrane hyperpolarization and decreased excitability produced by galanin were investigated in vitro on parasympathetic postganglionic neurones in the cardiac ganglion of the mudpuppy, Necturus maculosus. 2. Galanin produced a slowly developing hyperpolarization which, in 2.5 mM-KCl, reversed at -105.4 +/- 2.7 mV. The reversal potential was shifted by 38.7 +/- 4.9 mV following a fourfold elevation of the extracellular potassium concentration. 3. Galanin inhibited action potential firing in spontaneously active neurones and decreased the number of spikes in a train produced by long (500-680 ms) depolarizing current pulses. Both effects were independent of the galanin-induced hyperpolarization. 4. Galanin increased the threshold for spike generation, prolonged the spike hyperpolarizing after-potential and decreased the maximum rate of rise, amplitude and maximum rate of fall of the sodium spike. These effects occurred independently of the galanin-induced hyperpolarization. 5. Galanin decreased the amplitude and duration of TTX-insensitive spikes initiated in cells maintained in a solution containing 9 mM-calcium, 20 mM-TEA and 1.5 microM-TTX. 6. These results suggest that a galanin-like peptide may act as an inhibitory transmitter in the mudpuppy cardiac ganglion.

The presence and possible role of a galanin-like peptide in the mudpuppy heart

A correlated histochemical and pharmacological study was undertaken to establish the presence, origin, and possible function of nerve fibers containing a galanin-like peptide in the mudpuppy (Necturus maculosus) heart. Whole mount preparations of septum-sinus venosus or atria and sections of ventricular muscle were prepared for immunocytochemistry. Galanin-immunoreactive fibers were found coursing diffusely across the septum-sinus venosus to form complex networks over cardiac muscle strands. Individual atrial muscle strands were densely innervated by galanin-immunoreactive fibers and galanin-immunoreactive fibers were also observed in the epicardial and myocardial layers of the ventricle. Most of the parasympathetic postganglionic neurons in the cardiac ganglion and many of the small intensely fluorescent-like cells exhibited galanin immunoreactivity. Galanin-immunoreactive fibers were present in the nerve trunks connecting clusters of parasympathetic postganglionic neurons. Close associations between galanin-positive fibers and individual parasympathetic postganglionic neurons were also observed. The presence of the galanin-immunoreactive fibers was similar in preparations taken from animals pretreated with 6-hydroxydopamine to that seen in preparations taken from control animals, indicating that the galanin-positive fibers were not sympathetic postganglionic axons. Moreover, the galanin-immunoreactive nerve fibers were separate from fibers containing substance P and/or calcitonin gene-related peptide that have previously been shown to be processes of afferent fibers. In twitch-tension experiments, galanin in the range 1 x 10(-7) to 1 x 10(-6) M caused cardioinhibition of spontaneously beating isolated septal-sinus venosus preparations. Galanin also produced a concentration-dependent (1 x 10(-7) to 1 x 10(-6) M) decrease in the twitch-tension development of electrically stimulated atrial or ventricular preparations. Local application of galanin produced hyperpolarization of cardiac muscle fibers in both isolated septal-sinus venosus preparations and atrial preparations. The response of individual parasympathetic ganglion cells to local application of galanin varied between neurons; some neurons were depolarized whereas others were hyperpolarized. We conclude that a galanin-like peptide is contained in both the parasympathetic postganglionic neurons and small intensely fluorescent-like cells and their processes. Further, we hypothesize that in the case of the parasympathetic postganglionic neurons, the galanin-like peptide may work in conjunction with acetylcholine to regulate cardiac activity.

The organization of the cardiac ganglion of the axolotl (Ambystoma mexicanum)

The heart of the axolotl Ambystoma mexicanum was studied with histochemical methods to determine the distribution of neurons containing acetylcholine esterase, catecholamines and 5-hydroxytryptamine. The cardiac ganglion is made up of cholinergic nerve fibers and somata, and of catecholaminergic fibers. Small intensely fluorescent cells were found along blood vessels in the pericardial wall at the base of the heart, but not in the heart itself, except, in a few instances, in the region bordering the pericardial wall. Both the cholinergic and the catecholaminergic innervation of the heart were poorly developed at hatching and reached their mature state after a few months. Cholinesterase staining fibers appeared several weeks before catecholaminergic fibers. The number of postganglionic cholinergic neurons in the heart increased several-fold during the first month after hatching. Histofluorescence studies of organ cultures suggested that all the catecholamine present in the heart are of extrinsic origin. Liquid chromatography with electrochemical detection demonstrated that the dominant catecholamine in the heart is norepinephrine. No neurons containing 5-hydroxytryptamine were found.

Distribution of calcitonin gene-related peptide immunoreactive nerve fibers in the mudpuppy cardiac septum

An immunohistochemical study was undertaken to determine the distribution of calcitonin gene-related peptide (CGRP)-immunoreactive nerve fibers in the cardiac septum of the mudpuppy, Necturus maculosus. Numerous long, CGRP-immunoreactive nerve fibers course across the septum, run in the nerve trunks connecting clusters of postganglionic parasympathetic cells, form complexes over groups of ganglion cells and make pericellular networks around individual ganglion cells. The postganglionic parasympathetic neurons and small intensely fluorescent (SIF)-like cells did not exhibit CGRP immunoreactivity. Most of the CGRP-immunoreactive nerve fibers also are labeled for substance P. In freshly dissected preparations, the staining pattern for CGRP was not similar to that obtained using an antiserum against synaptic vesicle membrane, which appears to preferentially label cholinergic preganglionic terminals on all postganglionic parasympathetic cells in the mudpuppy preparation. Further, in explanted ganglia (maintained 10 days in culture) almost no reactivity was obtained with the antivesicle antiserum whereas numerous nerve fibers still exhibited CGRP-immunoreactivity. These observations demonstrate that the CGRP-immunoreactive nerve fibers are not parasympathetic preganglionic axons. Rather we suggest that the CGRP-immunoreactive nerve fibers are processes of primary sensory fibers.

Intracellular studies of the electrophysiological properties of cultured intracardiac neurones of the guinea-pig

1. The electrophysiological properties of intracardiac neurones cultured from ganglia within the atria and interatrial septum of the new-born guinea-pig heart were studied using intracellular micro-electrodes. 2. Three types of neurones with resting membrane potentials in the range -45 to -76 mV were detected. The first type, AHs cells, had high (15-28 mV) firing thresholds, pronounced slow post-spike after-hyperpolarizations and fired only once to prolonged intrasomal current injection. The second type, AHm cells, were similar to AHs cells, except that they could fire short bursts of spikes (100-400 ms) at the onset of current injection. The third type, M cells, had low firing thresholds (10-15 mV), no slow after-hyperpolarizations and produced non-adapting trains of action potentials in response to depolarizing current injection. 3. The generation of action potentials in M cells was prevented by tetrodotoxin (TTX; 0.3 microM), whereas in AHs and AHm cells action potentials displayed a channel blockade using solutions containing the divalent cations cadmium, cobalt or manganese (0.02-1 mM). 4. The post-spike after-hyperpolarization in AHs and AHm cells was abolished by the removal of extracellular calcium, shortened in solutions containing the calcium entry blockers CdCl2, MnSO4 and CoCl2 (0.02-1 mM) and prolonged by the addition of calcium (5.0 mM), tetraethylammonium (1-3 mM), 4-aminopyridine (1-3 mM), cyanide (10 microM) or caffeine (100 microM) to the perfusate. 5. The reversal potential of the post-spike after-hyperpolarization was -89.1 mV. This value changed by 62.9 mV for a 10-fold increase in extracellular potassium concentration. 6. The peak conductance change during the post-spike after-hyperpolarization (gK,Ca), was largely independent of membrane potential between -50 and -110 mV. The peak increase in gK,Ca and the duration of the after-hyperpolarization increased with the number of spikes preceding it. 7. It is concluded that calcium entry during the action potential is responsible for the activation of an outward potassium current in the two types of AH cells; the roles played by intracellular calcium extrusion as well as sequestration mechanisms in the generation of the response are discussed.

Spontaneous miniature outward currents in cultured bullfrog neurons

Spontaneous miniature hyperpolarizations were observed in cultured bullfrog neurons. Depolarization increased the frequency and amplitude of the events. Under voltage-clamp, these events were manifested as spontaneous miniature outward currents of SMOCs which were usually less than 2 nA, had a rapid rising phase and a slower voltage-dependent exponential decay. Analysis of inter-event intervals suggested that SMOCs occurred randomly, while analysis of their amplitudes yielded exponential amplitude distributions. Mean SMOC amplitudes and SMOC frequency increased with depolarization, even with 100 microM CdCl2 present. Time constants of SMOC decay resembled time constants obtained from voltage-jump experiments on Ca2+-loaded cells, and together with the sensitivity of SMOCs to tetraethyl ammonium (TEA), suggested that SMOCs are due to activation of fast Ca2+-gated potassium channels. We propose that a SMOC occurs when 10-5000 of these channels are activated by punctate intracellular Ca2+ release.

"SIF" cells in the sympathetic ganglia of the bullfrog, Rana catesbeiana: variety in population and innervation

"Small intensely fluorescent" (SIF) cells appeared singly or, more frequently, in variably-sized clusters in the sacroccygeal 8th and 9th sympathetic ganglia of the bullfrog. Smaller clusters containing only two to nine SIF cells accounted for 61% of 1773 clusters examined. The largest cluster contained 283 cells. The number of cells in individual ganglia also varied from 21 to 3332. SIF cells, solitary as well as in smaller clusters, received no distinct form of the synaptic contact. In contrast, the cells in larger clusters were frequently innervated by nerve endings that were similar in vesicular constitution to the nerve endings on principal ganglion (PG) cells. No synaptic contact was found between SIF cells and PG cells. SIF cells were also characterized by their location in the vicinity of blood capillaries with a continuous endothelium. Our observation seems to suggest that larger clusters of SIF cells receiving nerve endings are linked to a paracrine and/or endocrine system. Chemical influence via the blood stream and intraganglionic milieu for non-innervated SIF cells in the solitary or smaller clusters is a subject for speculation. An interneuronal role of SIF cells to relay stimuli to PG cells seems unlikely. The possible functions here assigned to SIF cells could be variable in efficiency depending on their population and density.

Anatomical evidence for the interaction of sympathetic and parasympathetic neurons in the cardiac ganglion of Necturus

Evidence of a direct interaction between sympathetic and parasympathetic elements in a cardiac parasympathetic ganglion is presented in this study. Experiments were done using acutely dissected or organ cultured parasympathetic cardiac ganglion preparations from Necturus maculosus (mudpuppy). The glyoxylic acid-induced fluorescence technique was used to visualize catecholamine-containing cells and fibers. Numerous long brightly fluorescent varicose fibers form a complex network over clusters of parasympathetic ganglion cells and strands of cardiac muscle. In addition to these fibers, there are numerous small brightly fluorescent interneurons (SIF cells) interspersed between individual parasympathetic ganglion cells. Long fibers and processes from the interneurons join to form bundles which arborize over groups of parasympathetic cells. In peripherally located smaller groups of ganglion cells there are no interneurons, but some of these parasympathetic cells appear to receive innervation from the long continuous fluorescent axons. Two experimental procedures were applied to support the conclusion that these long fibers were indeed sympathetic postganglionic axons: explants of cardiac ganglia were maintained for varying times to produce degeneration of any severed axons: chemical sympathectomy was produced by injection of 6-hydroxydopamine. The intrinsic SIF cells were apparently unaffected by both procedures. After 8 days in culture or after 6-OH dopamine treatment, all of the long continuous brightly fluorescent fibers, which normally intermingle with clusters of ganglion cells or innervate cardiac muscle, were absent. This indicates their extra-ganglionic origin. All of the isolated groups of parasympathetic ganglion cells not containing SIF cells were totally devoid of any catecholamine-containing fibers.

Vagus nerve stimulation alters regional acetylcholine turnover in rat heart

The turnover of neurotransmitter is a direct measure of neuronal function, varying with the impulse activity of the nerve. It is not known if vagal stimulation increases acetylcholine release uniformly throughout the heart, or if modification of neural signals occurs between the vagal nerve trunks and postganglionic synaptic terminals. The rate constant of acetylcholine turnover was measured in conduction and contractile regions of heart by quantifying the incorporation of [3H]choline into acetylcholine after labeling of the blood choline pool in urethane-anesthetized rats during two levels of vagal activity. Choline and acetylcholine were assayed by high pressure liquid chromatography with electrochemical detection of post-column enzymic reaction product, peroxide. The specific activities of choline and acetylcholine in the tissues at sacrifice were used to calculate the fractional turnover rates in cardiac regions. Supramaximal bilateral vagal stimulation for 20 minutes decreased heart rate (P less than 0.05), while mean arterial blood pressure remained constant. The rate constants for acetylcholine turnover in right atrial regions containing the sinoatrial node, left atrial tissues, and interatrial septum doubled from control values during vagal stimulation. In contrast, the fractional rate constants of acetylcholine turnover did not change in the right and left ventricles during vagal stimulation. We interpret these results to indicate general activation of postganglionic parasympathetic fibers to the atria and selective modulation of postganglionic parasympathetic neural function to the ventricles.

Intrinsic neurones and associated cells of the guinea-pig heart in culture

This paper describes a method for dissociation of intrinsic neurones from the atria and interatrial septum of newborn guinea-pig heart and their maintenance in culture. The appearance of the cultured intracardiac neurones, muscle and other non-neuronal cell types also present in the preparation has been observed by phase-contrast microscopy. Some of the neurochemical properties of the intracardiac neurones in culture have been investigated using histochemical methods. All the neurones studied were shown to contain acetylcholinesterase. No catecholamine-containing neurones were found. Using an indirect immunofluorescence technique, 20-50% of clearly identifiable neurones in culture contained neuropeptide Y-like immunoreactivity. Vasoactive intestinal polypeptide-like immunoreactive neurones were found in only one out of 15 culture preparations; no substance P-, neurotensin-, or enkephalin-like immunoreactivity was observed. These findings are consistent with those described for intracardiac neurones studied in situ, suggesting that the neurochemical differentiation of the intrinsic heart neurones is retained in culture. The culture preparation provides an opportunity to study the properties and role of intrinsic neurones of the heart. The characteristics of the intracardiac neurones may be distinguished from those of the extrinsic nerve fibres which degenerate in culture. Further, the intracardiac neurones are more accessible to experimental manipulation in culture than in situ.

Innervation of small intensely fluorescent cells in frog sympathetic ganglia

Autonomic ganglia have a population of small intensely fluorescent (SIF) cells with unknown function. We have investigated the afferent innervation of SIF cells in bullfrog sympathetic ganglia using intracellular recordings and light microscopy of stained preganglionic axon terminals. Contrary to previous knowledge, bullfrog SIF cells do indeed receive functional synaptic input and this innervation is provided solely by the C-type preganglionic nerve fibers.

The ultrastructure of identified locust motor neurones and their synaptic relationships

Motor neurones in the thoracic ganglia of the locust were impaled with microelectrodes and identified according to the muscle they innervated and their other physiological properties. They were then labeled by intracellular injection of horseradish peroxidase and processed for electron microscopy. The nature and distribution of synapses on each motor neurone was examined and, by the use of reconstruction from serial sections, their spatial relationships revealed. The metathoracic fast extensor tibiae and mesothoracic tergosternal flight motor neurones have both output and input synapses on their neuropilar branches. These synapses are involved in serial, reciprocal, and recurrent relationships showing that the structural equivalent of a physiological synapse may be complex. The metathoracic slow extensor tibiae and anterior fast flexor tibiae motor neurones apparently have only input synapses within the neuropile.

A scanning electron microscope study of the in vitro development of dissociated hippocampal cells

Cultures of dissociated hippocampal neurons from 18-day-old rat fetuses were examined by scanning electron microscopy after periods between one hour and 20 days following plating on a poly-L-lysine coated substrate. Cell attachment was virtually complete within one hour after plating, and at that stage many cells could be seen which had started to extend processes with broad growth cones. By four hours in culture, process formation was well advanced and some cells had already assumed a pyramidal configuration. After 16 hours in culture, numerous contacts were seen between neighboring growth cones, and this frequently led to fasciculation of the interacting fibers. During the next three weeks the cell bodies enlarged considerably and rounded-up, and two distinct types of processes became evident: large, rapidly tapering dendrite-like processes and finer, essentially uniform-diametered processes that resemble axons. In most of the older cultures a dense plexus of processes was formed, and many of the finer processes appeared to have "bouton-like" swellings as they traversed the upper surfaces of the neuronal perikarya. Non-neuronal elements, which comprised only about 5% of the cells initially plated, rapidly proliferated in our cultures and within three to six days formed a confluent monolayer beneath the neurons.

Elimination of synapses in the developing nervous system

Reduction of the number of axons that contact target cells may be a general feature of neural development. This process may underlie the progressively restricted malleability of the maturing nervous system.

The reorganization of synaptic connexions in the rat submandibular ganglion during post-natal development

1. The innervation of neurones in the submandibular ganglion of neonatal and adult rats has been studied with intracellular recording, and light and electron microscopy. 2. Intracellular recordings from neurones in isolated ganglia from adult animals showed that about 75% of the ganglion cells are innervated by a single preganglionic fibre. 3. However multiple steps in the post-synaptic potential (about five on average) were elicited in ganglion cells from neonatal animals by graded stimulation of the preganglionic nerve. The same result was obtained when the preganglionic fibres were stimulated at their emergence from the brainstem, indicating that neonatal neurones are innervated by several different preganglionic nerve cells. 4. The number of preganglionic fibres innervating individual ganglion cells gradually decreased during the first few weeks of life, and by about 5 weeks each ganglion cell was generally contacted by a single preganglionic axon. 5. Synapses were made on short protuberances in the immediate vicinity of the neuronal cell bodies in both neonatal and adult ganglia as shown by staining presynaptic boutons with the zinc-iodide osmium method, injection of horseradish peroxidase into ganglion cells, and electron microscopical examination. 6. Electron microscopical counts of synaptic profiles per ganglion cell perimeter showed that the number of synaptic contacts made on ganglion cells actually increased during the first few post-natal weeks, when the number of axons innervating each neurone was decreasing. 7. These results show that in the rat submandibular ganglion there is a reorganization of neuronal connexions during the first few weeks of life which results in a transition from multiple to generally single innervation of ganglion cells.

Synaptic excitation and inhibition resulting from direct action of acetylcholine on two types of chemoreceptors on individual amphibian parasympathetic neurones

1. Synaptic transmission was studied in visually identified parasympathetic ganglion cells that modulate the heart beat of the mudpuppy Necturus maculosus).2. The brief pulse of acetylcholine (ACh) released from terminals of the vagus nerve after each impulse can produce two distinct post-synaptic responses in individual principal cells of the ganglion: (i) within a milli-second of release, ACh generates a rapid and strong excitatory post-synaptic potential (e.p.s.p.) that normally initiates a post-synaptic impulse; (ii) this excitation is usually followed by a slow hyperpolarizing inhibitory post-synaptic potential (i.p.s.p.) that lasts for several seconds. The magnitude and time course of the i.p.s.p. depends on the frequency and number of vagal stimuli. When the hydrolysis of ACh is inhibited by prostigmine, a train of nerve stimuli may be followed by an i.p.s.p. lasting half a minute or longer.3. The rapid e.p.s.p. and slow i.p.s.p. result from the direct action of ACh on two different types of chemoreceptors in the post-synaptic membrane of the principal cell. The e.p.s.p. can be preferentially blocked by the nicotinic antagonist dihydro-beta-erythroidine (5 x 10(-7)M), while the i.p.s.p. is selectively blocked by the muscarinic antagonist atropine (5 x 10(-9)M).4. Potentials resembling nerve-evoked e.p.s.p.s and i.p.s.p.s can be produced by iontophoretic release of ACh from micropipettes onto the post-synaptic membrane. Application of the muscarinic agonist bethanechol generates exclusively inhibitory responses.5. The reversal potential for the i.p.s.p. is about -105 mV, which is approximately the equilibrium potential for potassium (E(K)). When the external K(+) concentration is altered, the reversal potential for inhibition is shifted to the new value of E(K) as expected from the Nernst equation. Changes in the external Na(+) and Cl(-) concentrations have no appreciable effect on the reversal potential. Thus, the i.p.s.p. is the result of a conductance increase for K(+).6. The conductance change producing the i.p.s.p. is voltage sensitive. When the membrane potential is shifted from -40 to -60 mV, the i.p.s.p becomes larger and longer. Beyond -60 mV the inhibitory response decreases in proportion to the driving force on K(+) without any further change in time course.7. The inhibitory response produced by an iontophoretically applied pulse of bethanechol has a delayed onset of about 150 msec at 24 degrees C. The early portion of this response, including the delay, is proportional to t(3), where t is time. The proportionality factor (the apparent rate constant) decreases elevenfold when the temperature is lowered by 10 degrees C. This suggests that a multi-step process is involved in the activation of the conductance increase that leads to the inhibitory response. Inhibitory responses with similar kinetics were produced in heart muscles of the mudpuppy upon application of ACh.

The acetylcholine sensitivity of the surface membrane of multiply-innervated parasympathetic ganglion cells in the mudpuppy before and after partial denervation

1. The surface chemosensitivity to iontophoretically applied acetylcholine (ACh) of single nerve cells in the cardiac ganglion of the mudpuppy was examined. 2. Some synapses on the neurones can be recognized in the living preparation with differential interference contrast optics. Identified synaptic regions of the ganglion cells were more sensitive to ACh than were other areas. The mean sensitivity of synaptic areas was 509 mV/nC, but that of random spots on the cell surface (which were mainly non-synaptic) was only 190 mV/nC. The mean rise time of ACh responses at synapses was 23 msec and at random spots was 36 msec. These data suggest that the density of ACh receptors is highest under the synapses on the post-synaptic membrane. 3. When some, but not all, of the presynaptic terminals on the ganglion cells are destroyed by cutting the vagus nerve, the sensitivity of the entire surface membrane to applied ACh increases. This increase in sensitivity reaches a maximum about 4-6 weeks after the operation. 4. Synaptic transmission at excitatory collateral synapses which remain after vagal degeneration is not altered by this hypersensitivity. 5. Neurones from ganglia which have been isolated and maintained in organ culture also become hypersensitive to applied ACh. this heightened chemosensitivity deveoops much faster in vitro; hypersensitivity in cultured ganglia becomes manifest within 4-5 days, in contrast with 4-6 weeks after vagus degeneration in vivo.

An electrophysiological study of chemical and electrical synapses on neurones in the parasympathetic cardiac ganglion of the mudpuppy, Necturus maculosus: evidence for intrinsic ganglionic innervation

1. The cardiac ganglion of the mudpuppy is situated on a thin sheet of tissue. Two nerve cell types can be distinguished readily in the living preparation - principal cells and smaller interneurones which synapse with the principal cells. The purpose of this study was to investigate synaptic transmission and the functional organization of neuronal connections of ganglion cells with intracellular micro-electrodes. 2. Stimulation of the preganglionic, vagus, nerves evoked a large excitatory response in principal cells. About three quarters of these neurones were innervated by a single vagal axon. The remaining cells received two or more preganglionic nerve fibres. 3. The quantum content of vagal excitatory post-synaptic potentials (e.p.s.p.s) was measured. Normally, the e.p.s.p. was suprathreshold and consisted of about twenty-two quanta, whereas only about nine quanta were required to reach threshold and initiate an action potential. 4. Intracellular stimulation of principal cells evoked e.p.s.p.s in neighbouring principal cells. The responses were blocked by cholinergic antagonists. These potentials were caused by excitation of principal cell axon collateral synapses. 5. Principal cells also formed electrical junctions with each other. These electrical junctions were very weak. Although they transmitted slow potential changes, only a small response was recorded in one cell when an electrically coupled neighbouring cell fired an impulse. The resistance of the electrical junction between principal cells was calculated to be about 5-8 X 10(8) omega. 6. Stable penetrations of interneurones were only rarely achieved, making it difficult to study their functional relationship to principal cells. Action potentials were recorded from interneurones in a few instances. 7. These data demonstrate that parasympathetic ganglion cells in the heart of the mudpuppy receive innervation from more than one source involving both chemical and electrical synapses, and that some of the synapses are intrinsic to the ganglion.