Cholinergic neurons of the chicken ciliary ganglion contain somatostatin

Somatostatin immunoreactivity was studied in the avian ciliary ganglion by immunocytochemistry and radioimmunoassay. Immunoreactivity was localized to small diameter cell bodies of neurons from embryos, newly-hatched and adult preparations. Immunostaining of ganglia with a mixture of antisera to substance P and monoclonal antibody to somatostatin indicated that a number of somatostatin-immunoreactive neurons were surrounded by substance P-immunoreactive boutons, which characteristically terminate on choroidal neurons. Staining with a mixture of antisera to choline acetyltransferase and antibody to somatostatin showed that the somatostatin-immunoreactive neurons were less intensely-stained for choline acetyltransferase than were the neurons lacking somatostatin immunoreactivity. Bundles of nerve fibers showing somatostatin and choline acetyltransferase immunoreactivity were found in the choroid layers of the eye. Radioimmunoassay indicated the presence of somatostatin immunoreactivity in both chick and quail ganglia; the somatostatin immunoreactivity eluted from high pressure liquid chromatography in the same positions as authentic somatostatin 14 and 28. These results show that somatostatin is contained in cholinergic choroidal neurons in the chick and quail ciliary ganglion.     

Choline acetyltransferase-immunoreactive neurons intrinsic to rodent cortex and distinction from acetylcholinesterase-positive neurons

Cholinergic neurons intrinsic to rat cortex were studied using a sensitive method for the localization of choline acetyltransferase immunoreactivity, acetylcholinesterase histochemistry, combined localization of choline acetyltransferase and acetylcholinesterase, and combined localization of choline acetyltransferase and retrogradely transported horseradish peroxidase-wheat germ agglutinin. Choline acetyltransferase immunoreactivity was localized predominantly in small bipolar cortical neurons within the upper layers of isocortex, while small multipolar neurons were the predominantly stained cell type in allocortical regions. Acetylcholinesterase histochemistry demonstrated mainly small polymorphic cells scattered throughout all cellular layers in all cortices. Combined staining for choline acetyltransferase and acetylcholinesterase resulted in localization of the markers in different cell populations; choline acetyltransferase-immunoreactive neurons did not contain detectable acetylcholinesterase and acetylcholinesterase-positive neurons did not contain detectable immunoreactivity to choline acetyl-transferase. Some possible connections of the cortical choline acetyltransferase-immunoreactive cells were studied in rats which had received injections of horseradish peroxidase-wheat germ agglutinin into either cortex or brainstem. The choline acetyltransferase-immunoreactive cells were frequently admixed with cells labeled with the retrograde marker; however, no double-labeled cells were observed.It was concluded that cortical cholinergic cells are not visualized by acetylcholinesterase histochemistry, and are likely to be involved in local circuitry.     

Choline acetyltransferase immunoreactivity in the cat cerebellum.

Choline acetyltransferase immunoreactivity was demonstrated in particular projection systems in cat cerebellum by combining immunohistochemistry, retrograde tracing and lesioning paradigms. The monoclonal antibody used in this study recognized a 68,000 mol. wt protein on immunoblots of cat cerebellum and striatum. Choline acetyltransferase immunoreactivity was localized to some neurons and varicose fibers in the cerebellar nuclei, and also to some mossy fibers and endings (rosettes), fiber plexuses around Purkinje cells, granule cells and parallel fibers in the cerebellar cortex. In addition, the presence of choline acetyltransferase-immunoreactive large cells, presumptive Golgi cells, in the granular layer was confirmed. In each cerebellar nucleus, choline acetyltransferase-immunoreactive neurons contained either large, medium-sized or small cell bodies and were distributed evenly in the entire nuclear domain. Large and medium-sized ones were frequently encountered. Choline acetyltransferase-immunoreactive mossy fibers and rosettes were most abundant in the vermal lobules I-III, VIII, IX and the simple lobule, moderately accumulated in the vermal lobules IV-VII, X, crus I and crus II, and less abundant in the paramedian lobule, paraflocculus and flocculus. Some granule cells with prominent dendritic claws and bifurcating parallel axons were immunolabeled in the entire vermis with infrequent occurrence in the remaining cortices. Following unilateral lesioning of the cerebellar nuclei with electrocoagulation or kainate injections, a reduction in number of choline acetyltransferase-immunoreactive fibers occurred ipsilaterally in the cerebellar cortex and contralaterally in the red nucleus, ventrolateral thalamic nucleus and ventroanterior thalamic nucleus. In addition, perikarya of some cerebellothalamic neurons were shown to contain choline acetyltransferase immunoreactivity. The results indicate that some nucleocortical, cerebellorubral and cerebellothalamic projections are cholinergic and that a subpopulation of cholinergic granule cell-parallel fibers exists.     

Ultrastructural relationships between choline acetyltransferase- and neuropeptide y-containing neurons in the rat striatum.

The relationships between cholinergic and neuropeptide Y-containing neuronal systems in the rat striatum were examined using a dual immunoperoxidase labelling method. These neurons were identified by their immunoreactivity to choline acetyltransferase and neuropeptide Y, respectively, and were visualized on the same sections using 3,3'-diaminobenzidine and benzidine dihydrochloride as distinct chromogens under two conditions: (i) neuropeptide Y detection by the 3,3'-diaminobenzidine diffuse brown reaction product and choline acetyltransferase detection by the benzidine dihydrochloride blue, granular reaction product; (ii) choline acetyltransferase detection by 3,3'-diaminobenzidine and neuropeptide Y detection by benzidine dihydrochloride. Although both neuropeptide Y- and choline acetyltransferase-immunoreactive cell bodies were simultaneously detected and were easily distinguishable whatever the conditions used, neuropeptide Y- and choline acetyltransferase-immunoreactive dendrites and axons could not be visualized on the same sections, since only the diaminobenzidine-labelled processes were detectable. Light microscopic observations on sections dual labelled with either method confirmed that choline acetyltransferase and neuropeptide Y immunoreactivities were localized in morphologically different populations of striatal neurons scattered throughout the striatum, choline acetyltransferase immunoreactivity being associated with large neurons and neuropeptide Y immunoreactivity with medium-sized neurons. In addition, the choline acetyltransferase-immunoreactive neurons were found to be more numerous than the neuropeptide Y-immunoreactive neurons and to be prevalent in the dorsolateral areas of the striatum, whereas neuropeptide Y-immunoreactive neurons were preferentially found in the ventromedial areas of this structure. Electron microscopic observations on sections processed under either condition revealed that choline acetyltransferase-positive terminals form synaptic contacts of the symmetrical type with neuropeptide Y-positive somata and proximal dendrites and that choline acetyltransferase-positive neurons are contacted by neuropeptide Y-positive terminals. These data show that the striatal neuropeptide Y- and choline acetyltransferase-containing neuronal systems have reciprocal synaptic interactions and provide morphological support for the hypothesis that striatal cholinergic and neuropeptide Y interneuron activities may be functionally linked.     

Cholinergic input to dopaminergic neurons in the substantia nigra: a double immunocytochemical study.

In order to determine whether the cholinergic fibres that innervate the substantia nigra make synaptic contact with dopaminergic neurons of the substantia nigra pars compacta, a double immunocytochemical study was carried out in the rat and ferret. Sections of perfusion-fixed mesencephalon were incubated first to reveal choline acetyltransferase immunoreactivity to label the cholinergic terminals and then tyrosine hydroxylase immunoreactivity to label the dopaminergic neurons. Each antigen was localized using peroxidase reactions but with different chromogens. At the light microscopic level, in confirmation of previous observations, choline acetyltransferase-immunoreactive axons and axonal boutons were found throughout the substantia nigra. The highest density of these axons was found in the pars compacta where they were often seen in close apposition to tyrosine hydroxylase-immunoreactive cell bodies and dendrites. In the ferret where the choline acetyltransferase immunostaining was particularly strong, bundles of immunoreactive fibres were seen to run through the reticulata perpendicular to the pars compacta. These bundles were associated with tyrosine hydroxylase-immunoreactive dendrites that descended into the reticulata. The choline acetyltransferase-immunoreactive fibres made "climbing fibre"-type multiple contacts with the tyrosine hydroxylase positive dendrites. At the electron microscopic level the choline acetyltransferase-immunoreactive axons were seen to give rise to vesicle-filled boutons that formed asymmetrical synaptic specializations with nigral dendrites and perikarya. The synapses were often associated with sub-junctional dense bodies. On many occasions the postsynaptic structures contained the tyrosine hydroxylase immunoreaction product, thus identifying them as dopaminergic. It is concluded that at least one of the synaptic targets of cholinergic terminals in the substantia nigra are the dendrites and perikarya of dopaminergic neurons and that in the ferret at least, the dendrites of dopaminergic neurons that descend into the pars reticulata receive multiple synaptic inputs from individual cholinergic axons.     

The cholinergic innervation of normal and transplanted superior colliculus in the rat: an immunohistochemical study

The distribution of choline acetyltransferase was determined in normal and transplanted rat superior colliculus with choline acetyltransferase immunohistochemistry. This distribution was compared to the pattern of histochemically detected acetylcholinesterase activity. To determine cholinergic input to the superficial superior colliculus, double labelling experiments combining retrograde tracing methods and choline acetyltransferase immunohistochemistry were carried out. No choline acetyltransferase-containing neurons were observed in the rat superior colliculus. A dense network of choline acetyltransferase-immunoreactive fibres and terminals was seen in the intermediate layers of the normal superior colliculus. The distribution was patchy and very similar to the pattern of acetylcholinesterase activity. Occasional fibres and terminals were seen in the deep tectal laminae. The superficial layers contained a low number of choline acetyltransferase-stained fibres and terminals but a comparatively high level of acetylcholinesterase activity. Following a unilateral injection of a tracer into the superficial superior colliculus, retrogradely labelled choline acetyltransferase-immunoreactive neurons were found in the dorsal and ventral subnuclei of the ipsilateral parabigeminal nucleus. As in the normal superior colliculus, choline acetyltransferase-positive neurons were not found in tectal transplants. However, choline acetyltransferase-immunoreactive fibres and terminals were seen in grafts but only in those which had extensive connections with the host midbrain. The pattern of staining most closely resembled that seen in the intermediate layers of the normal superior colliculus. The similar arrangement of choline acetyltransferase and acetylcholinesterase activity in the intermediate layers of normal rat superior colliculus provides further evidence for cholinergic innervation to these layers, probably originating in the dorsal and pedunculopontine tegmental nuclei. The data from the double labelling experiments indicate that the choline acetyltransferase-immunoreactive terminals observed in the superficial layers represent the terminal field of an ipsilateral cholinergic projection from the parabigeminal nucleus. Tectal grafts receive cholinergic innervation from the host. The evidence suggests that much of this input derives from the cholinergic nuclei in the brainstem tegmentum which normally project to the intermediate tectal layers.     

Leukaemia inhibitory factor prevents loss of p75-nerve growth factor receptor immunoreactivity in medial septal neurons following fimbria-fornix lesions.

Transection of the fimbria-fornix leads to retrograde degeneration of axotomized septal cholinergic neurons as manifested by loss of choline acetyltransferase and low-affinity nerve growth factor receptor (p75NGFR) immunoreactivity. Nerve growth factor administered into cerebral ventricles at the time of axotomy can prevent these changes, while ciliary neurotrophic factor can prevent the loss of p75NGFR immunostaining. Leukaemia inhibitory factor shares structural homologies with ciliary neurotrophic factor and has similar actions in the nervous system. Both proteins share the same signalling pathways, which involve the interleukin-6 transducing receptor components leukaemia inhibitory factor receptor beta and gp130. In this study, we compared the effects of leukaemia inhibitory factor, ciliary neurotrophic factor and nerve growth factor, administered into cerebral ventricles, on p75NGFR and choline acetyltransferase immunoreactivity in septal neurons after fimbria-fornix transection. We found that leukaemia inhibitory factor, like ciliary neurotrophic factor, prevents the loss of p75NGFR-stained medial septal neurons after fimbria-fornix axotomy, without maintaining choline acetyltransferase expression in these neurons. In addition, p75NGFR-immunostained neurons had significantly smaller mean diameter after axotomy in leukaemia inhibitory factor- and ciliary neurotrophic factor-treated animals as compared with either nerve growth factor-treated or unlesioned animals. These findings suggest that both leukaemia inhibitory factor and ciliary neurotrophic factor can prevent the axotomy-induced cell death of septal cholinergic neurons, but that, in contrast to nerve growth factor, these growth factors do not maintain the expression of choline acetyltransferase or the normal neuronal size of these injured neurons.     

Neuronal ultrastructure and somatostatin immunolocalization in the ciliary ganglion of chicken and quail

Summary Ciliary and choroid neurons of the avian ciliary ganglion innervate different targets in the eye bulb. By light microscopic immunocytochemistry, somatostatin (SOM) has been localized to a subset of ganglionic neurons believed to be, for the most part, choroid neurons. Although several studies have been published on the physiology, afferent and efferent innervation, and response to experimental injury of this population of cells, their morphological features are still unclear. This has led us to perform a fine structural and immunocytochemical study on the ciliary ganglia of adult chickens and quails to provide the first thorough characterization of the choroid neurons and to analyze whether or not they can be unequivocally identified by expression of SOM. Here, we show that standard and immuno-electron microscopy provide firm criteria for the distinction of ciliary and choroid neurons, whose populations overlap in cell size and territory of distribution. The satellite cell sheaths form compact myelin lamellae around ciliary neurons and flattened processes around choroid neurons. Moreover, ciliary neurons are innervated by a larger number of boutons than choroid neurons. Chicken ciliary neurons are invested by boutons only over one pole of the cell body, while their quail counterparts have an almost complete shell of presynaptic boutons over the entire cell body. Ciliary neurons form mixed synaptic junctions (chemical and electrical), while choroid neurons form only chemical synapses. Crest synapses are present in ciliary neurons of both species. Nematosomes occur in both ciliary and choroid neurons. Choroid neurons contain a larger complement of large dense core vesicles than ciliary neurons and their Golgi apparatuses are more prominent. In the light microscope, somatostatin-immunostaining appears noticeably different in the two species: mostly granular in the chicken and skein-shaped in the quail. Immuno-electron microscopy reveals that somatostatin-like immunoreactivity is localized to Golgi apparatus and large dense core vesicles. Somatostatin is expressed by all the choroid neurons, but not by the ciliary neurons. This neuropeptide is, therefore, a true cell population marker.     

Cholinergic and non-cholinergic septohippocampal pathways

Cholinergic innervation of the hippocampus was examined in the rat by immunocytochemical localization of choline acetyltransferase immunoreactivity combined with retrograde transport of horseradish peroxidase-conjugated wheatgerm agglutinin. It was found that at least 50% of hippocampal afferents arising in the septal-diagonal band region consisted of non-cholinergic projection neurons. In addition, scattered choline acetyltransferase-immunoreactive neurons were localized to the hippocampal formation. These results indicate that: (1) the septohippocampal pathway is neither uniformly nor predominantly cholinergic; and (2) confirm that cholinergic innervation of the hippocampal formation of the rat is derived in part from intrinsic neurons.     

Input from the frontal cortex and the parafascicular nucleus to cholinergic interneurons in the dorsal striatum of the rat.

Evidence derived from many experimental approaches indicates that cholinergic neurons in the dorsal striatum (caudate-putamen) are responsive to excitatory amino acids. Furthermore, evidence from physiological experiments indicate that the excitatory input is derived from the cortex and/or the thalamus. The object of the present experiment was to anatomically test whether cholinergic neurons receive cortical and/or thalamic input in the dorsal striatum using a combined anteograde tracing and immunocytochemical approach at both the light- and electron-microscopic levels. Rats received injections of the anterograde tracers Phaseolus vulgaris-leucoagglutinin or biocytin at multiple sites in the frontal cortex or parafascicular nucleus of the thalamus. Sections of the striatum were stained to reveal the anterogradely transported markers and then immunostained to reveal choline acetyltransferase immunoreactivity. The striata of these animals contained dense networks of anterogradely labelled fibres that were dispersed throughout the neuropil and interspersed with the choline acetyltransferase-immunoreactive (i.e. cholinergic) perikarya and dendrites. The anterogradely labelled fibres were often closely apposed to the choline acetyltransferase-immunoreactive neurons. Examination of electron-microscopic sections failed to demonstrate cortical terminals in synaptic contact with the cholinergic neurons even when choline acetyltransferase-immunoreactive structures were examined that had first been identified in the light microscope as having cortical terminals closely apposed to them. In these cases it was often observed that the cortical terminal, although apposed to the membrane of the labelled neurone, made synaptic contact with an unlabelled spine that was in the vicinity. In contrast to the cortical input, analysis of material that was double-stained to reveal thalamostriatal terminals and choline acetyltransferase-immunoreactive structures, revealed that the thalamostriatal terminals were often in asymmetrical synaptic contact with the perikarya and dendrites of cholinergic neurons. It is concluded that the cholinergic neurons of the dorsal striatum, like those of the ventral striatum or nucleus accumbens [Meredith and Wouterlood (1990) J. comp. Neurol. 296, 204-221] receive very little or no input from the cortex but are under a prominent synaptic control by the thalamostriatal system. Those pharmacological effects of excitatory amino acids on the cholinergic systems of the striatum are therefore presumably related to the thalamostriatal and not the corticostriatal system.     

Choline acetyltransferase-immunoreactive neurons in the rat entopeduncular nucleus.

Using a monoclonal antibody against choline acetyltransferase, neurons of the rat entopenduncular nucleus were found to express choline acetyltransferase immunoreactivity. These cholinergic cells were located mostly in the rostral portion of the entopeduncular nucleus with a marked decrease towards its caudal portion. To identify their target sites, a retrograde fiber tracing technique was combined with immunohistochemistry for choline acetyltransferase. After injection of wheatgerm agglutinin conjugated with horseradish peroxidase into the habenula, some of the entopedunculo-habenular cells were found to be immunoreactive for choline acetyltransferase. The cells in the peripallidal region (the substantia innominata, nucleus basalis magnocellularis and ansa lenticularis) with choline acetyltransferase immunoreactivity did not contain horseradish peroxidase. Following injection of fluorescent tracer into the frontal cerebral cortex, retrogradely labeled cells were observed in the rostral part of the entopedunucular nucleus. A majority of these entopedunculo-cortical cells exhibited choline acetyltransferase immunoreactivity, similar to the cells of the peripallidal region projecting to the neocortex. Employing two different fluorescent tracers, entopedunculo-cortical cells were shown to constitute a distinct cell population from the numerous entopedunculo-habenular cells. The present study demonstrated, in the rat entopeduncular nucleus, the presence of cholinergic neurons that projected to the neocortex and habenula.     

The distribution and compartmental organization of the cholinergic neurons in nucleus accumbens of the rat

In this study the distribution of the cholinergic neurons was examined in relation to the compartmental organization of nucleus accumbens. This was accomplished by charting the location of the choline acetyltransferase-immunoreactive neurons and mapping their distribution in relation to cytoarchitectural features and the patterns of acetylcholinesterase activity and enkephalin immunoreactivity. Choline acetyltransferase-containing perikarya are inhomogeneously distributed in nucleus accumbens. Their density is lowest at the rostral pole and highest, caudomedially, at the septal pole. The cells form a compact, medial column and a diffuse, lateral zone and, moreover, there are distinct gradients in their distribution. The highest numbers of immunoreactive perikarya occur within the intensely immunostained zones of choline acetyltransferase-immunoreactive neuropil in ventral and ventromedial parts of the nucleus, whereas lower numbers coincide with choline acetyltransferase-poor zones in the central part of the nucleus. Zones of intensely choline acetyltransferase-immunoreactive neuropil are largely in register with regions of high acetylcholinesterase activity in middle and caudal parts of the nucleus but do not coincide rostrally. Choline acetyltransferase-rich zones correspond to moderate enkephalin immunoreactivity in the outer shell of the nucleus, but a moderately choline acetyltransferase-immunostained matrix surrounds "patches" of intense enkephalin immunoreactivity in the core. Small aggregates of cells, which feature commonly in nucleus accumbens, seem to be avoided by both choline acetyltransferase- and enkephalin-immunoreactive zones. Choline acetyltransferase-immunoreactive processes are mostly confined by the boundaries of their respective immunoreactive zones. Few choline acetyltransferase-immunoreactive neurons lie in the enkephalin-rich patches and those that lie close to the patches show little preference in the directionality of their processes such that some cross the borders, whereas others do not. Thus, our findings show that the cholinergic elements are differentially distributed within nucleus accumbens; that these elements are compartmentally ordered; and that, in light of their limited access to other compartments, they possibly play only a minor role in intercompartmental communication.     

Atlas of cholinergic neurons in the forebrain and upper brainstem of the macaque based on monoclonal choline acetyltransferase immunohistochemistry and acetylcholinesterase histochemistry

Choline acetyltransferase immunohistochemistry was used to map the cholinergic cell bodies in the forebrain and upper brainstem of the macaque brain. Neurons with choline acetyltransferase-like immunoreactivity were seen in the striatal complex, in the septal area, in the diagonal band region, in the substantia innominata, in the medial habenula, in the pontomecencephalic tegmentum and in the oculomotor and trochlear nuclei. The ventral striatum contained a higher density of cholinergic cell bodies than the dorsal striatum. All of the structures that contained the choline acetyltransferase positive neurons also had acetylcholinesterase-rich neurons. Choline acetyltransferase positive neurons were not encountered in the cortex. Some perikarya in the midline, intralaminar, reticular and limbic thalamic nuclei as well as in the hypothalamus were rich in acetylcholinesterase but did not give a positive choline acetyltransferase reaction. A similar dissociation was observed in the substantia nigra, the raphe nuclei and the nucleus locus coeruleus where acetylcholinesterase-rich neurons appeared to lack perikaryal choline acetyltransferase activity.     

Serotonergic input to cholinergic neurons in the substantia innominata and nucleus basalis magnocellularis in the rat.

The aim of the present study was to determine, at the light microscopic level, whether the serotonergic fibers originating from the dorsal raphe nucleus (B7), median raphe nucleus (B8) and ventral tegmentum (B9) make putative synaptic contacts with cholinergic neurons of the nucleus basalis magnocellularis and substantia innominata. For this purpose, we utilized: (i) the anterograde transport of Phaseolus vulgaris leucoagglutinin combined with choline acetyltransferase immunohistochemistry; (ii) choline acetyltransferase/tryptophan hydroxylase double immunohistochemistry; and (iii) the FluoroGold retrograde tracer technique combined with tryptophan hydroxylase immunohistochemistry. Following iontophoretic injections of Phaseolus vulgaris leucoagglutinin in the dorsal raphe nucleus, labeling was observed primarily in the ventral aspects of the nucleus basalis magnocellularis and in the intermediate region of the substantia innominata. When Phaseolus vulgaris leucoagglutinin was combined with choline acetyltransferase immunohistochemistry, a close association between the Phaseolus vulgaris leucoagglutinin-positive fibers and cholinergic neurons was observed, even though the majority of the Phaseolus vulgaris leucoagglutinin-immunoreactive terminals seemed to establish contact with non-cholinergic elements. Following Phaseolus vulgaris leucoagglutinin injection in the median raphe nucleus, very few labeled fibers with no evident close contact with nucleus basalis magnocellularis and substantia innominata cholinergic neurons were observed. After tryptophan hydroxylase/choline acetyltransferase double immunohistochemistry, a plexus of serotonergic (tryptophan hydroxylase-positive) fibers in the vicinity of choline acetyltransferase-immunoreactive neurons of the substantia innominata and nucleus basalis magnocellularis was observed, and some serotonergic terminals have been shown to come into very close contact with the cholinergic cells. Most of the tryptophan hydroxylase-immunoreactive terminals seem to establish contacts with non-cholinergic cells. Following FluoroGold injection in the nucleus basalis magnocellularis and substantia innominata, the majority of retrogradely labeled neurons was observed mainly in the ventromedial cell group of the dorsal raphe nucleus. In this area, a minority of the FluoroGold-positive neurons was tryptophan hydroxylase immunoreactive. These findings show that serotonergic terminals, identified in very close association with the cholinergic neurons in the substantia innominata and nucleus basalis magnocellularis, derive primarily from the B7 serotonergic cell group of the dorsal raphe nucleus, and provide the neuroanatomical evidence for a direct functional interaction between these two neurotransmitter systems in the basal forebrain.     

Urocortin 1-containing neurons in the human Edinger-Westphal nucleus

The topographical location of neurons containing urocortin 1, a peptide related to corticotropin-releasing factor was investigated in human postmortem brain by immunohistochemistry, and compared with the location of neurons containing choline acetyltransferase, a marker for cholinergic cells. A three-dimensional computer reconstruction of the urocortin 1 and choline acetyltransferase-positive population of neurons within the oculomotor area was made. It was shown that the urocortin 1-positive neurons are located within the area identified as the Edinger-Westphal nucleus according to the human brain stem atlas, and that the neurons identified as Edinger-Westphal nucleus in the atlas are not choline acetyltransferase-positive. This finding agrees with recent animal studies showing that urocortin 1-positive neurons are not identical with the parasympathetic cholinergic neurons projecting to the ciliary ganglion. They indicate that the neurons identified as Edinger-Westphal nucleus in the human brain stem atlas belong to the non-preganglionic Edinger-Westphal nucleus, whereas the location of preganglionic Edinger-Westphal nucleus remains unidentified.     

Topographical localization of neurons containing parvalbumin and choline acetyltransferase in the medial septum-diagonal band region of the rat

The normal morphology and distribution of parvalbumin-containing neurons (shown in a previous study to be GABAergic nerve cells) of the medial septal-diagonal band region of the adult rat brain have been studied, and the findings compared with observations on choline acetyltransferase-immunoreactive neurons. The two antigens were visualized either in the same sections using a double-label immunohistochemical procedure for the simultaneous localization of parvalbumin and choline acetyltransferase, or in immediately adjacent sections. In double-stained sections of the whole medial septal-diagonal band complex, about 34% of the total neurons showed immunoreactivity to parvalbumin; the proportion of parvalbumin-labelled neurons was slightly higher in the medial septal-vertical limb of the diagonal band region, and much lower in the horizontal limb of the diagonal band region. The distribution of parvalbumin- and choline acetyltransferase-containing neurons also varied markedly between different mediolateral subdivisions of the medial septum: about 30, 65 and 2% of the parvalbumin-immunoreactive neurons were present in the midline, medial and lateral part of the medial septum, respectively. At different rostrocaudal levels, the proportion of parvalbumin- and choline acetyltransferase-positive neurons varied in a consistent manner, and the largest number of parvalbumin-containing neurons was found at the level 1.9 mm anterior to the bregma. In the absence of reliable immunocytochemical methods for the localization of glutamate decarboxylase and GABA, parvalbumin may serve as a good marker for studying the distribution of GABAergic neurons in the medial septum-diagonal band region. Moreover, the precise maps reported in the present study of the topographic localization of parvalbumin-containing GABAergic and choline acetyltransferase-immunoreactive cholinergic nerve cells in the medial septal-diagonal band complex will serve as a useful guide in future morphological and electrophysiological studies on the septum and its efferents.     

BK-Type K(Ca) channels in two parasympathetic cell types: differences in kinetic properties and developmental expression

The intrinsic electrical properties of identified choroid and ciliary neurons of the chick ciliary ganglion were examined by patch-clamp recording methods. These neurons are derived from a common pool of mesencephalic neural crest precursor cells but innervate different target tissues and have markedly different action potential waveforms and intrinsic patterns of repetitive spike discharge. Therefore it is important to determine whether these cell types express different types of plasma membrane ionic channels, and to ascertain the developmental stages at which these cell types begin to diverge. This study has focused on large-conductance Ca(2+)-activated K(+) channels (K(Ca)), which are known to regulate spike waveform and repetitive firing in many cell types. Both ciliary ganglion cell types, identified on the basis of size and somatostatin immunoreactivity, express a robust macroscopic K(Ca) carried by a kinetically homogeneous population of large-conductance (BK-type) K(Ca) channels. However, the kinetic properties of these channels are different in the two cell types. Steady-state fluctuation analyses of macroscopic K(Ca) produced power spectra that could be fitted with a single Lorentzian curve in both cell types. However, the resulting corner frequency was significantly lower in choroid neurons than in ciliary neurons, suggesting that the underlying K(Ca) channels have a longer mean open-time in choroid neurons. Consistent with fluctuation analyses, significantly slower gating of K(Ca) channels in choroid neurons was also observed during macroscopic activation and deactivation at membrane potentials positive to -30 mV. Differences in the kinetic properties of K(Ca) channels could also be observed directly in single-channel recordings from identified embryonic day 13 choroid and ciliary neurons. The mean open-time of large-conductance K(Ca) channels was significantly greater in choroid neurons than in ciliary neurons in excised inside-out patches. The developmental expression of functional K(Ca) channels appears to be regulated differently in the two cell types. Although both cell types acquire functional K(Ca) at the same developmental stages (embryonic days 9-13), functional expression of these channels in ciliary neurons requires target-derived trophic factors. In contrast, expression of functional K(Ca) channels proceeds normally in choroid neurons developing in vitro in the absence of target-derived trophic factors. Consistent with this, extracts of ciliary neuron target tissues (striated muscle of the iris/ciliary body) contain K(Ca) stimulatory activity. However, K(Ca) stimulatory activity cannot be detected in extracts of the smooth muscle targets of choroid neurons.     

Analysis of quantal content and quantal conductance in two populations of neurons in the avian ciliary ganglion

The avian ciliary ganglion contains two populations of parasympathetic cells, termed the ciliary and choroid neurons. We have estimated the quantal contents of nicotinic excitatory postsynaptic potentials in both populations of neurons by several methods. The singly innervated ciliary neurons have quantal contents of 15–30. In contrast, the multiply innervated choroid cells have quantal contents of 4–7. Quantal conductance was also determined, using a parallel conductance model which takes into account the capacitance of the cell membrane. This analysis indicates that in both populations of neurons one quantum activates approximately 100 postsynaptic receptors.

It is concluded that in autonomie ganglia singly innervated cells demonstrate a larger quantal content, consistent with a higher safety factor for neurotransmission, while quantal content in multiply innervated cells is generally much lower, allowing for considerable summation of presynaptic inputs. Further, in autonomic neurons many fewer postsynaptic receptors are activated by a single quantum than is the case at the neuromuscular junction.     

Dissociable effects on spatial maze and passive avoidance acquisition and retention following AMPA- and ibotenic acid-induced excitotoxic lesions of the basal forebrain in rats: differential dependence on cholinergic neuronal loss

Excitotoxic lesions of the basal forebrain were made by infusing either alpha-amino-3-hydroxy-5-methyl-4-isoxazole propionic acid (AMPA) or ibotenic acid. Acquisition and performance of spatial learning in the Morris water maze, over a ten day, two trials per day, training regimen were unaffected by the AMPA-induced lesions which reduced cortical choline acetyltransferase activity by 70%. However, acquisition was significantly impaired in rats with ibotenic acid-induced lesions that reduced cortical choline acetyltransferase by 50%. Additionally, ibotenic acid-lesioned rats swam further than either sham or AMPA-lesioned rats, in the "training" quadrant during a probe trial, in which the escape platform was removed, suggesting a perseverative search strategy. Lesions induced with AMPA, but not ibotenate, significantly impaired the acquisition of "step-through" passive avoidance. Both AMPA- and ibotenate-induced lesions significantly impaired the 96 h retention of passive avoidance, but the effect of AMPA was greater on latency measures. Histological analysis revealed that AMPA infusions destroyed more choline acetyltransferase-immunoreactive neurons than did ibotenate infusions but, unlike ibotenate, spared the overlying dorsal pallidum and also parvocellular, non-choline acetyltransferase-immunoreactive neurons in the ventral pallidal/substantia innominata region of the basal forebrain. The impairment in acquisition of the water maze following ibotenate-induced basal forebrain lesions therefore appears unrelated to damage to cholinergic neurons of the nucleus basalis of Meynert and to depend instead on damage to pallidal and other neurons in this area. The AMPA- and perhaps also the ibotenate-induced impairment in the retention of passive avoidance appears to be more directly related to destruction of cholinergic neurons of the nucleus basalis. These data are discussed in the context of cortical cholinergic involvement in mnemonic processes.