Topography of choline acetyltransferase-containing neurons in the forebrain of the rat

Age-related loss of nerve growth factor sensitivity in rat basal forebrain neurons

Nerve growth factor (NGF) has recently been implicated as a trophic agent in the survival and maintenance of basal forebrain cholinergic neurons. To test the hypothesis that NGF may play a role in the age-related degeneration of basal forebrain neurons and decline of cerebral cholinergic function, we have used a monoclonal antibody to the NGF receptor, 192 IgG, to immunocytochemically visualize and compare rat basal forebrain neurons responsive to NGF in aged (30 months) and young adult (10 months) rats. In a subpopulation of aged rats, NGF receptor-immunoreactive cells in the basal forebrain appear vacuolated and shrunken, and the neuropil staining is markedly reduced. While no substantial decline in cell density is apparent in Nissl-stained sections, the number of NGF receptor-positive cell profiles within the vertical limb of diagonal band nuclei is reduced by an average of 32% in aged rats. Marked reduction in the expression of NGF receptors in aged rats may signify loss of capacity of the basal forebrain neurons to bind and transport NGF from their terminals in the hippocampus and cortex, subsequent decrease in NGF delivered to the cell bodies, and eventual cellular dysfunction and death of neurons in aging.

Immunohistochemical localization of beta-nerve growth factor receptors in the forebrain of the rat

Using a monoclonal antibody (192-IgG) directed against the rat beta-nerve growth factor (beta-NGF) receptor the distribution of beta-NGF receptors in the forebrain of the rat has been determined. beta-NGF receptor-containing cells were located in presumed cholinergic cells of the medial septal nucleus, vertical and horizontal limbs of the diagonal band of Broca and the nucleus basalis of Meynert.

Observations on choline acetyltransferase containing structures in the CD-1 mouse brain

Central cholinergic structures within the CD-1 mouse were evaluated by immunohistochemical visualization of choline acetyltransferase (ChAT) using the monoclonal antibody AB8. Rostrally, cholinergic neurons were seen within the neostriatum, medial septal nucleus (Ch1), ventral (Ch2) and horizontal (Ch3) limb nuclei and nucleus basalis-substantia innominata complex (Ch4). Caudally, cholinergic neurons were seen in the cuneiformis-pedunculopontine nuclei (Ch5), lateral dorsal tegmental (Ch6) and parabigeminal (Ch8) nuclei as well as the medial habenular nucleus and cranial motor nuclei. Additional cholinergic perikarya were found in the hippocampus and cerebral cortex. ChAT stained fibers were observed in the cerebral cortex and in many fiber fascicles.

Neurochemical effects following AF64A injection into the basal nuclei of rats

AF64A, a specific cholinergic neurotoxin, was injected into the basal nuclei of rats. The injected sites were the bilateral nucleus basalis of Meynert (NBM) and the medial septal nucleus (MSN), well known to be the nuclei of origin of the two major cholinergic pathways. The remote effects of injection were estimated by the regional choline acetyltransferase (CAT) activity in the frontal cortex, striatum and hippocampus. The injection of AF64A (1 nmol in 1 microliter) produced a reduction in the CAT activity in each projected site: NBM lesions in the frontal cortex and MSN lesions in the hippocampus after one and three weeks. Twelve weeks after the injection, the reduced CAT activity had returned to normal levels. This neurochemical effect shows plasticity and recovery with time. The injections of small amounts of AF64A (0.2 and 0.1 nmol in 1 microliter) produced no chemical changes after one week.

Nerve growth factor receptor-mediated transport from cerebrospinal fluid to basal forebrain neurons

Recent data indicate that the neurons of the cholinergic basal forebrain (CBF) respond to nerve growth factor (NGF) with increased survival under experimental conditions and have NGF receptors which mediate the binding and retrograde transport of NGF from axon terminals to somata. Focal intraparenchymal injections of retrograde tracing agents into neuropil demonstrate that the distribution of axons from cholinergic nuclei to cortex and hippocampus is topographically restricted and largely ipsilateral. Monoclonal antibody 192, a well-characterized antibody which recognizes only the rat NGF receptor, was labelled with 125I and injected into a lateral ventricle of adult rats. Highly specific bilateral transport to numerous neurons of the CBF system was demonstrated by autoradiography. This result directly demonstrates that suitably targeted antibodies can be taken up by specific neuronal populations following intraventricular injection and implies that CBF neurons may be influenced by relatively high molecular weight substances injected into cerebrospinal fluid.

Accumulation of circulating endogenous and exogenous immunoglobulins by hypothalamic magnocellular neurons

Rat monoclonal antibodies, used in immunocytochemistry of normal rat brain, result in a granular reaction product within neurons innervating areas lacking a blood-brain barrier. Immunocytochemical characterization shows that the staining is independent of the primary antibody and exclusively dependent on the presence of anti-rat immunoglobulin. This granular staining could be selectively eliminated by pre-adsorption of the anti-rat immunoglobulin with purified rat immunoglobulin or disruption of microtubule retrograde transport systems by intraventricular injection of colchicine. A dependence on retrograde transport and complete independence from local synthesis was further substantiated by the rapid uptake and accumulation of intravenously administered rabbit or rat [125I]immunoglobulins by the supraoptic-neurohypophysial system. Immunoelectron microscopy was used to identify the endogenous rat immunoglobulin within lysosome-like organelles in the cytoplasm of magnocellular neuroendocrine cells. The uptake and incorporation of plasma macromolecules into the lysosomal system of magnocellular and other neurons projecting to regions with a weak blood-brain barrier may represent a novel mode of blood-central nervous system interactions.

Distribution of nicotinic binding sites with respect to CRF and neurophysin immunoreactive perikarya within the rat hypothalamus

These studies determined the differential autoradiographic distribution of [125I]alpha-bungarotoxin versus [3H]nicotine relative to the histochemically defined perikarya for neurophysin and corticotropin releasing factor (CRF). Specific [3H]nicotine binding sites occurred in relatively greater density within the neuropil surrounding PVN and SON compared to within the nuclei. In contrast, the highest density of [125I]alpha-BTX sites codistributed with neurophysin immunoreactive perikarya within these nuclei.

Characteristics of memory impairment following lesioning of the basal forebrain and medial septal nucleus in rats

Memory impairment in rats with lesions of the basal forebrain (BF) and medial septal nucleus (MS) including cell bodies of the cortical and septohippocampal cholinergic systems, respectively, were compared in order to evaluate the functional contribution of the two cholinergic systems to memory. Biochemical assay revealed that lesioning of the BF and MS resulted in marked and selective decreases in both choline acetyltransferase and acetylcholinesterase activities in the cerebral cortex and hippocampus, respectively. Rats with BF lesions exhibited a severe deficit in a passive avoidance task; acquisition of passive avoidance by repeated training was sluggish, and the acquired response was rapidly eliminated in a subsequent extinction test. However, only slight impairment of passive avoidance was observed in rats with MS lesions. Memory impairment in rats with BF or MS lesions was also investigated using two spatial localization tasks, the Morris water task and the 8-arm radial maze task. Both BF and MS lesions elicited a significant impairment in the Morris water task that required reference memory, as demonstrated by an apparent increase in the latency to escape onto a hidden platform in a large water tank. The impairment was much more obvious in the BF-lesioned rats. In contrast, in the radial maze task primarily requiring working memory, rats with lesions of the MS showed severe disruption, exhibiting a marked increase in total errors, a decrease in the number of initial correct responses, and an apparent change in the strategy pattern. However, corresponding changes in the rats with BF lesions were slight. These results suggest that BF lesions may lead to substantial long-term memory impairment while MS lesions may primarily produce short-term or working memory impairment, indicating a qualitatively different contribution of the two cholinergic systems to memory. It is also suggested that these two experimental animal models may be useful for evaluation of therapeutic drugs for senile dementia of the Alzheimer type.

Comparative distribution of mRNAs for glutamic acid decarboxylase, tyrosine hydroxylase, and tachykinins in the basal ganglia: an in situ hybridization study in the rodent brain

Neurotransmitter-related messenger RNAs were detected by in situ hybridization in sections of rat and mouse brains by using 35S-radiolabelled RNA probes transcribed from cDNAs cloned in SP6 promoter-containing vectors. The distribution of messenger RNAs for glutamic acid decarboxylase, tachykinins (substance P and K), and tyrosine hydroxylase was examined in the striatum, pallidum, and substantia nigra. Dense clusters of silver grains were observed with the RNA probe complementary of the cellular messenger RNA for glutamic acid decarboxylase (antisense RNA) over most large neurons in the substantia nigra pars reticulata and medium-sized to large neurons in all pallidal subdivisions. A few very densely and numerous lightly labelled medium-sized neurons were present in the striatum. Among the areas examined, only the striatum contained neurons labelled with the antisense tachykinin RNA. Most of these neurons were of medium size, and a few were large. With the antisense tyrosine hydroxylase RNA, silver grains were found over neurons of the substantia nigra pars compacta and adjacent A10 and A8 dopaminergic cell groups. No signal was observed with RNAs identical to the cellular messenger RNA for glutamic acid decarboxylase or tachykinin (sense RNA). These results show a good correlation with immunohistochemical studies, suggesting that documented differences in the distribution and the level of glutamic acid decarboxylase, tyrosine hydroxylase, and substance P immunoreactivities in neurons of the basal ganglia are related to differences in the level of expression of the corresponding genes rather than to translation accessibility, stability, or transport of the gene products.

Transient expression of choline acetyltransferase-like immunoreactivity in Purkinje cells of the developing rat cerebellum

The expression of choline acetyltransferase (ChAT)-like immunoreactivity was studied immunohistochemically in the cerebelli of developing rats. Brains were examined from the day of birth (postnatal day 1: P1) until adulthood. From P4 through P21, several Purkinje cells in the uvula, nodule, and flocculus of the cerebellum demonstrated ChAT-like immunoreactivity. After P23, no ChAT-positive neurons were observed in any region of the cerebellum. This finding paralleled the transient expression of acetylcholinesterase in Purkinje cells of these same cerebellar areas during development.

A topographical analysis of the origin of some efferent projections from the lateral hypothalamic area in the rat

Some projections from the lateral hypothalamic area in the rat have been investigated, using combinations of fluorescent tracers, injected into several different parts of the central nervous system. Projections appear to arise from loosely organized assemblies of neurons, called sets and from more densely packed assemblies, called clusters. The sets and clusters vary considerably in position and in distinctness of their borderlines. Even within extensive and vaguely defined sets, however, high concentrations of labeled neurons may be present at specified sites in the lateral hypothalamus. Such concentrations are observed in the transitional area of the zona incerta and the dorsal part of the lateral hypothalamus, and in the ventrolateral part of the hypothalamus, bordering the cerebral peduncle and the subthalamic nucleus, in both cases after injections into some "autonomic centers" in the brainstem, such as the parabrachial nuclei and the dorsal vagal complex. Sets and clusters may overlap considerably. Within the fields of overlap the number of double labeled neurons may vary from almost zero up to more than 50%, depending on the injection sites. The results show that different parts of the lateral hypothalamus in the rat have different efferent relationships. Combination of the results of the present study with known data concerning the afferent relationships, the cytoarchitecture and behavioral functions of the lateral hypothalamic area, suggests that different parts of this entity are involved in different regulatory and behavioral functions.

Effects of postnatal hypoxia-ischemia on cholinergic neurons in the developing rat forebrain: choline acetyltransferase immunocytochemistry

We studied the effect of early postnatal hypoxia-ischemia on cholinergic neurons in the developing rat forebrain using immunohistochemistry for choline acetyltransferase (ChAT). In 7-day-old rat pups, hypoxia-ischemia was induced in one cerebral hemisphere by combining unilateral carotid ligation with exposure to 8% oxygen for 2.5 h. This procedure caused brain injury in the hemisphere ipsilateral to ligation, most prominent in the corpus striatum, hippocampus and overlying cortex. In animals sacrificed 2-3 weeks after the insult, at approximately 3 weeks of age, the density of cholinergic cell bodies was slightly higher in the lesioned rostral caudate-putamen than the opposite side (+12%, P less than 0.05). In the more caudal portion of caudate-putamen, this effect was greater. In contrast, the size of the cholinergic perikarya in the injured striatum was significantly reduced. Cholinergic neurons in the septum (Ch1, Ch2), globus pallidus and nucleus basalis (Ch4) were relatively unaffected. Considered together with previously reported neurochemical data, these observations suggest that the immature cholinergic neurons are less vulnerable to death from hypoxia-ischemia than other components of the striatum. However, differentiation of surviving cholinergic perikarya and possibly their axonodendritic processes may be disrupted by the early insult.

Cortical projection patterns of magnocellular basal nucleus subdivisions as revealed by anterogradely transported Phaseolus vulgaris leucoagglutinin

The present paper deals with a detailed analysis of cortical projections from the magnocellular basal nucleus (MBN) and horizontal limb of the diagonal band of Broca (HDB) in the rat. The MBN and HDB were injected iontophoretically with the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L). After immunocytochemical visualization of labeled efferents, the distribution of projections over the cortical mantle, olfactory regions and amygdala were studied by light microscopy. Based on differences in cortical projection patterns, the MBN was subdivided in anterior, intermediate and posterior portions (MBNa, MBNi and MBNp). All subdivisions maintain neocortical projections and are subject to an anterior to posterior topographic arrangement. In the overall pattern, however, the frontal cortex is the chief target. Furthermore, all MBN parts project to various regions of meso- and allocortex, which are progressively more dense when the tracer injection is more anteriorly placed. The most conspicuous finding, however, was a ventrolateral to dorsomedial cortical projection pattern as the PHA-L injection site moved from posterior to anterior. Thus, the posterior MBN projects predominantly to lateral neo- and mesocortex while the anterior MBN sends more fibers to the medial cortical regions. Furthermore, the MBNa is a source of considerable afferent input to the olfactory nuclei and as such should be regarded as a transition to the HDB. The HDB, apart from projecting densely to olfactory bulb and related nuclei, maintains a substantial output to the medial prefrontal cortical regions and entorhinal cortex, as well. Comparison of young vs aged cases indicate that aging does not appear to have a profound influence on cortical innervation patterns, at least as studied with the PHA-L method.

A small proportion of cholinergic neurones in the nucleus basalis magnocellularis of ferret appear to stain positively for tyrosine hydroxylase

The immunofluorescence and peroxidase-antiperoxidase methods for immunohistochemistry were used to show that a small number of neurones in the nucleus basalis magnocellularis of ferret stain positively for what appears to be tyrosine hydroxylase, a marker for catecholaminergic neurones. With a double immunocytochemical staining method, it was confirmed that the tyrosine hydroxylase-like immunoreactivity is localized in neurones that also stain strongly for choline acetyltransferase.

The cholinergic nuclei of the basal forebrain of the rat: normal structure, development and experimentally induced degeneration

The normal morphology and distribution of the cholinergic neurones of the basal forebrain of the rat have been studied qualitatively and quantitatively after staining immunohistochemically with a monoclonal antibody to choline acetyl transferase (ChAT). This was done in order to provide an adequate control for the changes found in these cells on both sides of the brain in the experimental investigation of the reaction of the cells to damage of their axons. The cholinergic cells form a more or less continuous anteroposterior band, but they can be subdivided into distinct nuclear groups on the basis of the size and form of the cell bodies and dendrites, their position and arrangement. these nuclei conform closely to previous descriptions of Nissl-stained material: the medial septal nucleus, the vertical and horizontal nuclei of the diagonal band and the basal nucleus. Quantitative measurements of the cross-sectional areas of the cells in the different nuclei confirmed the conclusions drawn from the qualitative examination. Measurements of the ChAT cells at different ages showed that in all nuclei they are significantly larger in size in infancy than in the adult, and they shrink to the mature size by 46 days. The cells in the various cholinergic nuclei show distinctly different reactions to damage of their terminal axonal fields. After removal of a large part of the neocortex by removal of the overlying pia-arachnoid mater the cells in the basal nucleus in the operated hemisphere underwent retrograde cellular degeneration, being swollen and paler-staining up to 14 days, and thereafter shrinking by 20-30% (as compared with those in the brains of age- and sex-matched littermate controls). The degree of shrinkage was appreciably greater when the animals were operated upon at the neonate stage. No cell loss was found, qualitatively or quantitatively, in the basal nucleus. After removal of the hippocampus there is marked loss of cholinergic neurones in the medial septal nucleus and in the vertical nucleus of the diagonal band, and with severe shrinkage of the remaining cells. Removal of the olfactory bulb results in only slight shrinkage of the cells, and no cell loss, in the horizontal nucleus of the diagonal band.(ABSTRACT TRUNCATED AT 400 WORDS)

Topography of cholinergic and substance P pathways in the habenulo-interpeduncular system of the rat. An immunocytochemical and microchemical approach

The topography of cholinergic and substance P containing habenulo-interpeduncular projections has been studied in the rat. The research has been carried out by combining choline acetyltransferase and substance P immunohistochemistry to experimental lesions and biochemical assays in microdissected brain areas. In addition, computer-assisted image analysis has been performed in order to obtain quantification of immunohistochemical data. The results show that cholinergic and substance P containing neurons have a different localization in the medial habenula and project to essentially different areas of the interpeduncular nucleus. Cholinergic neurons are crowded in the ventral two-thirds of the medial habenula while substance P containing cells are exclusively localized in the dorsal part of the nucleus. In most parts of the interpeduncular nucleus, choline acetyltransferase and substance P containing fibres and terminals are similarly segregated and no overlapping is apparent except for the rostralmost and the caudalmost ends of the nucleus. Cholinergic activity is largely concentrated in the central core of the nucleus, while substance P is preferentially localized in the peripheral subnuclei of the interpeduncular nucleus. In addition, both substance P and choline acetyltransferase levels show peculiar regional variations along the rostrocaudal axis of the interpeduncular nucleus. The results of experimental lesions demonstrate that the substance P projection carried by each fasciculus retroflexus is prevailingly ipsilateral in the rostral part of the interpeduncular nucleus and becomes progressively bilateral as far as more caudal regions of the nucleus are reached. By contrast, the cholinergic projections carried by each fasciculus retroflexus intermingle more rapidly and only show a slight ipsilateral dominance in the interpeduncular nucleus. The results of the study are discussed with reference to previous anatomical and neurochemical data which, in several instances, had given rise to discrepant interpretations.

A search for choline acetyltransferase-like immunoreactivity in neurons of cat striate cortex

The goal of this study was to determine whether cat striate cortex contains neurons with choline acetyltransferase-like immunoreactivity. Two different monoclonal antibodies were applied with various fixation protocols. As controls served selected regions of the cat brain and the rat neocortex where cholinergic neurons had been demonstrated previously with independent methods. All experimental protocols labelled the presumptive cholinergic neurons in the central regions but revealed only a few weakly stained neurons in cat striate cortex. These had a non-pyramidal morphology and were scattered throughout all layers.

Distribution of cholinergic neurons and fibers in the hypothalamus of the rat using choline acetyltransferase as a marker

The distribution of choline-acetyltransferase-like immunoreactive structures in the rat hypothalamus and preoptic area was examined by using avidin-biotin immunocytochemistry. We found that the hypothalamus is richly innervated by the cholinergic neuron system. Sites containing cholinergic neurons of varying density were: medial and lateral preoptic areas, septohypothalamic nucleus, median preoptic area, lateral hypothalamus including the perifornical area, anterior hypothalamic nucleus, arcuate nucleus, dorsomedial hypothalamic nucleus, posterior hypothalamic nucleus, dorsal and ventral premammillary nuclei, neuropil mediodorsal to the anterior hypothalamic nucleus, neuropil ventral to the anterior hypothalamic nucleus and ventromedial hypothalamic nucleus, neuropil between lateral hypothalamus and ventromedial hypothalamus, and neuropil between dorsal premammillary nucleus and posterior hypothalamic nucleus. There were also many varicose and non-varicose fibers in the preoptic area and hypothalamus. Two kinds of varicose fibers, one with strong immunoreactivity and the other with weak immunoreactivity, were seen. Non-varicose fibers were also detected in the optic chiasma and habenulo-interpeduncular tract. These fibers were passing fibers.

The immunohistochemical localization of choline acetyltransferase in the cat brain

The distribution of neurons displaying choline acetyltransferase (ChAT) immunoreactivity was examined in the feline brain using a monoclonal antibody. Groups of ChAT-immunoreactive neurons were detected that have not been identified previously in the cat or in any other species. These included small, weakly stained cells found in the lateral hypothalamus, distinct from the magnocellular rostral column cholinergic neurons. Other small, lightly stained cells were also detected in the parabrachial nuclei, distinct from the caudal cholinergic column. Many small ChAT-positive cells were also found in the superficial layers of the superior colliculus. Other ChAT-immunoreactive neurons previously detected in rodent and primate, but not in cat, were observed in the present study. These included a dense cluster of cells in the medial habenula, together with outlying cells in the lateral habenula. Essentially all of the cells in the parabigeminal nucleus were found to be ChAT-positive. Additional ChAT-positive neurons were detected in the periolivary portion of the superior olivary complex, and scattered in the medullary reticular formation. In addition to these new observations, many of the cholinergic cell groups that have been previously identified in the cat as well as in rodent and primate brain such as motoneurons, striatal interneurons, the magnocellular rostral cholinergic column in the basal forebrain and the caudal cholinergic column in the midbrain and pontine tegmentum were confirmed. Together, these observations suggest that the feline central cholinergic system may be much more extensive than previous studies have indicated.

Isoperiodic bursting by magnocellular neuroendocrine cells in the rat hypothalamic slice

1. Recruitment of magnocellular neuroendocrine cells (m.n.c.s) to a repetitive burst pattern (phasic firing) is associated with increased vasopressin secretion from neurohypophysial terminals in the intact animal. Based on invertebrate studies, bursts of action potentials can arise in two distinct ways: as an intrinsic property of the recorded cell or as an emergent property of synaptic interactions. 2. The majority of phasic m.n.c.s in the hypothalamic slice preparation display an endogenous pace-maker mechanism underlying bursting. It is voltage dependent and varies considerably in periodicity and time course as described in the accompanying paper (Andrew, 1987). 3. In contrast to this intrinsic mechanism, the present study examined if cells might be driven by periodic synaptic input. Intracellular recordings from six of thirty-two phasic m.n.c.s in the supraoptic nucleus revealed an isoperiodic oscillation of the membrane potential, where each depolarizing phase could support a burst. 4. The oscillation had a smooth trajectory and fixed period (range, 5-17 s). The oscillatory frequency was not voltage dependent, i.e. periodicity was unaffected by steady current injection through the recording electrode. 5. The frequency and amplitude of the oscillation remained unaltered by action potential firing. The isoperiodic oscillation could abate spontaneously, leaving intact the endogenous ability to fire a triggered burst driven by an underlying plateau potential. 6. Perfusion with either 10 mM-Mg2+-0.05 mM-Ca2+ or 0.5-2.0 microM-tetrodotoxin blocked both the oscillation and evoked post-synaptic potentials, indicating that the oscillation was synaptically generated. Given that both treatments could also block the intrinsic burst process and that the oscillation could spontaneously abate, the synaptic nature of the oscillation remains a tentative but reasonable conclusion. 7. In total, the evidence suggests that the isoperiodic oscillation has a synaptic origin independent of intrinsic mechanisms. It probably results from synaptic input generated within the slice but the source is not yet identified. This input could support phasic bursting in those m.n.c.s lacking a pace-maker ability and so promote the release of vasopressin in the intact animal.

Quantitative autoradiography of dopamine D2 sites in rat caudate-putamen: localization to intrinsic neurons and not to neocortical afferents

Dopamine D2 receptors, labeled with [3H]spiroperidol or [3H]sulpiride, show a lateral-to-medial gradient in the caudate-putamen, with a more than two-fold greater density laterally than medially. It has been thought that D2 receptors are located on at least two neuronal elements of the caudate-putamen, neurons intrinsic to this structure and axons whose cell bodies reside in the cortex. As a first step in establishing what neuronal elements underlie this heterogeneous organization of D2 receptors, we took advantage of quantitative autoradiography to examine the association of these receptors with those elements. The present findings show that the D2 sites are almost exclusively located on neurons whose somata reside in the caudate-putamen and are not located on terminals of corticostriatal axons. A detailed comparison of the distribution of histochemically identified acetylcholinesterase neurons with that of D2 receptors in serially adjoining sections suggests a common organizational pattern. The density of [3H]spiroperidol sites in rat caudate-putamen was determined after unilateral injection of the neurotoxin quinolinic acid into this structure or after ablation of neocortical regions. Quantification of the tissue damage was achieved by acetylcholinesterase histochemistry (following diisopropylfluorophosphate treatment), as well as by thionin and luxol fast staining of sections adjacent to those used for [3H]spiroperidol autoradiography. In identically treated animals, biochemical determination of the extent of tissue damage was made utilizing assays for high-affinity [3H]choline and [3H]glutamate uptake in the caudate-putamen. In quinolinic acid-injected rats, the density of D2 sites was decreased by 90-95% at the site of complete loss of large acetylcholinesterase-positive neurons. Other animals, given ablations of specific neocortical fields (medial prefrontal, motor, somatosensory) or of the entire parietal-frontal cortex of one hemisphere, showed no loss of caudate-putamen D2 sites unless the cortical ablation caused accompanying damage of the caudate-putamen. In the caudate-putamen of all animals there was a close correspondence between the D2 sites and the striatal neurons (and processes) that show strong acetylcholinesterase reactivity. We suggest that the caudate-putamen topography of D2 sites is based largely on the internal organization of this structure and may preferentially involve acetylcholine-containing intrinsic neurons.

Striatal substance P cell clusters coincide with the high density terminal zones of the discontinuous nigrostriatal dopaminergic projection system in the cat: a study by combined immunohistochemistry and autoradiographic axon-tracing

A portion of the nigrostriatal projection that originates from presumably dopaminergic neurons in the caudal pars compacta of the substantia nigra and the suprajacent pars dorsalis (retrorubral area), was shown by [3H]amino acid autoradiographic tracing to distribute nonhomogeneously in the head of the caudate nucleus, such that zones of high density termination are in register with the archipelago of substance P cell clusters revealed immunohistochemically in the same and adjacent tissue sections of the cat's brain. Axons from this same portion of the substantia nigra distribute densely at caudal levels of the putamen where again substance P-immunoreactive striatal cells are numerous. In nearby tissue sections from the same cases, tyrosine hydroxylase-like immunoreactivity suggested only subtle variations in the density of the catecholamine axon network within the striatum. Thus, whereas dopamine axons are distributed densely throughout the striatum, those originating from cells in the caudal pars compacta et dorsalis of the substantia nigra and ending in the head of the caudate nucleus appear to terminate preferentially within the substance P cell clusters. These data suggest that the striatal substance P cells, which send their axons selectively to the entopeduncular nucleus and substantia nigra, but much less so the globus pallidus, are a major target of nigrostriatal dopamine transmission. This result is discussed with respect to the anatomical, neurochemical and functional organization of the striatifugal projection system.

An immunocytochemical study of choline acetyltransferase-containing neurons and axon terminals in normal and partially deafferented hippocampal formation

Monoclonal antibodies to the acetylcholine synthesizing enzyme, choline acetyltransferase (ChAT), have been used to study putative cholinergic structures in immunocytochemical preparations of normal rat hippocampal formation and of hippocampal formation deprived of its septal innervation. Small numbers of ChAT-positive (ChAT+) neuronal somata were observed scattered throughout the septotemporal extent of the normal hippocampal formation. They were most common in stratum lacunosum-moleculare of regio superior, but were also found in various layers of the dentate gyrus and occasionally in the remaining hippocampal laminae. In addition, light microscopy demonstrated that ChAT+ terminal fields in normal hippocampal formation were organized in discrete bands and laminae. Pronounced dense bands were observed: immediately superficial to stratum granulosum; deep to stratum pyramidale; and at the border between stratum radiatum and stratum lacunosum-moleculare. In the dentate gyrus, ChAT+ staining was pronounced in the hilus at temporal levels, but only moderate staining occurred in the anterior hilus and throughout the molecular layer. A close correspondence was observed in the density and distribution of ChAT+ immunoreactivity and acetylcholinesterase staining. Electrolytic lesions of the medial septal nucleus/diagonal band complex had no effect on the occurrence of ChAT+ somata, but virtually abolished the ChAT+ laminar staining pattern and eliminated all but occasional small patches of ChAT+ terminals. These results confirm that the vast majority of hippocampal cholinergic terminals originate either from neurons of the medial septum/diagonal band complex or from fibers of passage. The newly observed intrinsic hippocampal neurons can account for at least some of the ChAT activity remaining after septal lesions, and they apparently contribute to the cholinergic innervation of the hippocampal formation.

Synaptic organization of cholinergic neurons in the monkey neostriatum

Cholinergic neurons in the monkey neostriatum were examined at the light and electron microscopic level by immunohistochemical methods in order to localize choline acetyltransferase (ChAT), the synthesizing enzyme for acetylcholine. At the light microscopic level a sparse distribution of cholinergic neurons was identified throughout the caudate nucleus. Neurons had large (25-30 microns) somata, eccentric invaginated nuclei, primary dendrites of unequal diameters, and varicosities on distal dendritic branches. Ultrastructural study showed that the cholinergic cells had a cytoplasm abundant in organelles. Within dendritic branches, mitochondria and cisternae were localized primarily to varicosities. Synaptic inputs were distributed mostly to the dendrites and at least four types that formed symmetric or asymmetric synapses were observed. Immunoreactive fibers were relatively numerous within the neuropil and exhibited small diameters (0.1-0.15) micron) and swellings at frequent intervals. Cholinergic boutons that formed synapses were compared to unlabeled terminals making asymmetric synapses with dendritic spines. Results showed that ChAT-positive axons had significantly smaller cross-sectional areas, shorter synaptic junctions, and a higher density and surface area of mitochondria than the unlabeled boutons. Cholinergic axons formed symmetric synapses mostly with dendritic spines (53%) and the shafts of unlabeled primary and distal dendrites (37%). A relatively small proportion of the boutons contacted axon initial segments (1%) and cell bodies (9%) that included medium-sized neurons with unindented (spiny) and indented (aspiny) nuclei. The majority of dendritic spines contacted by cholinergic axons were also postsynaptic to unlabeled boutons forming asymmetric synapses. The results suggest that cholinergic neurons in the primary neostriatum belong to a single morphological class corresponding to the large aspiny (type II) interneuron identified in previous Golgi studies. Present results along with earlier Golgi-electron microscopic observations from this laboratory suggest that neostriatal cholinergic cells integrate many sources of intrinsic and extrinsic inputs. The observed convergence of ChAT-immunoreactive boutons and unlabeled axons onto the same dendritic spines suggests that intrinsic cholinergic axons modulate extrinsic inputs onto neostriatal spiny neurons at postsynaptic sites close to the site of afferent input.

Quantitative light microscopic autoradiographic localization of cholinergic muscarinic receptors in the human brain: forebrain

The distribution of muscarinic cholinergic receptors in the human forebrain and cerebellum was studied in detail by quantitative autoradiography using N-[3H]methylscopolamine as a ligand. Only postmortem tissue from patients free of neurological diseases was used in this study. The highest densities of muscarinic cholinergic receptors were found in the striatum, olfactory tubercle and tuberal nuclei of the hypothalamus. Intermediate to high densities were observed in the amygdala, hippocampal formation and cerebral cortex. In the thalamus muscarinic cholinergic receptors were heterogeneously distributed, with densities ranging from very low to intermediate or high. N-[3H]Methylscopolamine binding was low in the hypothalamus, globus pallidus and basal forebrain nuclei, and very low in the cerebellum and white matter tracts. The localization of the putative muscarinic cholinergic receptors subtypes M1 and M2 was analysed in parallel using carbachol and pirenzepine at a single concentration to partially inhibit N-[3H]methylscopolamine binding. Mixed populations of both subtypes were found in all regions. M1 sites were largely predominant in the basal ganglia, amygdala and hippocampus, and constituted the majority of muscarinic cholinergic receptors in the cerebral cortex. M2 sites were preferentially localized in the diencephalon, basal forebrain and cerebellum. In some areas such as the striatum and substantia innominata there was a tendency to lower densities of muscarinic cholinergic receptors with increasing age. In general, we observed a slight decrease in M2 sites in elderly cases. Muscarinic cholinergic receptor concentrations seemed to be reduced following longer postmortem periods. The distribution of acetylcholinesterase was also studied using histochemical methods, and compared with the localization of muscarinic cholinergic receptors and other cholinergic markers. The correlation between the presence of muscarinic cholinergic receptors and the involvement of cholinergic mechanisms in the function of specific brain areas is discussed. Their implication in neurological diseases is also reviewed.

Pallidal neurons in the rat

The globus pallidus has been examined in rat brains with Golgi methods. Most of the impregnated cells, the typical pallidal neurons, have relatively large cell bodies and thick, infrequently branched dendrites that are several hundred microns long. Most dendrites have one or two spines, some of them are moderately spiny, and a few are quite spiny. Although the dendrites generally end by simply becoming thinner and beaded, they occasionally form special dendritic ramifications, which are similar to the complicated dendritic endings reported in primate brains. The variability in the size of the somata and in the structure of the dendrites is not sufficiently consistent to permit dividing the neurons into distinctive subsets. However, two forms of dendritic trees can be defined. The neurons in the center of the pallidum have radiate dendritic trees, whereas the cells along the borders have compressed dendritic trees. Two axonal patterns have been seen: ones with and ones without collaterals. All of the axons are beaded. Two other cell types were found. The special border cells along the external medullary lamina in caudal pallidum have dendrites that extend for some distance into the caudate-putamen. They otherwise resemble typical pallidal neurons. Small neurons that were infrequently impregnated may be interneurons, but their axons were not visualized. Their dendrites are short, varicose, and have a few spines. The spherical dendritic trees have a radius of 150-170 micron. Two sorts of axons that are probably afferent fibers were observed. The more common ones are nonbeaded, thin axons that have several boutons en passant and collaterals spaced along their length. In comparison, the other afferent fiber has numerous swellings, boutons en passant, and collaterals that are crowded together. They appear to invest the dendrites closely.

Substance P-containing terminals in synaptic contact with cholinergic neurons in the neostriatum and basal forebrain: a double immunocytochemical study in the rat

Antibodies against substance P and choline acetyltransferase (ChAT) have been used in a sequential double-immunocytochemical ultrastructural study of the rat forebrain. The peroxidase-anti-peroxidase procedure was used for both antigens, however, two different substrates for the peroxidase reactions were used. The substance P-immunoreactive sites were first localized using 3,3'-diaminobenzidine as the substrate, then the ChAT-immunoreactive sites were localized using benzidine dihydrochloride. The reaction product formed by the two substrates was distinguishable in both the light and electron microscopes. Using this procedure, the cell bodies and proximal dendrites of identified cholinergic neurons in the neostriatum were found to receive symmetrical synaptic input from substance P-immunoreactive boutons. A similar pattern of substance P-immunoreactive synaptic input was observed onto magnocellular basal forebrain cholinergic neurons in the ventral pallidum and ventromedial globus pallidus. In both the striatum and basal forebrain substance P-immunoreactive boutons were also seen in contact with structures that did not display ChAT immunoreactivity.

Immunocytochemical localization of choline acetyltransferase in rat ventral striatum: a light and electron microscopic study

The ventral striatum, previously defined as including the nucleus accumbens, substriatal grey, olfactory tubercle and striatal cell bridges has been examined in an immunocytochemical study with monoclonal antibodies to choline acetyltransferase (ChAT) in order to identify putative cholinergic neurons and synaptic junctions within the region. Light microscopy revealed ChAT-positive neurons with similar morphological characteristics in all divisions of ventral striatum. The somata of immunoreactive neurons were round or elongated in shape, approximately 10 X 21 microns in size and had two to four dendrites that coursed long distances and occasionally branched. Electron microscopy of ChAT-positive neurons in substriatal grey initially studied by light microscopy revealed that unlabelled boutons occasionally formed synapses with immunoreactive somata and proximal dendrites, but were more numerous along distal dendrites. Light microscopy demonstrated that ventral striatal neuropil contained numerous ChAT-positive fibres and punctate structures that varied in concentration from moderate to very dense. The lateral border of the substriatal grey and the area within, and adjacent to, all islands of Calleja exhibited the most dense ChAT-positive punctate staining. Additionally, the medial portion of nucleus accumbens was more densely ChAT-positive than the lateral, and the olfactory tubercle displayed laminar variations of immunoreaction product. Counterstained immunocytochemical specimens demonstrated that some areas of dense ChAT-positive punctate staining were associated with clusters of ChAT-negative, medium-sized neurons. Furthermore, electron microscopic observations of substriatal grey revealed that ChAT-positive dense regions were associated with numerous immunoreactive boutons, some of which established synapses with unlabelled somata, dendritic shafts and spines. These results suggest that the densely ChAT-positive neuropil areas within ventral striatum receive more cholinergic innervation than the more lightly stained neuropil areas. There are numerous similarities in the morphological characteristics of ChAT-positive neurons and synapses observed in ventral striatum when compared with those previously described in dorsal striatum. However, some differences were observed, such as smaller somal sizes in ventral, as contrasted with dorsal striatum, and a substantial variation in ChAT-positive fibre and punctate neuropil staining seen within the ventral but not the dorsal striatum. Such differences suggest that the ventral striatum may exhibit greater heterogeneity of cholinergic function than the dorsal striatum.

Cholinergic function and memory: extensive inhibition of choline acetyltransferase fails to impair radial maze performance in rats

The present study investigated the effects of a potent inhibitor of choline acetyltransferase (ChAT), BW813U, on the choice accuracy of rats in the radial arm maze. BW813U (100 mg/kg, IP) produced a rapid (within 1 hour) and substantial decrease in ChAT activity throughout the brain, ranging from 66% (hippocampus) to 80% (caudate nucleus) that lasted up to 5 days. A single injection (50 mg/kg, IP) into rats with lesions (using ibotenic acid) in the nucleus basalis magnocellularis and medial septal area, decreased ChAT activity by 75% and 60% in the cortex and hippocampus, respectively. Lesioned and unlesioned rats were trained on the radial arm maze until they reached a criterion level of performance. Each rat then received an injection of BW813U (50 or 100 mg/kg, IP). Choice accuracy was not impaired at any time following the injection. The lack of effect on performance may be due to 2 possible factors: The radial maze retention paradigm chosen may not be sufficiently difficult, or the decrease in acetylcholine production was not sufficient to affect behavior. Compensation by non-cholinergic neural systems might account for the insensitivity of the rats to significant cholinergic depletion.

Galanin-like immunoreactivity in hippocampal afferents in the rat, with special reference to cholinergic and noradrenergic inputs

The distribution of galanin-like immunoreactivity in the rat hippocampal formation (hippocampus and dentate gyrus) was studied and its origins were determined using various lesioning techniques. Special reference was made to the known cholinergic and noradrenergic hippocampal inputs from the septum-basal forebrain complex and locus coeruleus, both of which have previously been shown to co-contain galanin-like immunoreactivity at the cell body level. Galanin-immunoreactive fibers in the hippocampal formation were of at least three different morphological types: (1) Fine, slender, faintly immunoreactive fibers were seen throughout the hippocampal formation. (2) A strongly fluorescent varicose fiber population was observed mainly in the strata radiatum and oriens of the ventral CA3 region. (3) A population of fine, faint puncta was seen within the granule and pyramidal cell layers throughout the hippocampal formation. Knife cut lesions of the dorsal afferent pathways resulted in almost complete disappearance of all fiber types, except for the ventral fine fibers. Lesions of the fimbria affected mainly the coarse and punctate fiber types, while lesions of the supracallosal striae depleted mainly the fine fibers. Cuts anterior and ventral to the hippocampal formation caused a decrease in ventral fine fibers. Furthermore, lesions of the dorsal bundle caused an almost complete disappearance of the fine fibers in all regions of the hippocampal formation. Neurotoxin lesions of the diagonal band/septal complex resulted in decreases in faintly immunoreactive puncta within the granule cell layer and adjacent fine fibers. It is concluded that most fine galanin-positive fibers originate in the lower brain stem, presumably the locus coeruleus, and appear to reach the hippocampal formation primarily through the supracallosal striae and the ventral route. The fimbria seems to contain a large proportion of the fibers giving rise to the coarse strongly fluorescent innervation, which appears to originate rostral to the pons. The galanin-immunoreactive fibers originating in cholinergic somata of the diagonal band, medial septal nuclei, previously shown to project to the hippocampal formation, seem to give rise to faintly labeled puncta within the granule and pyramidal cell layers, and to a small proportion of the fine fibers bordering the cell layers, as revealed by immunohistochemistry using our antibody.(ABSTRACT TRUNCATED AT 400 WORDS)

Localization of choline acetyltransferase and vasoactive intestinal polypeptide-like immunoreactivity in the nervus terminalis of the fetal and neonatal rat

Ganglia of the nervus terminalis have been shown to contain luteinizing hormone-releasing hormone (LHRH) immunoreactive cells in several mammalian species. These cells are always accompanied by clusters of cells non-immunoreactive to antiserum to LHRH. Using immunocytochemical procedures, we found choline acetyltransferase (ChAT) and vasoactive intestinal polypeptide (VIP) present in cell bodies and in nerve processes throughout the peripheral, intracranial and central projections of the nervus terminalis. In addition, a dense plexus of substance P (SP) immunoreactive fibers was seen in the nasal mucosa surrounding the nasal glandular acini and blood vessels. A number of SP reactive fibers were traced with the olfactory nerves through the cribriform plate of the ethmoid bone and appeared to enter the brain in the area of the central roots of the nervus terminalis.

GABAergic input to cholinergic forebrain neurons: an ultrastructural study using retrograde tracing of HRP and double immunolabeling

Amygdalopetal cholinergic neurons in the ventral pallidum were identified by combining choline acetyltransferase (ChAT) immunohistochemistry with retrograde tracing of horseradish peroxidase (HRP) following injections of the tracer in the basolateral amygdaloid nucleus. Although ChAT-positive terminals were identified in the ventral pallidum, they were never seen in contact with either immunonegative or ChAT-positive amygdalopetal neurons. In material, in which immunostaining against glutamic acid decarboxylase (GAD), the synthesizing enzyme for GABA was combined with retrograde tracing of HRP from the basolateral amygdaloid nucleus, GAD-positive terminals were seen to contact immunonegative amygdalopetal neurons. In addition, when sections of the rostral forebrain were processed, first to preserve and identify the transported HRP, and then were sequentially tested for both ChAT and GAD immunohistochemistry with the immunoperoxidase reaction for both tissue antigens, GAD-immunopositive terminals were seen to make synaptic contacts with cholinergic amygdalopetal neurons. These results suggest that amygdalopetal, presumably cholinergic, neurons receive GAD-positive terminals. In separate experiments using immunoperoxidase for ChAT and ferritin-avidin for GAD labeling, we confirmed the presence of GAD-containing terminals on cholinergic neurons. In addition, cholinergic terminals were seen in synaptic contact with GAD-positive cell bodies. These morphological studies suggest that direct GABAergic-cholinergic and cholinergic-GABAergic interactions take place in the rostral forebrain.

Ultrastructural organization of choline-acetyltransferase-immunoreactive fibres innervating the neocortex from embryonic ventral forebrain grafts

Suspension grafts of foetal tissue rich in cholinergic neurones were transplanted into the frontoparietal cortex of rats that had previously undergone deafferentation of the extrinsic cholinergic innervation of the cortex by injection of ibotenic acid into the nucleus basalis magnocellularis. The cortical tissue containing the graft was processed for electron microscopic immunocytochemistry by using a monoclonal antibody to choline acetyltransferase (ChAT) in order to examine the contacts established between cholinergic fibres from the graft and the host neocortex. The density, distribution, and targets of this graft-host innervation were compared with those seen in the intact and deafferented cortex. ChAT-positive fibres in both grafted and control animals formed extensive synaptic connections with various cortical neural elements--those of graft origin being of similar morphology to those in the intact cortex. However, the distribution of postsynaptic cortical targets of the graft-derived ChAT-immunoreactive boutons was abnormal, such that a greater percentage of such terminals formed synaptic contacts with neuronal perikarya, especially layer V pyramidal neurones, than was seen in control brains. It is possible that the formation of new synaptic contacts between the embryonic graft and host frontoparietal cortex may, in part, be necessary for the restoration of functional activity that has been previously reported in these grafted animals.

Ultrastructural characterization of choline acetyltransferase-containing neurons in the basal forebrain of rat: evidence for a cholinergic innervation of intracerebral blood vessels

The ultrastructural morphology and vascular associations of cholinergic neurons in the horizontal limb of the nucleus of the diagonal band of Broca (nDBBhl) and amygdala of rat were determined by the immunocytochemical localization of choline acetyltransferase (ChAT), the acetylcholine biosynthetic enzyme. Within the nDBBhl peroxidase reaction product was distributed throughout the cytoplasm of selectively labeled neuronal perikarya and dendrites. Labeled perikarya were characterized by an oval cell body (7-10 microns X 17-26 microns in diameter) in which was located a large nucleus and often a prominent nucleolus. Dendrites were by far the most numerous immuno-labeled profiles in the nDBBhl. The labeled dendrites had a cross-sectional diameter of 0.4-4.6 microns and contained numerous mitochondria and microtubules. Approximately 10% of all immunolabeled dendrites received synaptic contacts from unlabeled presynaptic boutons. In contrast to the relatively large number of ChAT-labeled dendrites within the nDBBhl, ChAT-positive axons were less frequently observed and immunolabeled axon terminals were never detected. The labeled axons had an outside diameter of 0.4-1.4 micron and were myelinated. The absence or relative paucity of immunolabeled terminals in the nDBBhl indicates that most if not all of the cholinergic perikarya within this nucleus are efferent projection neurons. The nDBB is known to have widespread projections to many areas of the neocortex, hippocampus, and amygdala. In the present study we examined the amygdala and observed many ChAT-labeled axon boutons. The immunolabeled varicosities contained numerous agranular vesicles and although ChAT-positive terminals were in direct contact with unlabeled neuronal elements within the amygdala, few if any synaptic densities were detected in a single plane of section. With respect to the vasculature, immunolabeled perikarya and dendrites within the nDBBhl and axon terminals in the amygdala were often in direct apposition to blood vessels. In many instances the labeled profile was observed lying directly on the basal lamina of a capillary endothelial cell. In no instance, however, were membrane densities observed. The presence of cholinergic neuronal elements contacting the vessel wall provides morphologic evidence suggesting that the neurogenic control of cerebral vasculature is in part mediated via a cholinergic mechanism.

The cholinergic system of the human hindbrain studied by choline acetyltransferase immunohistochemistry and acetylcholinesterase histochemistry

A map of cholinergic cells of the human brainstem identified by immunohistochemistry of choline acetyltransferase (ChAT) is presented, along with a map of acetylcholinesterase (AChE)-containing cells and fibers. ChAT-positive structures belong to 4 brainstem systems: the cranial motor nuclei; the parabrachial complex; the reticular system; and the vestibular system. All motor nuclei of the cranial nerves, as well as the nucleus supraspinalis, are ChAT-positive. The positively staining structures of the parabrachial system include the nucleus tegmentali pedunculopontinus, and the nuclei parabrachialis medialis and lateralis. Nuclei of the reticular system containing some ChAT-positive cells include the nucleus reticularis pontis oralis and caudalis, the nucleus reticularis tegmenti pontis, the nucleus reticularis gigantocellularis, the nucleus reticularis lateralis and the formatio reticularis centralis (medulla). Structures of the vestibular and auditory systems which contain some ChAT-positive cells include the nucleus vestibularis lateralis, and the nuclei olivaris superioris medialis and lateralis. All ChAT-positive structures stain strongly for AChE. AChE-positive, ChAT-negative structures were noted in several sensory systems. The substantia nigra, locus coeruleus and raphe nuclei, known to contain non-cholinergic cells, also stain positively. The significance of the AChE-positive, ChAT-negative staining in most structures remains to be determined. A knowledge of the cholinergic systems of human brain may be important to an understanding of the pathology of a number of diseases.

Cytoarchitecture, fiber connections, and some histochemical aspects of the interpeduncular nucleus in the rat

The organization of afferent and efferent connections of the interpeduncular nucleus (IP) has been examined in correlation with its subnuclear parcellation by using anterograde and retrograde tracing techniques. Based on Nissl, myelin, and acetylcholinesterase staining five paired and three unpaired IP subnuclei are distinguished. The unpaired division includes the rostral subnucleus (IP-R), the apical subnucleus (IP-A), and the central subnucleus (IP-C). The subnuclei represented bilaterally are the paramedian dorsal medial (IP-DM) and intermediate subnuclei (IP-I) and the laterally placed rostral lateral (IP-RL), dorsal lateral (IP-DL), and lateral subnuclei (IP-L). Immunohistochemical techniques showed cell bodies and fibers and terminals immunoreactive for substance P, leu-enkephalin, met-enkephalin, or serotonin to be differentially distributed over the different IP subnuclei. Substance P-positive perikarya were found in IP-R, enkephalin neurons in IP-R, IP-A, and the caudodorsal part of IP-C, and serotonin-containing cell bodies in IP-A and the caudal part of IP-L. Efferent IP projections were studied both by injecting tritiated leucine in IP and by injecting HRP or WGA-HRP in the presumed termination areas. The results indicate that the major outflow of IP is directed caudal-ward to the median and dorsal raphe nuclei and the caudal part of the central gray substance, i.e., the dorsal tegmental region. The projection appears to terminate mainly in the raphe nuclei, around the ventral and dorsal tegmental nuclei of Gudden, and in the dorsolateral tegmental nucleus. The descending projection to the dorsal tegmental region originates in virtually all IP subnuclei, but the main contribution comes from IP-R and the lateral subnuclei IP-RL, IP-DL, and IP-L. Sparser projections to the dorsal tegmental region originate in IP-C and IP-I, whereas the contribution of IP-A is only minimal. The projections from IP-R are mainly ipsilateral and those from IP-DM are mainly contralateral. IP fibers to the median and dorsal raphe nuclei originate predominantly in IP-R and IP-DM, and to a lesser extent in IP-C, IP-I, IP-RL, and IP-DL. A much smaller contingent of IP fibers ascends to diencephalic and telencephalic regions. A relatively minor projection, stemming from IP-RL and IP-DL, reaches the lateral part of the mediodorsal nucleus, the nucleus gelatinosus, and some midline thalamic nuclei. These IP fibers follow either the habenulo-interpeduncular pathway or the mammillothalamic tract.(ABSTRACT TRUNCATED AT 400 WORDS)

Cholinergic projections from the parabigeminal nucleus (Ch8) to the superior colliculus in the mouse: a combined analysis of horseradish peroxidase transport and choline acetyltransferase immunohistochemistry

Choline acetyltransferase (ChAT) immunocytochemistry, acetylcholinesterase histochemistry and muscarinic receptor autoradiography demonstrated a cholinergic innervation within the superior colliculus. A method for the concurrent visualization of ChAT and transported horseradish peroxidase showed that a major extrinsic source for this cholinergic input is in the parabigeminal nucleus. We have designated these cholinergic neurons as the Ch8 cell group.

Prenatal development of nucleus basalis complex and related fiber systems in man: a histochemical study

To provide parameters for study of the "cholinergic" innervation of a human fetal cerebrum, we have analyzed the prenatal development of histochemical reactivity in the nucleus basalis complex (a magnocellular complex known to contain a high concentration of cholinergic perikarya). Brains from fetuses and premature infants ranging between 8 and 35 weeks of gestation were frozen cut and processed by the thiocholine method for the demonstration of acetylcholinesterase activity. Since no consistent results were obtained with inhibitors on the material younger than 15 weeks, the histochemical reactivity for early stages was expressed as the total cholinesterase reactivity. The first sign of histochemical differentiation of the basal telencephalon is the appearance of a dark cholinesterase reactive "spot" situated between the developing lenticular nucleus and basal telencephalon surface as early as 9 weeks of gestation. The first cholinesterase reactive bundle connects this reactive area (nucleus basalis complex anlage) with the strongly reactive fiber system situated along the dorsal side of the optic tract. During the next "stage" (10.5 weeks), there is a significant increase in the size of the nucleus basalis complex and strongly cholinesterase reactive neuropil occupies the sublenticular, diagonal and septal areas. At this stage we have seen two new cholinesterase-reactive bundles: one well developed cholinesterase reactive fiber stratum approaching (but not penetrating) the neocortical anlage through the external capsule and another minute bundle running towards the medial limbic cortex through the precommissural septum. The supraoptic fiber system can be traced now to the pregeniculate area and the tegmentum. At 15 weeks, the first acetylcholinesterase reactive perikarya appear and the nucleus basalis complex anlage becomes segregated into several strongly reactive territories, corresponding in position to the medial septal, diagonal and basal nuclei as defined on adjacent Nissl stained sections. At this stage, fibers from the nucleus basalis complex enter the "white" matter of frontal, temporal, parietal and occipital parts of the cerebral hemisphere via the external capsule. Between 15 and 18 weeks, acetylcholinesterase fibers spread throughout the "white" matter of the cerebral hemisphere. In the next "stage" (18-22 weeks), strongly reactive fibers can be followed from the nucleus basalis below the putamen and through the external capsule to the transient, synapse-rich subplate zone of frontal, temporal, parietal and occipital cortices.(ABSTRACT TRUNCATED AT 400 WORDS)

Cholinergic limbic projections and behavioral role of basal forebrain nuclei in the rat

The purposes of the present study were to identify cholinergic non-neocortical projections of the basal forebrain and to determine the role of this region in the regulation of estrogen-dependent reproductive behaviors in the rat. Bilateral electrolytic lesions were placed in an area encompassing the horizontal limb of the diagonal band, as well as portions of the substantia innominata and magnocellular preoptic nucleus, and choline acetyltransferase (CAT) activity was assayed in microdissected brain areas seven days after lesion. Compared to sham surgery, lesions of this region significantly reduced CAT activity in the basal amygdala (34%), dorsal hippocampus (14%), cingulate cortex (25%), piriform cortex (36%), and entorhinal cortex (34%). Other limbic and midbrain structures do not appear to receive significant cholinergic innervation from this locus since no reductions in CAT were detected after bilateral lesions. These included the anterior hypothalamus, ventromedial hypothalamus, mammillary nucleus, habenula, subiculum, ventral hippocampus, insular cortex, central gray, and interpeduncular nucleus. Behaviorally, female rats with bilateral lesions of the basal forebrain displayed an unusually high incidence of rejection behavior in response to attempted mounts by stimulus male rats in sexual behavior tests. There was no effect of basal forebrain lesions on the incidence of lordosis exhibited by these females. The dissociation of rejection and lordosis suggests that distinct neural pathways mediate the occurrence of these reproductive behaviors and that rejection behavior may be regulated by basal forebrain pathways.

Light microscopic evidence of striatal input to intrapallidal neurons of cholinergic cell group Ch4 in the rat: a study employing the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L)

Injections of the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L) were placed in various striatal loci in the rat. Within the globus pallidus, PHA-L-filled striatofugal axons were seen to approach cholinergic neurons, identified with either acetylcholinesterase histochemistry or choline acetyltransferase immunohistochemistry, and, apparently, to contact the surface of such cells with axonal varicosities. Since these varicosities are thought to mark the sites of synaptic terminals, such juxtapositions provide strong light-microscopic evidence that intrapallidal cholinergic neurons in the rat receive a direct innervation from the striatum and are integrated into the circuitry of the basal ganglia.

Distribution of GABAergic and cholinergic neurons in the rat diagonal band

GABAergic neurons are coextensive with cholinergic neurons in the medial septum-diagonal band complex. Serial sectioning, sequential staining and double immunofluorescence techniques employing antibodies to glutamate decarboxylase and choline acetyltransferase revealed the distribution of these transmitter-specific neurons in the rat. Morphologically, the two types of neurons appear similar, in that they are predominantly large multipolar cells, but they are characterized by different, overlapping distributions in the diagonal band. Glutamate decarboxylase-positive cells are scattered throughout the nucleus of the vertical limb of the diagonal band, while choline acetyltransferase-positive neurons are more numerous medially and are distributed in groups corresponding to the dorsal and ventral aspects of the nucleus. In the rostral parts of the nucleus of the horizontal limb of the diagonal band, the choline acetyltransferase-positive cells tend to be located medially, whereas caudally they spread dorsal to the nucleus to become continuous with other large cholinergic neurons in the ventral pallidum and sublenticular substantia innominata. The large majority of glutamate decarboxylase-positive neurons remain in a more ventral and lateral position within the nucleus of the horizontal limb and are particularly numerous just lateral to the diagonal band fibers as they join the medial forebrain bundle. Cholinergic neurons were estimated to be about two times more numerous than GABAergic neurons. Approximately 1% of the choline acetyltransferase-positive neurons were also glutamate decarboxylase-positive in double immunofluorescence studies, but not in sequentially stained or serial sections.

Cholinergic and GABAergic afferents to the olfactory bulb in the rat with special emphasis on the projection neurons in the nucleus of the horizontal limb of the diagonal band

We have examined the location of cholinergic and GABAergic neurons that project to the rat main olfactory bulb by combining choline acetyltransferase (ChAT) and glutamic acid decarboxylase (GAD) immunohistochemistry with retrograde fluorescent tracing. Since many of the projection neurons are located in subcortical basal forebrain structures, where the delineation of individual regions is difficult, particular care was taken to localize projection neurons with respect to such landmarks as the ventral pallidum (identified on the basis of GAD immunoreactivity), the diagonal band, and medial forebrain bundle. In addition, sections with fluorescent tracers or immunofluorescence were counterstained for Nissl substance in order to correlate tracer or immunopositive neurons with the cytoarchitecture of the basal forebrain. The majority of the cholinergic bulbopetal neurons are located in the medial half of the nucleus of the horizontal limb of the diagonal band (HDB), whereas only a few are located in its lateral half. A substantial number of cholinergic bulbopetal cells are also found in the sublenticular substantia innominata. A small number of cholinergic bulbopetal neurons, finally, are located in the ventrolateral portion of the nucleus of the vertical limb of the diagonal band. At the level of the crossing of the anterior commissure, approximately 17% of the bulbopetal neurons in the HDB are ChAT-positive. The noncholinergic bulbopetal cells are located mainly in the lateral half of the HDB. GAD-containing bulbopetal neurons are primarily located in the caudal part of the HDB, especially in its lateral part. About 30% of the bulbopetal projection neurons in the HDB are GAD-positive. A few GAD-positive bulbopetal cells, furthermore, are located in the ventral pallidum, anterior amygdaloid area, deep olfactory cortex, nucleus of the lateral olfactory tract, lateral hypothalamic area, and tuberomamillary nucleus. The topography of bulbopetal neurons was compared to other projection neurons in the HDB. After multiple injections of fluorescent tracer in the neocortex, retrogradely labeled neurons were concentrated in the most medial part of the HDB, while neurons projecting to the olfactory and entorhinal cortices were located in the ventral part of the HDB. These results show that the cells of the HDB can be divided into subpopulations based upon projection target as well as transmitter content. Furthermore, these subpopulations correspond, at least to a considerable extent, to areas that can be defined on cyto- and fibroarchitectural grounds.