Projections of the interstitial nerve cells surrounding the globus pallidus: a study of retrograde changes following cortical ablations in rabbits

Dopaminergic regulation of cortical acetylcholine release

The extent to which the activity of basal forebrain cholinergic neurons is influenced by dopamine (DA) was investigated using in vivo microdialysis of cortical acetylcholine (ACh). Systemic administration of the DA receptor agonist apomorphine significantly increased dialysate concentrations of ACh. Systemic, but not local, administration of d-amphetamine produced similar effects. Both D1 (SCH 23390) and D2 (haloperidol, raclopride) DA receptor antagonists attenuated the amphetamine-induced increase in cortical ACh release; however, only the D1 antagonist significantly reduced basal output of cortical ACh. These findings suggest that the activity of cortically projecting cholinergic neurons in the nucleus basalis is regulated in an excitatory manner by central dopaminergic neurons and that both D1 and D2 receptors are involved.

Expression of nerve growth factor (NGF) receptors in the brain and retina of chick embryos: comparison with cholinergic development

The expression of nerve growth factor receptor (NGFR) transcripts was investigated with in situ hybridization techniques in the CNS of chick embryos from 3 days of incubation (E3) to 14 days posthatch (P14). The time course and distribution of NGFR expression was compared with the development of the cholinergic phenotype. Cholinergic properties were assessed by immunolabeling for choline acetyltransferase (ChAT) and histochemistry for acetylcholinesterase (AchE) activity. NGFR transcripts are expressed transiently in the inner plexiform layer and ganglion cell layer of the retina (E4-P1), neostriatum and hippocampus (E18), infundibular hypothalamus (E7-18), spiriform complex (E9-15), layers 2, 3 (E9-18), and 10 (E11-18) of the optic tectum, nucleus mesencephalicus profundus, pars ventralis (E9-18), parvicellular isthmic nucleus (E7-P1), magnocellular isthmic nucleus (E9-E18), nucleus semilunaris (E7-18), isthmo-optic nucleus (E7-P14), rostral motor nuclei (E5-18), developing cerebellum (E7-15), internal granule cell layer (E11-18) and Purkinje cell layer (E15-P14) of the cerebellar cortex, and the inferior olivary nucleus (E9-15). A small number of neuronal populations with embryonic expression of NGFR remain strongly NGFR-positive in the posthatch animal:habenular nuclei (labeled after E5), nucleus subrotundus (after E9), mesencephalic trigeminal nucleus (after E5), caudal parts of locus ceruleus and nucleus subceruleus (after E7), medullar reticular nuclei (after E11), and motor nuclei IX, X, and XII (after E9). The majority of neuronal populations with NGFR expression show cholinergic properties in development, and NGFR expression always precedes the onset of ChAT immunoreactivity. Postnatal expression of growth factor receptors is largely confined to neurons of the reticular type. NGFR expression in avian CNS nuclei differs from that in mammals. Early loss of NGFR expression in the cholinergic basal forebrain (which remains strongly NGFR positive in mammals) and persistent NGFR expression in parts of the avian locus ceruleus indicate changes of growth factor receptor expression and growth factor requirements in phylogeny. Knowledge of the time and distribution of NGFR expression in the chick embryo will facilitate the assessment of specific functions of NGF and NGF-like molecules in an embryonic model with easy access for experimental manipulations.(ABSTRACT TRUNCATED AT 400 WORDS)

Alternating phases of FGF receptor and NGF receptor expression in the developing chicken nervous system

Patterns of expression of transcripts encoding receptors for fibroblast growth factor and nerve growth factor (FGF-R and NGF-R) in the developing chick nervous system are compared using in situ hybridization histochemistry. FGF-R transcripts are expressed abundantly in the germinal neuroepithelial layer. Expression ceases as cells migrate into the mantle layer and returns during late maturation of neuronal populations, including cholinergic nuclei of the basal forebrain, brainstem reticular and motor nuclei, and cerebellar Purkinje and granule neurons. The pattern of NGF-R expression is generally reciprocal to that of FGF-R in the CNS and in some phases of development of the PNS. These results suggest that FGF and NGF may act sequentially rather than in concert during neuronal development.

New perspectives in basal forebrain organization of special relevance for neuropsychiatric disorders: the striatopallidal, amygdaloid, and corticopetal components of substantia innominata

The basal forebrain is critically involved in functions representing the highest levels of integration. Only recently has a relatively clear anatomical picture of this important area begun to emerge. The territory that has generally been referred to as the "substantia innominata" appears to be composed of portions of three recognizable forebrain structures: the ventral striatopallidal system, the extended amygdala and the magnocellular corticopetal system. (1) Rostrally, the striatopallidal system reaches ventrally to the base of the brain. (2) Caudal to the ventral extension of the striatopallidal system elements of the centromedial amygdala and bed nucleus of the stria terminalis are merged so that these two areas together with this subpallidal corridor form a large forebrain unit that might be described as an "extended amygdala". (3) Large cholinergic and non-cholinergic corticopetal neurons form a more or less continuous aggregate that is interwoven with the striatopallidal and extended amygdala systems in basal forebrain. Consideration of morphological and connectional characteristics of basal forebrain suggests that the corticopetal cell groups, together with magnocellular elements of the striatum, serve similar functional roles for the striatopallidal system, the extended amygdala, and the septal-diagonal band complex. Specifically, the output of medium spiny neurons in striatum, extended amygdala, and lateral septum are directed toward somewhat larger sparsely or moderately spiny neurons with radiating dendrites which in turn project to diencephalon and brainstem or provide either local feedback (e.g. in striatum) or distal feedback to cortex. The functional implications of this parallel processing of descending forebrain afferents are discussed.

Postnatal development of interstitial (subplate) cells in the white matter of the temporal cortex of kittens: a correlated Golgi and electron microscopic study

The early postnatal development of interstitial cells (IC) in the white matter of the temporal cortex in kittens was studied. Counts in Nissl-stained preparations show that the number of IC diminishes by about 60% during the second postnatal week. In Golgi preparations, IC are bipolar or bitufted with long, beaded dendrites coursing in the white matter toward the ventricular surface. Ascending, shorter dendrites are thinner, often branch in a short bush, and possess long spines resembling filopodia. The majority of their axons descend in the white matter, emitting numerous recurrent collaterals that become ascending fibers reaching various cortical layers. Most IC resemble inverted pyramidal cells. They appear well developed at the time of birth and continue to develop elaborate axonal complexes in the white matter of older animals. Electron microscopic observations of degenerating IC were detected in all cases studied and their presence was related to the existence of cell death responsible for elimination of a fraction of IC. They were recognized by their dark aspect and by dilations of the endoplasmic reticulum. Synapses contacting degenerating profiles were also observed. It is concluded that IC belong to the population of early generated subplate cells which may have a transient function involved in certain morphogenetic events during the development of the cortical plate. Some persist in the adult where they can be recognized as IC of the white matter.

The nucleus basalis of Meynert in neurological dementing disease: a review

The nucleus basalis of Meynert of the substantia innominata supplies the major cholinergic innervation of the cerebral cortex. Pathological alterations have been observed in the nucleus basalis of Meynert in several dementing neurological disorders. This paper is an overview of the work done by several researchers in their attempt to find the possible connections between pathology in the nucleus basalis of Meynert and the clinical symptomatology of dementia in several neurological diseases.

Age-related shrinkage of cortically projecting cholinergic neurons: a selective effect

The number and size of basal forebrain neurons that provide the cholinergic innervation for the cerebral cortex, amygdala, and hippocampus were studied in young and aged mice. The results showed that these neurons became substantially smaller with increasing age. This effect was relatively selective, since the immediately adjacent cholinergic neurons in the striatum did not show a change of similar magnitude. The shrinkage of these basal forebrain neurons may account for the decline of cholinergic innervation that occurs with age. In the material that we examined, aging did not influence the number of cholinergic neurons in the basal forebrain, only their size. It seems, therefore, that the age-related changes in cholinergic function (and their putative behavioral consequences) are not associated with a substantial component of irreversible cell death.

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.

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)

Three-dimensional representation and cortical projection topography of the nucleus basalis (Ch4) in the macaque: concurrent demonstration of choline acetyltransferase and retrograde transport with a stabilized tetramethylbenzidine method for horseradish peroxidase

Ninety-six percent of the nucleus basalis neurons that project to the neocortex contain choline acetyltransferase. These projections from the cholinergic component of the nucleus basalis (Ch4) are topographically organized so that each cortical area receives most of its cholinergic input from a different Ch4 sector. The three-dimensional reconstruction of these sectors reveals the presence of a complex structure. A stabilization procedure that was used in these experiments maintains all the advantages of the tetramethylbenzidine method for horseradish peroxidase while eliminating the vulnerability of the reaction-product to high pH and dehydrating agents.

Effects of bilateral ibotenate-induced lesions of the nucleus basalis magnocellularis upon selective cholinergic biochemical markers in the rat anterior cerebral cortex

The relationship of choline acetyltransferase (ChAT) activity and high affinity binding of the potent and selective sodium-dependent choline uptake inhibitor [3H]hemicholinium-3 ([3H]HC-3) to high-affinity binding of the muscarinic agonist [3H](+)-cis-methyldioxolane ([3H](+)CD), the putative M1 selective antagonist [3H]pirenzepine ([3H]PZ) and the classical antagonist [3H](-)-quinuclidinyl benzilate ([3H](-)QNB) in homogenates of the rat neocortex was studied. ChAT activity was 42% lower in rats with ibotenate-induced lesions of the nucleus basalis magnocellularis (nbm) when compared to controls, and [3H]HC-3 binding was similarly reduced by 44%. However, equilibrium dissociation constants (Kd values) for [3H]HC-3 (0.8-1.0 nM), [3H](-)QNB (11-24 pM), [3H]PZ (4.0-4.3 nM) and [3H](+)CD (2.1-2.9 nM) were each unchanged. Mean Bmax values (total binding site densities) for [3H](+)CD were significantly altered in both hemispheres of the anterior cerebral cortex, showing a 25% reduction in the number of sites which display the highest affinity conformation for this potent muscarinic agonist. The decreased ChAT activity and [3H]HC-3 binding after nbm lesions were associated with only slight reductions in putative M1 muscarinic site density (14%) and [3H](-)QNB binding site density (13%). Thus, it appears that while [3H]PZ and [3H](-)QNB label predominantly postsynaptic muscarinic binding sites, a significant number of sites labeled by [3H](+)CD may be associated with presynaptic cholinergic nerve terminals. These data suggest that cholinergic input differentially regulates the drug binding sites of anterior cerebral cortical muscarinic receptors, exerting a substantial effect upon the highest affinity conformational state for agonists.

Selective memory loss following nucleus basalis lesions: long term behavioral recovery despite persistent cholinergic deficiencies

Rats were trained for several months to perform a radial arm maze task and then given either sham or ibotenic acid lesions of the nucleus basalis magnocellularis (NBM), the primary cholinergic projection to the neocortex. The lesion produced a profound and apparently selective disturbance in memory for recent events. Further testing revealed that although the memory deficit persisted for several weeks, a gradual but complete recovery eventually occurred. Moreover, when these functionally recovered rats were later tested on a passive avoidance task that is normally sensitive to lesions of the NBM, no deficit was found. Thus, the post-lesion recovery of function generalized to a different memory test, upon which no post-lesion practice had been given. Post-mortem determinations revealed that the lesions caused marked neurodegeneration of the NBM, and decreases in both cortical choline acetyltransferase activity and high affinity choline uptake, but had no effect on density of muscarinic receptors. No evidence of neuronal recovery or neurochemical compensatory changes in the cholinergic system was found in the cortical projection areas, lesion site, or in parallel cholinergic systems terminating in the hippocampus or olfactory bulb. These results support the idea that the cortically-projecting cholinergic cells of the NBM normally play an important role in mediating recent memory. However, they also demonstrate that any simple relationship between the function of this brain region and the mediation of recent memory is unlikely. Finally, the results of this study direct attention toward issues related to the mechanisms involved with the recovery of function, and the extent to which degeneration of this brain area may contribute directly to the severe disturbance of cognitive function associated with certain neurodegenerative diseases (e.g., Alzheimer's, Pick's and Parkinson's disease).

Basal forebrain innervation of rodent neocortex: studies using acetylcholinesterase histochemistry, Golgi and lesion strategies

Acetylcholinesterase (AChE)-rich projections from basal forebrain to neocortex cerebri were characterized in the present study. The purpose was to investigate 3 aspects of these projections in rats and mice that have been incompletely described in previous work: intracortical organization of the fibers, subcortical pathways and axonal branching patterns of individual basal forebrain neurons. AChE histochemistry, lesions and Golgi impregnations were the principal strategies employed in this light microscopic study. The moderately dense, AChE-stained innervation of neocortex can be altered by intracortical lesions. The results depended on the region involved and the orientation of the lesion. Sagittal knife cuts had barely detectable effects, regardless of sites. Coronal knife cut lesions in medial cortex resulted in substantial loss of staining in cingulate and medial occipital fields. In contrast, coronal lesions of lateral or anterior cortex produce only small zonal reductions in staining. The interpretation of the latter findings that we favor is that AChE-rich basal forebrain fibers enter lateral/anterior cortex and branch densely there, but in tangentially limited and overlapping terminal domains. Observations on the topography and targets of AChE-rich basal forebrain cortical afferents revealed that the fibers could be grouped based on certain characteristics. Three sets of fibers were distinguishable: anterior pathway innervating cortex of the frontal pole. These fibers were traceable to the region of the substantia innominata/nucleus basalis. They crossed the neostriatum and external capsule in the sagittal plane, forming in 3 dimensions an orderly sheet-like array of fibers bridging the anteroventral surface of the neostriatum with nearby polar cortex medial pathway innervating cingulate and medial occipital cortex. Emerging predominantly from the region of the diagonal band, the fibers run caudally as a triangular bundle in deep layer VI of cingulate cortex. lateral pathway innervating most of remaining lateral neocortex. The fibers radiate out from substantia innominata/nucleus basalis with a complex 3-dimensional organization. In all pathways, fibers enter and initially run within layer VI before ascending pialward, although the intracortical course in layer VI differs between pathways. These fibers primarily terminate in layer V with a secondary concentration in layer I. However, the latter appears to receive substantial AChE-stained inputs from other sources, possibly intracortical, as well. The pathways overlap at their respective boundary zones. This system is comparably organized in rats and mice.(ABSTRACT TRUNCATED AT 400 WORDS)

Cholinergic projections from the basal forebrain to the basolateral amygdaloid complex: a combined retrograde fluorescent and immunohistochemical study

We have examined the location of cholinergic and non-cholinergic neurons that project to the rat basolateral amygdaloid nucleus by using choline acetyltransferase (ChAT) immunohistochemistry in combination with retrograde fluorescent tracing on the same tissue section. Since many tracer-and ChAT-positive neurons were identified in basal forebrain areas, including the ventral pallidum, we also stained many of the sections for glutamate decarboxylase, a suitable marker for the delineation of pallidal areas. Cholinergic neurons projecting to the basolateral amygdaloid nucleus were observed in a continuous territory stretching from the dorsal part of ventral pallidum, through sublenticular substantia innominata to ventral parts of globus pallidus and peripallidal areas. Non-cholinergic neurons projecting to the basolateral amygdaloid nucleus were found intermixed within the same structures and constitute approximately 25% of the amygdalopetal projection neurons in these ventral forebrain structures. Since amygdalopetal cholinergic neurons were demonstrated in areas generally recognized as giving rise to cholinergic projections to cerebral cortex, several retrograde double-labeling experiments with two different fluorescent tracers were performed for the purpose of detecting the possible existence of collateral projections. The results obtained showed that the cholinergic basal forebrain neurons in general project to only one forebrain region, and, furthermore, that the cholinergic system consists of partially overlapping subsets of neurons that project to various neocortical and allocortical areas and to the amygdaloid body.

Neuronal loss in the basal nucleus of Meynert in a patient with olivopontocerebellar atrophy

A morphometric study of the basal nucleus of Meynert has been performed in a case of familial olivopontocerebellar atrophy with mental deterioration. The magnocellular population of the basal nucleus was found to be substantially reduced in number (over 60%) as compared with that of three age-matched controls. This finding has not been reported previously and might represent one of the anatomic substrates of some of the cognitive disturbances exhibited by a considerable number of patients with olivopontocerebellar atrophy (OPCA).

A cytoarchitectonic and histochemical study of nucleus basalis and associated cell groups in the normal human brain

Several recent studies have reported loss of neurons in the nucleus basalis in Alzheimer's disease. However, few detailed studies of the normal distribution of these neurons in the human brain have appeared. We have used Nissl staining and acetylcholinesterase histochemical staining of the human basal forebrain, alone or in combination to identify the organization of the nucleus basalis and associated cell groups, (or collectively, the magnocellular basal nucleus) in the normal human brain. The magnocellular basal nucleus includes a series of clusters of neurons and scattered perikarya extending from the medial septum and diagonal band nucleus rostrally, through the substantia innominata to the furthest caudal extent of the globus pallidus. This distribution is similar to that which has been described in the monkey. Furthermore, acetylcholinesterase-positive fibers in the human brain are seen in the two major pathways that have been identified as carrying magnocellular basal nucleus axons to the cerebral cortex in other species. These observations suggest that the topographic organization of the magnocellular basal projection to cerebral cortex in other species probably exists in man as well. It will therefore be important in future studies of the fate of these neurons in neurological degenerative diseases to assess the loss of neurons in the different components of the magnocellular basal nucleus in relation to the clinical evidence for dysfunction in the cortical areas which they innervate.

Cortical projections arising from the basal forebrain: a study of cholinergic and noncholinergic components employing combined retrograde tracing and immunohistochemical localization of choline acetyltransferase

The neurochemical identity of ascending putative cholinergic pathways from the rat basal forebrain was investigated employing a method for simultaneously visualizing choline acetyltransferase immunoreactivity and retrogradely transported horseradish peroxidase-conjugated wheatgerm agglutinin. This histochemical procedure revealed three distinct populations of neurons: (1) cells which stained only for choline acetyltransferase immunoreactivity; (2) cells which stained only for retrograde tracer and (3) cells which stained simultaneously for choline acetyltransferase immunoreactivity and retrograde tracer. The results demonstrated that this projection is topographically organized and consists of both cholinergic and noncholinergic components. The relative contribution of each component varied with the telencephalic target area as follows: the olfactory bulb receives a projection from cells of the horizontal limb nucleus, 10-20% of which are cholinergic (Ch3); the hippocampal formation receives afferents from cells of the medial septal and vertical limb nuclei, 35-45% of which are cholinergic (Ch1 and Ch2); and the cortical mantle receives afferents primarily from cells within the substantia innominata-nucleus basalis complex, 80-90% of which are cholinergic (Ch4). The topographical organization of Ch4 projections is not as completely differentiated as we have previously observed in the primate.

Evidence for a laminar organization of basal forebrain afferents to the visual cortex

The present study shows that restriction of HRP injections to layer I within the visual cortex results in negligible retrograde labeling within the nuclei of the basal forebrain. In contrast, when the injections of either HRP or WGA-HRP are restricted to the granular and infragranular layers of visual cortex, extensive retrograde labeling occurs within the basal forebrain. Based upon these findings, we argue that the projection from the basal nucleus terminates preferentially within the deep layers of the visual cortex, and thus contributes minimally to the supragranular layers, including layer I.

Neurone loss in the nucleus basalis of Meynert in Creutzfeldt-Jakob disease

In a man of 47 with a 2-month history of Creutzfeldt-Jakob-disease verified neuropathologically a morphometric study of the nucleus basalis of Meynert, the major source of cholinergic innervation of the cortex, revealed a neuronal loss of 45%. The degeneration of these neurones may provide the morphological substrate of the cortical cholinergic deficiency which has been reported in this condition. The six subpopulations of the nucleus basalis were affected in different degrees. Neuronal loss was most pronounced in those subpopulations which project to cortical areas most affected by spongiosis and neuronal loss. It is suggested that maintenance of the nucleus basalis complex is a necessary condition for higher cortical function.

Central cholinergic pathways in the rat: an overview based on an alternative nomenclature (Ch1-Ch6)

Monoclonal antibodies to choline acetyltransferase and a histochemical method for the concurrent demonstration of acetylcholinesterase and horseradish peroxidase were used to investigate the organization of ascending cholinergic pathways in the central nervous system of the rat. The cortical mantle, the amygdaloid complex, the hippocampal formation, the olfactory bulb and the thalamic nuclei receive their cholinergic innervation principally, from cholinergic projection neurons of the basal forebrain and upper brainstem. On the basis of connectivity patterns, we subdivided these cholinergic neurons into six major sectors. The Ch1 and Ch2 sectors are contained within the medial septal nucleus and the vertical limb nucleus of the diagonal band, respectively. They provide the major cholinergic projections of the hippocampus. The Ch3 sector is contained mostly within the lateral portion of the horizontal limb nucleus of the diagonal band and provides the major cholinergic innervation to the olfactory bulb. The Ch4 sector includes cholinergic neurons in the nucleus basalis, and also within parts of the diagonal band nuclei. Neurons of the Ch4 sector provide the major cholinergic innervation of the cortical mantle and the amygdala. The Ch5-Ch6 sectors are contained mostly within the pedunculopontine nucleus of the pontomesencephalic reticular formation (Ch5) and within the laterodorsal tegmental gray of the periventricular area (Ch6). These sectors provide the major cholinergic innervation of the thalamus. The Ch5-Ch6 neurons also provide a minor component of the corticopetal cholinergic innervation. These central cholinergic pathways have been implicated in a variety of behaviors and especially in memory function. It appears that the age-related changes of memory function as well as some of the behavioral disturbances seen in the dementia of Alzheimer's Disease may be related to pathological alterations along central cholinergic pathways.

Topographic analysis of the innervation of the rat neocortex and hippocampus by the basal forebrain cholinergic system

The basal forebrain-cortex connections of the rat were topographically mapped by retrograde tracer methods; and their contribution to the cholinergic innervation of the cortex was assessed by excitotoxin lesions placed in the rostral and caudal aspects of the complex. Discrete injections of tracer into frontal cortex labeled the prominent multipolar acetylcholinesterase (AchE)-positive cells of the ventromedial globus pallidus. Injections of tracer into the parietal cortex labelled cells in the ventral globus pallidus, the underlying substantia innominata, and the lateral hypothalamus. Separate injections of Fast Blue and Nuclear Yellow in the frontal and in the parietal cortex resulted in double-labeled cells in the ventral globus pallidus, which indicates that at least some of these cells may possess collateralizing axons. The cingulate cortex is innervated predominantly by neurons in the nucleus of the horizontal limb of the diagonal band. The occipital cortex was also shown to receive a projection primarily from the nucleus of the horizontal limb of the diagonal band. The hippocampal formation is innervated primarily by cells located in the vertical limb of the diagonal band and in the medial septum. Consistent with the results of the retrograde tracing studies, excitotoxin lesions affecting the diagonal band and medial septum decreased choline acetyltransferase (CAT) activity up to 40% on the occipital cortex and by 64% in the hippocampus, but did not affect CAT activity in the rostral neocortex. In contrast, ibotenate lesions of the caudal ventral globus pallidus and substantia innominata caused decreases in CAT activity in the frontal cortex of up to 65% without affecting enzyme activity in the hippocampal formation. The results of the present study provide details on the topographic organization of the cortical projections originating in the basal forebrain complex and indicate that these neurons are the predominant source of cortical cholinergic innervation.

Regional decreases of cortical choline acetyltransferase after lesions of the septal area and in the area of nucleus basalis magnocellularis

Choline acetyltransferase and [3H]choline uptake have been measured in neocortical regions and hippocampus one week after lesions which destroyed the septum bilaterally, and after unilateral lesions in the area of nucleus basalis magnocellularis. Lesions of the septal area, which severely decreased choline acetyltransferase in hippocampus, only moderately decreased choline acetyltransferase in a posterior cortical region and had no effect in frontal and parietal regions. In contrast, lesions which included nucleus basalis magnocellularis decreased choline acetyltransferase markedly in frontal and parietal regions and had less of an effect in the posterior cortical regions. Lesion-induced decreases of [3H]choline uptake paralleled those of choline acetyltransferase. Lesion which included nucleus basalis magnocellularis had no effect on choline acetyltransferase in hippocampus, nucleus accumbens, olfactory tubercle, midbrain or pons-medulla. These results suggest that existence of topographically distinct cholinergic inputs to neocortex. In agreement with previous studies, cholinergic projections from the peripallidal region of nucleus basalis magnocellularis are predominantly to frontal and parietal neocortex. In contrast to previous suggestions, cholinergic projections to neocortex from the septal area are limited to the posterior regions of neocortex.

Distribution and morphological characteristics of acetylcholinesterase-containing neurons in the basal forebrain of the cat

The topographical distribution and morphological characteristics of neurons containing acetylcholinesterase (AChE, EC 3.1.1.7) in the basal forebrain of the cat were studied by means of the Butcher's pharmaco-histochemical technique involving staining for AChE at various times after the administration of di-isopropylfluorophosphate (DFP). This method allows a clear visualization of numerous AChE-producing neurons in olfactory tubercle, medial septal-diagonal band area, hypothalamus and basal ganglia. In olfactory tubercle the AChE neurons abound in the deep polymorph layer where they form several types of cell clusters topographically related to the islands of Calleja. The AChE neurons in medial septal nucleus appear morphologically similar to those in nucleus of the diagonal band. As a whole, the medial septal-diagonal band area stands out as one of the major AChE cell collections in basal forebrain. In hypothalamus, neurons staining intensely for AChE occur particularly in supraoptic and paraventricular nuclei and in supramammillary nucleus. The neurons in lateral hypothalamic area stain only moderately for the enzyme. On the other hand, numerous large-sized AChE cells are scattered throughout the neostriatum. However, the AChE cells in putamen appear morphologically different, more numerous per mm2, and larger than those in caudate nucleus suggesting that the feline neostriatum is not a homogeneous structure. The globus pallidus contains both small and large cells that stain lightly and intensely for AChE, respectively. The small pallidal cells are similar to entopeduncular cells and it is proposed that they form the typical pallidal elements. In contrast, the large pallidal AChE cells appear similar to AChE neurons lying in adjacent substantia innominata, and are continuous with the AChE cells in medial septal-diagonal band area. It is suggested that these magnocellular AChE neurons form a population of "limbic" elements within the feline basal ganglia.