[Food-procuring stereotype movements is accompanied by changes of c-Fos gene expression in the amygdala and modulation of heart rate in rats]

The distribution of Fos-immunoreactive (Fos-ir) and NADPH Diaphorase reactive (NADPH-dr-) neurons in the different subnuclei of amygdala and insular cortex (on the level -2,12 to -3,14 mm from bregma), and the associated changes of heart rate (HR) in intact, food-deprivated and executed food-procuring movements of rats were studied. In comparison with other groups of animals, the mean number of the Fos-ir neurons in the central nucleus of amygdala (Ce) and the insular cortex (GI/DI) at all studied levels was significantly greater in the executed food-procuring movements in rats. The main focus of localization of the Fos-ir neurons was found in lateral part of the Ce (58.5 +/- 1.9 units in 40-microm-thick section) at the level -2.56 mm. The mean number of Fos-ir neurons was significantly greater also in the lateral and capsular parts of the Ce. The mean number of Fos-ir neurons in the GI/DI was 165.5 +/- 3.2 cells in section. The number and density of NADPH-d reactive neurons was not significantly different in the brain structures of all animal groups studied. The double stained neurons (Fos-ir + NADPH-dr) were registered in medial, basolateral, anterior cortical amygdaloid nuclei and substantia innominata (SI) in rats after realization food-procuring movements. It was found that realization of food-procuring movements by the forelimb during repeated sessions was accompanied with the gradual decline of mean values of the HR (from 5% to 12% of control level) with subsequent renewal of them to the initial values (tonic component). The analysis of dynamics of the HR changes during realization of separate purposeful motion has shown the transient period of the HR suppression (500 ms), which coincided with the terminal phase of grasping of food pellet (phasic component). We suggest that the revealed focuses of localization of Fos-ir neurons in the lateral and medial subregions of amigdaloid Ce and also GI/DI, and SI testified that these structures of brain are involved in generation of the goal-directed motions. Direct projections of these subnuclei (and hypothalamus) to the cardiovascular centers of the medulla determine the associated regulation of the cardiovascular system function in the period of realization of the goal-directed motions in animals.

Parvalbumin-immunoreactive neurons and GABAergic neurons of the basal forebrain project to the rat basolateral amygdala

The basal forebrain (BF) contains a diffuse array of cholinergic and non-cholinergic neurons that project to the cerebral cortex and basolateral nuclear complex of the amygdala (BLC). Previous studies have shown that the GABAergic subpopulation of non-cholinergic corticopetal BF neurons selectively innervates cortical interneurons. Although several investigations in both rodents and primates have indicated that some BF neurons projecting to the BLC are non-cholinergic, there have been no studies that have attempted to identify the neurochemical phenotype(s) of these neurons. The present study combined Fluorogold retrograde tract tracing with immunohistochemistry for two markers of BF GABAergic neurons, parvalbumin (PV) or glutamic acid decarboxylase (GAD), to determine if a subpopulation of BF GABAergic cells projects to the BLC. Injections of Fluorogold confined to the rat BLC, and centered in the basolateral nucleus, produced extensive retrograde labeling in the ventral pallidum and substantia innominata regions of the BF. Although the great majority of retrogradely labeled neurons were not double-labeled, about 10% of these neurons, located mainly along the ventral aspects of the fundus striati and globus pallidus, exhibited immunoreactivity for PV or GAD. The results of this investigation contradict the long-held belief that there is no extra-amygdalar source of GABAergic inputs to the BLC, and indicate that the cortex-like BLC, in addition to the cortex proper, receives inhibitory inputs from the basal forebrain.

Activation of orexin/hypocretin projections to basal forebrain and paraventricular thalamus by acute nicotine

Orexin/hypocretin neurons of the lateral hypothalamus/perifornical area project to a diverse array of brain regions and are responsive to a variety of psychostimulant drugs. It has been shown that orexin neurons are activated by systemic nicotine administration suggesting a possible orexinergic contribution to the effects of this drug on arousal and cognitive function. The basal forebrain and paraventricular nucleus of the dorsal thalamus (PVT) both receive orexin inputs and have been implicated in arousal, attention and psychostimulant drug responses. However, it is unknown whether orexin inputs to these areas are activated by psychostimulant drugs such as nicotine. Here, we infused the retrograde tract tracer cholera toxin B subunit (CTb) into either the basal forebrain or PVT of adult male rats. Seven to 10 days later, animals received an acute systemic administration of (-) nicotine hydrogen tartrate or vehicle and were euthanized 2h later. Triple-label immunohistochemistry/immunofluorescence was used to detect Fos expression in retrogradely-labeled orexin neurons. Nicotine increased Fos expression in orexin neurons projecting to both basal forebrain and PVT. The relative activation in lateral and medial banks of retrogradely-labeled orexin neurons was similar following basal forebrain CTb deposits, but was more pronounced in the medial bank following PVT deposits of CTb. Our findings suggest that orexin inputs to the basal forebrain and PVT may contribute to nicotine effects on arousal and cognition and provide further support for the existence of functional heterogeneity across the medial-lateral distribution of orexin neurons.

Stereological estimates of the basal forebrain cell population in the rat, including neurons containing choline acetyltransferase, glutamic acid decarboxylase or phosphate-activated glutaminase and colocalizing vesicular glutamate transporters

The basal forebrain (BF) plays an important role in modulating cortical activity and influencing attention, learning and memory. These activities are fulfilled importantly yet not entirely by cholinergic neurons. Noncholinergic neurons also contribute and comprise GABAergic neurons and other possibly glutamatergic neurons. The aim of the present study was to estimate the total number of cells in the BF of the rat and the proportions of that total represented by cholinergic, GABAergic and glutamatergic neurons. For this purpose, cells were counted using unbiased stereological methods within the medial septum, diagonal band, magnocellular preoptic nucleus, substantia innominata and globus pallidus in sections stained for Nissl substance and/or the neurotransmitter enzymes, choline acetyltransferase (ChAT), glutamic acid decarboxylase (GAD) or phosphate-activated glutaminase (PAG). In Nissl-stained sections, the total number of neurons in the BF was estimated as approximately 355,000 and the numbers of ChAT-immuno-positive (+) as approximately 22,000, GAD+ approximately 119,000 and PAG+ approximately 316,000, corresponding to approximately 5%, approximately 35% and approximately 90% of the total. Thus, of the large population of BF neurons, only a small proportion has the capacity to synthesize acetylcholine (ACh), one third to synthesize GABA and the vast majority to synthesize glutamate (Glu). Moreover, through the presence of PAG, a proportion of ACh- and GABA-synthesizing neurons also has the capacity to synthesize Glu. In sections dual fluorescent immunostained for vesicular transporters, vesicular glutamate transporter (VGluT) 3 and not VGluT2 was present in the cell bodies of most PAG+ and ChAT+ and half the GAD+ cells. Given previous results showing that VGluT2 and not VGluT3 was present in BF axon terminals and not colocalized with VAChT or VGAT, we conclude that the BF cell population influences cortical and subcortical regions through neurons which release ACh, GABA or Glu from their terminals but which in part can also synthesize and release Glu from their soma or dendrites.

Vesicular glutamate (VGlut), GABA (VGAT), and acetylcholine (VACht) transporters in basal forebrain axon terminals innervating the lateral hypothalamus

The basal forebrain (BF) is known to play important roles in cortical activation and sleep, which are likely mediated by chemically differentiated cell groups including cholinergic, gamma-aminobutyric acid (GABA)ergic and other unidentified neurons. One important target of these cells is the lateral hypothalamus (LH), which is critical for arousal and the maintenance of wakefulness. To determine whether chemically specific BF neurons provide an innervation to the LH, we employed anterograde transport of 10,000 MW biotinylated dextran amine (BDA) together with immunohistochemical staining of the vesicular transporter proteins (VTPs) for glutamate (VGluT1, -2, and -3), GABA (VGAT), or acetylcholine (ACh, VAChT). In addition, we applied triple staining for the postsynaptic proteins (PSPs), PSD-95 with VGluT or Gephyrin (Geph) with VGAT, to examine whether the BDA-labeled varicosities may form excitatory or inhibitory synapses in the LH. Axons originating from BDA-labeled neurons in the magnocellular preoptic nucleus (MCPO) and substantia innominata (SI) descended within the medial forebrain bundle and extended collateral varicose fibers to contact LH neurons. In the LH, the BDA-labeled varicosities were immunopositive (+) for VAChT ( approximately 10%), VGluT2 ( approximately 25%), or VGAT ( approximately 50%), revealing an important influence of newly identified glutamatergic together with GABAergic BF inputs. Moreover, in confocal microscopy, VGluT2+ and VGAT+ terminals were apposed to PSD-95+ and Geph+ profiles respectively, indicating that they formed synaptic contacts with LH neurons. The important inputs from glutamatergic and GABAergic BF cells could thus regulate LH neurons in an opposing manner to stimulate vs. suppress cortical activation and behavioral arousal reciprocally.

Different roles for amygdala central nucleus and substantia innominata in the surprise-induced enhancement of learning

Within most modern learning theories, the discrepancy between expected and obtained outcomes ("prediction error" or "surprise") is a critical determinant of the acquisition of learned associations. The results of studies from many laboratories show that the surprising omission of an expected event may enhance attention to stimuli that remain present, such that subsequent learning about those stimuli is enhanced. A series of reports from our laboratories demonstrated that these surprise-induced enhancements of stimulus associability depend on circuitry that includes the amygdala central nucleus (CeA), the cholinergic neurons in the sublenticular substantia innominata/nucleus basalis magnocellularis (SI/nBM), as well as certain cortical projections of these latter neurons. In this study, we found very different roles for CeA and SI/nBM in surprise-induced enhancements of stimulus associability. In four experiments that used transient inactivation techniques, we found that surprise-induced enhancement of subsequent learning about a stimulus depended on intact CeA function at the time of surprise but not when more rapid learning was subsequently expressed. In contrast, normal SI/nBM function was critical to the expression of enhanced learning but was not necessary when surprise was induced. These data suggest that these two components of the so-called "extended amygdala" serve distinct roles in the encoding and retrieval of information used in modulating attention to stimuli in associative learning. Additional circuitry linking these brain regions may also be important in the maintenance of that information.

Adenosine inhibits basal forebrain cholinergic and noncholinergic neurons in vitro

Adenosine has been proposed as a homeostatic "sleep factor" that promotes the transition from waking to sleep by affecting several sleep-wake regulatory systems. In the basal forebrain, adenosine accumulates during wakefulness and, when locally applied, suppresses neuronal activity and promotes sleep. However, the neuronal phenotype mediating these effects is unknown. We used whole-cell patch-clamp recordings in in vitro rat brain slices to investigate the effect of adenosine on identified cholinergic and noncholinergic neurons of the magnocellular preoptic nucleus and substantia innominata. Adenosine (0.5-100 microM) reduced the magnocellular preoptic nucleus and substantia innominata cholinergic neuronal firing rate by activating an inwardly rectifying potassium current that reversed at -82 mV and was blocked by barium (100 microM). Application of the A1 receptor antagonist 8-cyclo-pentyl-theophylline (200 nM) blocked the effects of adenosine. Adenosine was also tested on two groups of electrophysiologically distinct noncholinergic magnocellular preoptic nucleus and substantia innominata neurons. In the first group adenosine, via activation of postsynaptic A1 receptors, reduced spontaneous firing via inhibition of the hyperpolarization-activated cation current. Blocking the H-current with ZD7288 (20 microM) abolished adenosine effects on these neurons. The second group was not affected by adenosine. These results demonstrate that, in the magnocellular preoptic nucleus and substantia innominata region of the basal forebrain, adenosine inhibits both cholinergic neurons and a subset of noncholinergic neurons. Both of these effects occur via postsynaptic A1 receptors, but are mediated downstream by two separate mechanisms.

Sensitized attentional performance and Fos-immunoreactive cholinergic neurons in the basal forebrain of amphetamine-pretreated rats

BACKGROUND

The consequences of repeated exposure to psychostimulants have been hypothesized to model aspects of schizophrenia. This experiment assessed the consequences of the administration of an escalating dosing regimen of amphetamine (AMPH) on attentional performance. Fos-like immunoreactivity (Fos-IR) in selected regions of these rats' brains was examined to test the hypothesis that AMPH-sensitized attentional impairments are associated with increased recruitment of basal forebrain cholinergic neurons.

METHODS

Rats were trained in a sustained attention task and then treated with saline or in accordance with an escalating dosing regimen of AMPH (1-10 mg/kg). Performance was assessed during the pretreatment and withdrawal periods and following the subsequent administration of AMPH "challenges" (.5, 1.0 mg/kg). Brain sections were double-immunostained to visualize Fos-IR and cholinergic neurons.

RESULTS

Compared with the acute effects of AMPH, AMPH "challenges," administered over 2 months after the pretreatment was initiated, resulted in significant impairments in attentional performance. In AMPH-pretreated and -challenged animals, an increased number of Fos-IR neurons was observed in the basal forebrain. The majority of these neurons were cholinergic.

CONCLUSIONS

The evidence supports the hypothesis that abnormally regulated cortical cholinergic inputs represent an integral component of neuronal models of the attentional dysfunctions of schizophrenia.

Organization of hypocretin/orexin efferents to locus coeruleus and basal forebrain arousal-related structures

Hypocretin/orexin neurons give rise to an extensive projection system, portions of which innervate multiple regions associated with the regulation of behavioral state. These regions include the locus coeruleus, medial septal area, medial preoptic area, and substantia innominata. Evidence indicates that hypocretin modulates behavioral state via actions within each of these terminal fields. To understand better the circuitry underlying hypocretin-dependent modulation of behavioral state, the present study characterized the degree to which there exists: 1) lateralization of hypocretin efferents to basal forebrain and brainstem arousal-related regions, 2) topographic organization of basal forebrain- and brainstem-projecting hypocretin neurons, and 3) collateralization of individual hypocretin neurons to these arousal-related terminal fields. These studies utilized combined immunohistochemical identification of hypocretin neurons with single or double retrograde tracing from the locus coeruleus, medial preoptic area, medial septal area, and substantia innominata. Results indicate that approximately 80% of hypocretin efferents to basal forebrain regions project ipsilaterally, whereas projections to the locus coeruleus are more bilateral (65%). There was a slight preference for basal forebrain-projecting hypocretin neurons to be distributed within the medial half of the hypocretin cell group. In contrast, hypocretin neurons projecting to the locus coeruleus were located primarily within the dorsal half of the hypocretin cell group. Finally, a large proportion of hypocretin neurons appear to project simultaneously to at least two of the examined terminal fields. These latter observations suggest coordinated actions of hypocretin across multiple arousal-related regions.

Separate sets of neurons of the central nucleus of the amygdala project to the substantia innominata and the caudal pontine reticular nucleus in the rat

The central nucleus of the amygdala (CeA) is generally regarded as a control nucleus of subcortical target systems. Due to its widespread projections to different brain areas it is able to modulate emotional behavior of the organism. However, it is still not clear whether single neurons of the CeA project to different areas or to one target area. Injections of the retrograde tracers Fluorogold and True Blue into target regions of the central nucleus of the amygdala, i.e., the substantia innominata (SI) and the caudal pontine reticular nucleus (PNC), revealed overlapping but otherwise distinct neuronal populations within mainly the medial division of the CeA. From our study we conclude that SI and PNC receive input from different subsets of amygdala neurons.

Compartmentation of alpha 1 and alpha 2 GABA(A) receptor subunits within rat extended amygdala: implications for benzodiazepine action

The extended amygdala, a morphological and functional entity within the basal forebrain, is a neuronal substrate for emotional states like fear and anxiety. Anxiety disorders are commonly treated by benzodiazepines that mediate their action via GABA(A) receptors. The binding properties and action of benzodiazepines depend on the alpha-subunit profile of the hetero-pentameric receptors: whereas the alpha1 subunit is associated with benzodiazepine type I pharmacology and reportedly mediates sedative as well as amnesic actions of benzodiazepines, the alpha2 subunit confers benzodiazepine type II pharmacology and mediates the anxiolytic actions of benzodiazepines. We determined the localization of alpha1 and alpha2 subunits within the extended amygdala, identified by secretoneurin immunostaining, to define the morphological substrates for the diverse benzodiazepine actions. A moderate expression of the alpha1 subunit could be detected in compartments of the medial subdivision and a strong expression of the alpha2 subunit throughout the central subdivision. It is concluded that the alpha1 and alpha2 subunits are differentially expressed within the extended amygdala, indicating that this structure is compartmentalized with respect to function and benzodiazepine action.

Distribution of nestin immunoreactivity in the normal adult human forebrain

The distribution of nestin immunoreactivity was studied in the whole normal adult human forebrains using new anti-human nestin mouse monoclonal and rabbit polyclonal antiserum. The nestin immunoreactive cells could be divided into three types according to their morphological characteristics. The first type contained neuron-like nestin immunoreactive cells, distributed in CA1-3 of hippocampus, septum, the nucleus of diagonal band, amygdala and basal nucleus of Meynert. The second type contained astrocyte-like cells, distributed in the subependymal zone and subgranular layer of dentate gyrus. The third type of cells had smaller cell bodies and fewer processes, also distributed in the subependymal zone and subgranular layer of dentate gyrus. Double immunohistochemical staining showed that the nestin positive, neuron-like cells in the nucleus of diagonal band and hippocampus also expressed NSE. However, the astrocyte-like nestin immunoreactive cells of the subependymal zone and subgranular layer of dentate gyrus were not double labeled with GFAP. Although some nestin immunoreactive fibers were distributed in the infundibulum, no nestin-immunoreactive cells were detected in the cortex. These data indicate that nestin exist in the adult human brain outside of the subependymal zone and dentate gyrus and also implies that nestin-immunoreactive cells may play a role in the modulation of basal forebrain function.

The neglected constituent of the basal forebrain corticopetal projection system: GABAergic projections

At least half of the basal forebrain neurons which project to the cortex are GABAergic. Whilst hypotheses about the attentional functions mediated by the cholinergic component of this corticopetal projection system have been substantiated in recent years, knowledge about the functional contributions of its GABAergic branch has remained extremely scarce. The possibility that basal forebrain GABAergic neurons that project to the cortex are selectively contacted by corticofugal projections suggests that the functions of the GABAergic branch can be conceptualized in terms of mediating executive aspects of cognitive performance, including the switching between multiple input sources and response rules. Such speculations gain preliminary support from the effects of excitotoxic lesions that preferentially, but not selectively, target the noncholinergic component of the basal forebrain corticopetal system, on performance in tasks involving demands on cognitive flexibility. Progress in understanding the cognitive functions of the basal forebrain system depends on evidence regarding its main noncholinergic components, and the generation of such evidence is contingent on the development of methods to manipulate and monitor selectively the activity of the GABAergic corticopetal projections.

Wake-promoting and sleep-suppressing actions of hypocretin (orexin): basal forebrain sites of action

The hypocretins (orexins) are a newly identified peptide family comprised of two peptides, hypocretin-1 and hypocretin-2. Recent observations suggest an involvement of these peptides in the regulation of behavioral state. For example, these peptides are found in a variety of brain regions associated with the regulation of forebrain neuronal and behavioral activity states. Furthermore, when infused into the lateral ventricles in awake animals, hypocretin-1 elicits increased duration of waking beyond that observed in vehicle-treated animals. Previous studies have been limited to an examination of the sleep-wake effects of hypocretin-1 in awake animals. Currently, the sleep-wake effects of hypocretin-2 and the extent to which hypocretins can initiate waking in the sleeping animal remain unclear. To better characterize the wake-promoting actions of the hypocretins, the current studies examined the sleep-wake effects of varying doses (0.007, 0.07 and 0.7 nmol) of hypocretin-1 and hypocretin-2 when administered into sleeping rats (e.g. remote-controlled infusions). Infusions of hypocretin-1 and hypocretin-2 into the lateral ventricles elicited a short latency (0.7 nmol hypocretin-1; 93+/-30 s from the start of the 120-s infusion) increase in electroencephalographic, electromyographic, and behavioral indices of waking. These infusions also produced substantial decreases in slow-wave and rapid-eye movement sleep. Hypocretin-1 was more potent than hypocretin-2 in these actions. Interestingly, hypocretin-1 infused into the fourth ventricle elicited less robust waking which occurred with a longer latency than infusions into the lateral ventricles. These latter observations suggest a forebrain site of action participates in hypocretin-1-induced waking. Within the forebrain, a variety of basal forebrain structures, including the medial preoptic area, the medial septal area and the substantia innominata, receive a moderate hypocretin innervation. Therefore, additional studies examined the sleep-wake effects of bilateral hypocretin-1 infusions into these basal forebrain structures. Robust increases in waking were observed following infusions into, but not outside, the medial septal area, the medial preoptic area and the substantia innominata. These results indicate a potentially prominent role of hypocretins in sleep-wake regulation via actions within certain basal forebrain structures and are consistent with studies indicating a prominent role of hypocretins in sleep/arousal disorders.

Evidence for target preferences by cholinergic axons originating from different subdivisions of the basal forebrain

Possible target preferences of basal forebrain cholinergic neurons were studied in organotypic slice cultures. Cholinergic neurons in slices of medial septum or substantia innominata send axons into both hippocampus and neocortex when co-cultured together. However, septal cholinergic axons course through adjacent slices of neocortex to reach and branch densely in slices of hippocampus, but septal axons seldom grow beyond adjacent hippocampal tissue to reach neocortex. In contrast, cholinergic axons from substantia innominata commonly grow through hippocampus to reach neocortex, and also grow through neocortex to reach hippocampus, with similar branching densities in each target. The greater density of septal axonal branches in hippocampus than in neocortex suggests a preference of septal axons for the hippocampal target.

Projections from the nociceptive area of the central nucleus of the amygdala to the forebrain: a PHA-L study in the rat

The lateral capsular division (CeLC) of the central nucleus (Ce) of the amygdala, in the rat, has been shown to be the main terminal area of a spino(trigemino)-parabrachio-amygdaloid nociceptive pathway [Bernard & Besson (1990) J. Neurophysiol. 63, 473-490; Bernard et al. (1992) J. Neurophysiol. 68, 551-569; Bernard et al. (1993) J. Comp. Neurol. 329, 201-229]. The projections to the forebrain from the CeLC and adjacent regions were studied in the rat by using microinjections of Phaseolus vulgaris leucoagglutinin (PHA-L) restricted in subdivisions of the Ce and the basolateral amygdaloid nucleus anterior (BLA). Our data showed that the entire CeLC projects primarily and extensively to the substantia innominata dorsalis (SId). The terminal labelling is especially dense in the caudal aspect of the SId. The other projections of the CeLC in the forebrain were dramatically less dense. They terminate in the bed nucleus of the stria terminalis (BST) and the posterior hypothalamus (pLH). No (or only scarce) other projections were found in the remaining forebrain areas. The Ce lateral division (CeL) and the Ce medial division (CeM), adjacent to the CeLC, also project to the SId with slightly lower density labelling. However, contrary to the case of the CeLC, both the CeL and the CeM extensively project to the ventrolateral subnucleus of the BST (BSTvl) with a few additional terminals found in other regions of the lateral BST. Only the CeM projects densely to both the interstitial nucleus of the posterior limb of the anterior commissure and the caudal most portion of the pLH. The projections of the BLA are totally different from those of the Ce as they terminate in the dorsal striatum, the accumbens nucleus, the olfactory tubercle, the nucleus of olfactory tract and the rostral pole of the cingulate/frontal cortex. This study demonstrates that the major output of the nociceptive spino(trigemino)-parabrachio-CeLC pathway is to the SId. It is suggested that the CeLC-SId pathway could have an important role in anxiety, aversion and genesis of fear in response to noxious stimuli.

Aggregates of cAMP-dependent kinase RIalpha characterize a type of cholinergic neurons in the rat brain

Acetylcholine is synthesized by different types of neurons, showing a distinct biochemical phenotype. Aggregates of RIalpha regulatory subunit of cAMP-dependent protein kinases are visualized by immunohistochemistry only in some cholinergic neurons, since they tightly colocalize with two different markers, choline acetyltransferase (ChAT) and vesicular acetylcholine transporter (VAChT). These neurons are present mainly in brain areas related to the limbic system. None of the other regulatory subunits of cAMP dependent kinases colocalize with cholinergic markers.

Cells containing immunoreactive estrogen receptor-alpha in the human basal forebrain

The distribution of estrogen receptor protein-alpha (ER-alpha)-containing cells in the human hypothalamus and adjacent regions was studied using a monoclonal antibody (H222) raised against ER-alpha derived from MCF-7 human breast cancer cells. Reaction product was found in restricted populations of neurons and astrocyte-like cells. Neurons immunoreactive for ER-alpha were diffusely distributed within the basal forebrain and preoptic area, infundibular region, central hypothalamus, basal ganglia and amygdala. Immunoreactive astrocyte-like cells were noted within specific brain regions, including the lamina terminalis and subependymal peri-third-ventricular region. These data are consistent with the location of estrogen receptors in the basal forebrain of other species and the known effects of estrogens on the cellular functions of both neurons and supporting elements within the human hypothalamus and basal forebrain.

Neurotransmitter characteristics of neurons projecting to the supramammillary nucleus of the rat

Retrograde labelling was combined with immunohistochemistry to localize neurons containing choline acetyltransferase, gamma-aminobutyric acid (GABA), glutamate, serotonin, somatostatin, Leu-enkephalin, neurotensin, and substance P-immunoreactivity in neurons projecting to the supramammillary nucleus in the rat. Injections of wheat germ agglutinin conjugated to horseradish peroxidase (WGA-HRP) into the supramammillary nucleus resulted in retrogradely labelled neurons in the medial septal nucleus, the nuclei of the diagonal band of Broca, the infralimbic cortex, the medial and lateral preoptic nucleus, the subiculum, the laterodorsal tegmental nucleus, the compact subnucleus of the central superior nucleus and the dorsal raphe nucleus. In the medial septal nucleus and in the nuclei of the diagonal band of Broca, 80-85% of WGA-HRP- labelled neurons (30-40 per section) were also immunoreactive for choline acetyltransferase and small numbers of WGA-HRP-labelled neurons were immunoreactive for GABA, glutamate, neurotensin or substance P. In the medial preoptic nucleus, 85-90% of retrogradely labelled neurons (25-30 per section) were immunoreactive for somatostatin and a few WGA-HRP-labelled neurons displayed neurotensin-immunoreactivity. In the rostroventral part of the subiculum, small numbers of retrogradely labelled neurons were also immunoreactive for neurotensin or for glutamate. In the laterodorsal tegmental nucleus, 90% of WGA-HRP-labelled neurons (20-25 per section) were immunoreactive for choline acetyltransferase and small numbers of retrogradely labelled neurons also displayed substance P immunoreactivity. In the compact subnucleus of the central superior nucleus, 50-60% of retrogradely labelled neurons (15-20 per section) were also immunolabelled for GABA and approximately 30-40% of WGA-HRP-labelled neurons (10-12 per section) were immunoreactive for Leu-enkephalin. The compact subnucleus of the central superior nucleus also contained small numbers of retrogradely labelled neurons that displayed neurotensin immunoreactivity. In the dorsal raphe nucleus, 80-85% of WGA-HRP- labelled neurons (30-40 per section) were also immunoreactive for serotonin and small numbers of retrogradely labelled neurons displayed neurotensin or glutamate immunoreactivity. These results suggest that the multiple neurochemicals contained in ascending and descending projections to the SuM participate in complex interactions in the transmission process of SuM neurons.

Preservation of nucleus basalis neurons containing choline acetyltransferase and the vesicular acetylcholine transporter in the elderly with mild cognitive impairment and early Alzheimer's disease

Immunocytochemistry for choline acetyltransferase (ChAT) and the vesicular acetylcholine transporter (VAChT) was used to examine the expression of these linked cholinergic markers in human basal forebrain, including cases with early stages of Alzheimer's disease (AD). Previous neurochemical studies have measured decreased ChAT activity in terminal fields, but little change or even increased levels of VAChT. To determine total cholinergic neuron numbers in the nucleus basalis of Meynert (nbM), stereologic methods were applied to tissue derived from three groups of individuals with varying levels of cognition: no cognitive impairment (NCI), mild cognitive impairment (MCI), and early-stage Alzheimer's disease (AD). Both markers were expressed robustly in nucleus basalis neurons and across all three groups. On average, there was no significant difference between the number of ChAT- (210,000) and VAChT- (174, 000) immunopositive neurons in the nbM per hemisphere in NCI cases for which the biological variation was calculated to be 17%. There was approximately a 15% nonsignificant reduction in the number of cholinergic neurons in the nbM in the AD cases with no decline in MCI cases. The number of ChAT- and VAChT-immunopositive neurons was shown to correlate significantly with the severity of dementia determined by scores on the Mini-Mental State Examination, but showed no relationship to apolipoprotein E allele status, age, gender, education, or postmortem interval when all clinical groups were combined or evaluated separately. These data suggest that cholinergic neurons, and the coexpression of ChAT and VAChT, are relatively preserved in early stages of AD.

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

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

m2 muscarinic receptor immunolocalization in cholinergic cells of the monkey basal forebrain and striatum

Pharmacological studies have suggested that the m2 muscarinic receptor functions as an autoreceptor in the cholinergic axons which innervate the cerebral cortex and striatum. To test this hypothesis in the macaque monkey, we used a subtype-specific antibody to the m2 muscarinic receptor. Immunoreactive cells were well visualized in the nucleus basalis, where some of these cells displayed dense m2 immunoreactivity, while others were lightly labeled. This heterogeneity of labeling intensity was not based on peculiarities of the methodology, because cholinergic cells of the striatum expressed uniformly dense m2 immunoreactivity. Concurrent labeling with choline acetyltransferase immunoreactivity proved that most of the heavily m2-labeled cells in the nucleus basalis were also choline acetyl-transferase positive. The findings demonstrate that at least 10-25% of the cholinergic neurons in the nucleus basalis of the monkey are densely m2 immunoreactive. In the striatum, concurrent labeling demonstrated that the majority, if not all, choline acetyltransferase-positive cells also contained m2 immunoreactivity. In addition, these experiments identified a population of smaller striatal cells which were m2 immunoreactive and choline acetyltransferase negative. Consecutive labeling with m2 immunoreactivity and NADPH-diaphorase histochemistry demonstrated that many of these m2-immunoreactive non-cholinergic neurons belonged to the population of nitric oxide-synthesizing medium aspiny neurons. The findings indicate that the m2 muscarinic receptor may be expressed at high levels in only a subset of cholinergic basal forebrain neurons. In contrast, m2 receptors appear to be expressed by all cholinergic cells of the striatum.

Nucleus subputaminalis (Ayala): the still disregarded magnocellular component of the basal forebrain may be human specific and connected with the cortical speech area

The small magnocellular group located within the rostrolateral extension of the basal forebrain was named and described as the nucleus subputaminalis in the human and chimpanzee brain by Ayala. Analysis of cytoarchitectonic and cytochemical characteristics of this cell group has been largely disregarded in both classical and more current studies. We examined the nucleus subputaminalis in 33 neurologically normal subjects (ranging from 15 weeks of gestation to 71 years-of-age) by using Nissl staining, choline acetyltransferase immunohistochemistry, acetyl cholinesterase histochemistry and nerve growth factor receptor immunocytochemistry. In addition, we applied reduced nicotinamide adenine dinucleotide phosphate-diaphorase histochemistry and calbindin-D28k immunocytochemistry in three neurologically normal subjects. At the most rostrolateral levels we describe the previously poorly characterized component of the lateral (periputaminal) subdivision of the subputaminal nucleus, which may be human specific since it is not described in non-human primates. Moreover, we find the human subputaminal nucleus best developed at the anterointermediate level, which is the part of the basal nucleus that is usually much smaller or missing in monkeys. The location of subputaminal cholinergic neurons within the frontal lobe, the ascension of their fibers through the external capsule towards the inferior frontal gyrus, the larger size of the subputaminal nucleus on the left side at the most rostral and anterointermediate levels and the most protracted development among all magnocellular aggregations within the basal forebrain strongly suggest that they may be connected with the cortical speech area. These findings give rise to many hypotheses about the possible role of the subputaminal nucleus in various neurodegenerative, neurological and psychiatric disorders, particularly Alzheimer's disease and primary progressive aphasia. Therefore, future studies on the basal forebrain should more carefully investigate this part of the basal nucleus.

Calcium channels in the GABAergic presynaptic nerve terminals projecting to meynert neurons of the rat

Effects of selective Ca2+ channel blockers on GABAergic inhibitory postsynaptic currents (IPSCs) were studied in the acutely dissociated rat nucleus basalis of Meynert (nBM) neurons attached with nerve endings, namely, the "synaptic bouton" preparation, and in the thin slices of nBM, using nystatin perforated and conventional whole-cell patch recording modes, respectively. In the synaptic bouton preparation, nicardipine (3 x 10(-6) M) and omega-conotoxin-MVIIC (3 x 10(-6) M) reduced the frequency of spontaneous postsynaptic currents by 37 and 22%, respectively, whereas omega-conotoxin-GVIA had no effect. After blockade of L- and P/Q-type Ca2+ channels, successive removal of Ca2+ from external solution had no significant effect on the residual spontaneous activities, indicating that N-, R-, and T-type Ca2+ channels are not involved in the spontaneous GABA release. Thapsigargin, but not ryanodine, increased the frequency of spontaneous IPSCs in both the synaptic bouton and slice preparations, suggesting the partial contribution of the intracellular Ca2+ storage site to the spontaneous GABA release. In contrast, omega-conotoxin-GVIA (3 x 10(-6) M) and omega-conotoxin-MVIIC (3 x 10(-6) M) suppressed the evoked IPSCs by 31 and 37%, respectively, but nicardipine produced no significant effect. The residual evoked currents were abolished in Ca2+-free external solution but not in the external solution containing 10(-5) M Ni2+, suggesting the involvement of N-, P/Q-, and R-type Ca2+ channels but not L- and T-type ones in the evoked IPSCs. Neither thapsigargin nor ryanodine had any significant effects on the evoked IPSCs. It was concluded that Ca2+ channel subtypes responsible for spontaneous transmitter release are different from those mediating the transmitter release evoked by nerve stimulation.

Lesions of the nucleus basalis magnocellularis do not impair prepulse inhibition and latent inhibition of fear-potentiated startle in the rat

The present study tested if lesions of the nucleus basalis magnocellularis (NBM) affect prepulse inhibition (PPI) of the acoustic startle response and latent inhibition (LI) of fear-potentiated startle. The NBM is known to play an important role in learning and memory. Recently, the interest of research focused on its role in attentional and response selection processes. We here tested the effect of excitotoxic NBM-lesions on PPI, a phenomenon of sensorimotor gating that occurs at early stages of information processing. We also assessed the lesion effects on LI, a phenomenon of reduced conditioning after stimulus preexposure that can be used to measure selective attention. Bilateral infusions into the NBM of 80 nmol of quinolinic acid markedly reduced the number of choline acetyltransferase immunopositive neurons in the NBM and lead to a pronounced reduction of acetylcholine esterase in the cortex and the amygdala. However, no effects on PPI, fear-conditioning, or LI of fear-potentiated startle were found. Therefore, we conclude that there is no NBM-driven attentional or response selection process involved in PPI. Furthermore, the simple association learning in the classical conditioning paradigm used for fear-potentiated startle or LI is unaffected by NBM-lesions.

Characterization of outward currents in neurons of the avian nucleus magnocellularis

Characterization of outward currents in neurons of the avian nucleus magnocellularis. J. Neurophysiol. 80: 2824-2835, 1998. Neurons of the nucleus magnocellularis (NM) preserve the timing of auditory signals through the convergence of a variety of voltage- and ligand-gated ion channels. To understand better how these channels interact, we have characterized the kinetics, voltage sensitivity, and pharmacology of outward currents of NM neurons in brain slices. The reversal potential (Erev) of outward currents varied with potassium concentration as expected for currents carried by potassium. However, Erev was consistently more positive than the Nernst potential for potassium (EK). Deviation of Erev from the calculated EK most likely arose from potassium accumulation in extracellular spaces by potassium conductances active at rest and during depolarizing steps. Three outward potassium currents were studied that varied in voltage and pharmacological sensitivity. A tetraethylammonium (TEA)-sensitive, high-threshold current was activated within 1-5 ms of the onset of depolarization, with a half-maximal activation voltage (V1/2) of -19 mV. It was blocked partially by 4-aminopyridine (4-AP) and was the dominant ionic conductance of NM neurons. A dendrotoxin-I (DTX) and 4-AP-sensitive, low-threshold current had a V1/2 of -58 mV, rapid activation kinetics, and only partial inactivation, with decay time constants between 20 and 100 ms. A rapidly inactivating current was observed that was resistant to TEA and DTX and was blocked by intracellular Cs+. The transient current was inactivated almost completely at the resting potential. The onset of inactivation was fastest at potentials negative to those that caused activation. When intracellular K+ was replaced by Cs+, large inward and outward currents were obtained that corresponded respectively to the above-mentioned DTX- and TEA-sensitive currents. Outward, TEA-sensitive current was carried by Cs+, with a PCs/PK of approximately 0.1. In current-clamped neurons, DTX induced repetitive firing and increased membrane time constant near rest but had little effect on action potential duration. These studies indicate that a low-threshold, DTX-sensitive current plays a key role in making NM neurons highly responsive to the onset and offset of synaptic stimuli.

Differential changes of nicotinic receptors in the rat brain following ibotenic acid and 192-IgG saporin lesions of the nucleus basalis magnocellularis

The basal forebrain cholinergic neurons are implicated in the pathogenesis of neurodegenerative diseases including Alzheimer's disease (AD). The nicotinic acetylcholine receptors (nAChRs) have been found to be significantly afflicted in AD. To study the underlying mechanisms for dysfunction of the basal forebrain cholinergic neurons development of suitable animal models is warranted. In this study we investigated the effects of bilateral lesions of the nucleus basalis magnocellularis on nAChRs in the rat brain using the cholinergic system selective immunotoxin 192-IgG saporin and non-selective excitotoxin ibotenic acid. Changes in nAChRs were measured by 3H-cytisine and 3H-epibatidine, two ligands with different selectivity for nAChRs subtypes. In the parietal cortex of ibotenic acid lesioned rates, the choline acetyltransferase activity (ChAT) was decreased by 24% while no changes were detected in the frontal cortex or hippocampus. Similarly, a 40% decrease was observed in the number of nAChRs labelled by 3H-cytisine, but not by 3H-epibatidine, in the parietal cortex, while no changes were found in the frontal cortex or hippocampus. Although the 192-IgG saporin induced lesions reduced the ChAT activity in the frontal cortex, parietal cortex and hippocampus by 77, 50 and 21%, respectively, no changes were observed in the number of nAChRs as studied by 3H-cytisine or 3H-epibatidine. The results indicate a difference in vulnerability of the cortical nAChR subtypes to experimental lesions of the nucleus basalis magnocellularis. The findings in this study suggest that a major portion of the nAChRs might be located on non-cholinergic neurons in the brain.

Effects of cholinergic depletion on evoked activity in the cortex of young and aged rats

Degeneration of cholinergic neurons in the basal forebrain is a neural marker of Alzheimer's disease and is associated with perceptual and cognitive deficits. An idea that has attracted scientific scutiny is that aging makes the brain more susceptible to neurodegenerative diseases such as Alzheimer's. The purpose of this study was to compare the effects of the loss of cholinergic input from nucleus basalis of Meynert on evoked activity in the posteromedial barrel subfield of the somatosensory cortex in young (2-2.5 months) and aged (28-30 months) male Fisher hybrid rats. The mean firing rate and receptive fields of single neurons in the posteromedial barrel subfield of the somatosensory cortex were examined after selective lesions of cholinergic neurons in the nucleus basalis of Meynert with an immunotoxin. IgG 192-saporin. Functional properties of single neurons in young animals were affected much more significantly by cholinergic depletion than those in aged animals. In cholinergic-depleted young animals, the mean firing rate of evoked activity and receptive field of posteromedial barrel subfield neurons were significantly decreased. Cholinergic depletion caused a 14% decrease in evoked activity and a 33% increase in receptive field size in young animals. The mean firing rate and receptive field of single neurons were not affected by cholinergic depletion in aged animals. It is concluded that functional properties of cortical sensory neurons in young animals are more vulnerable to cholinergic depletion than are those of aged animals and that cholinergic depletion does not further impact the properties of neurons exposed to the processes of aging.

The serotonin inhibition of high-voltage-activated calcium currents is relieved by action potential-like depolarizations in dissociated cholinergic nucleus basalis neurons of the guinea-pig

The aim of the present study was to investigate whether the voltage-dependent inhibition of calcium currents by serotonin 5-HT1A agonists can be alleviated (facilitated) by action potential-like depolarizations. In dissociated cholinergic basal forebrain neurons using whole-cell recordings, it is shown that a selective serotonin 5-HT1A agonist (8-OH-DPAT) predominantly blocks N-type HVA calcium current, although a minor reduction of P-type current was also observed. The inhibition may principally occur through Gi-Go subtypes of G-proteins because it was prevented by N-ethylmaleimide, a substance known to block specifically pertussis-sensitive G-proteins. The inhibitory effect of 8-OH-DPAT on calcium currents is voltage-dependent because it was alleviated by long-lasting depolarizing prepulses. Interestingly, the inhibition could also be reversed by prepulses made-up of action potential-like depolarizations that were given at a frequency of 200 Hz. This observation may have important implications during periods of high-frequency rhythmic bursts, a firing pattern that is prevalent in cholinergic basal forebrain neurons.

Neural correlates of singing behavior in male zebra finches (Taeniopygia guttata)

This study examined the relationship between the volumes of four song control nuclei: the high vocal center (HVC), the lateral part of the magnocellular nucleus of the anterior neostriatum (IMAN), Area X, and the robust nucleus of the archistriatum (RA), as well as syrinx mass, with several measures of song output and song complexity in male zebra finches (Taeniopygia guttata). Male zebra finches' songs were recorded in standardized recording sessions. The syrinx and brain were subsequently collected from each bird. Volumes of the song control nuclei were reconstructed by measuring the cross-sectional area of serial sections. Syrinx mass was positively correlated with RA volume. The volume of IMAN was negatively related to element repertoire size and the number of elements per phrase. We found no other correlations between brain and behavioral measures. This study, combined with others, indicates that the evidence for a general relationship among songbirds between HVC volume and song complexity is equivocal. There are clear species differences in this brain-behavior correlation.

Lectin staining in the basal nucleus (Meynert) and the hypothalamic tuberomamillary nucleus of the developing human prosencephalon

Previous studies have demonstrated that extracellular matrix glycoconjugates, shown by lectin-histochemistry with Vicia villosa agglutinin (VVA) and peanut agglutinin (PNA) as so-called perineuronal nets, play an important role in brain maturation. Concanavalin A (ConA) binding to neuronal surface glycoconjugates may be a marker of synaptic junctions. The present study was done to demonstrate the binding sites of these lectins in two functionally related nuclei of the prosencephalon, the basal nucleus (Meynert) and the hypothalamic tuberomamillary nucleus. Fetal brains of 16-36 weeks of gestation were examined by using VVA, PNA, and ConA to determine appearance and distribution patterns of specific lectin-binding sites on glycoconjugates during fetal brain development. The basal nucleus and the tuberomamillary nucleus showed a characteristic "cellular staining" that may have been due to cytoplasmatic labeling, surface labeling, or both. Lectin-staining occurred much earlier in the basal nucleus than in the tuberomamillary nucleus. Although all three lectins were bound to neurons of the basal nucleus, only ConA-positive neurons were observed in the tuberomamillary nucleus. In conclusion, lectin-labeled cells most probably represent projection neurons that are GABAergic (tuberomamillary nucleus) or cholinergic (basal nucleus). Labeling with the three lectins demonstrated nuclear-specific staining patterns that occur early in fetal development and gradually increase. Binding sites for lectins characterizing perineuronal nets (VVA, PNA) occurred only in the basal nucleus, whereas binding sites for ConA on neuronal-surface glycoconjugates, which seem to play a role in early synaptogenesis, were present in the basal and the tuberomamillary nucleus. The basal nucleus, however, expressed ConA binding sites distinctly earlier, probably indicating early arriving afferents.

Distinctive morphological features of a subset of cortical neurons grown in the presence of basal forebrain neurons in vitro

Basal forebrain cholinergic neurons (BFCNs) provide the major subcortical source of cholinergic input to cerebral cortex and play an important role in regulating cortical activity. The present study examined the ability of BFCNs to influence neocortical neuronal growth by examining effects of the presence of BFCNs on certain cortical neurons grown under the controlled conditions of dissociated cell culture. Initial experiments demonstrated distinctive morphological features of a population of neurons (labeled with SMI-32, a monoclonal antibody to nonphosphorylated neurofilament proteins that labels pyramidal neurons in vivo) in cocultures containing basal forebrain (BF) and cortical cells. These neurons (large neurons immunoreactive for SMI-32 [SMI-32(+) neurons]) were characterized as having extensive axons, greater soma size, and more dendritic growth than did most SMI-32(+) neurons in the cultures. Staining for SMI-32 in cocultures in which the cortical neurons were labeled with a fluorescent marker before adding the BF cells indicated that virtually all large SMI-32(+) neurons were of cortical origin. Eliminating BFCNs with the selective cholinergic immunotoxin 192 IgG-saporin resulted in a >80% decrease in the number of large SMI-32(+) neurons, although causing little damage to other cells in the treated cultures; this suggests that survival or maintenance of large SMI-32(+) neurons may depend on ongoing trophic support from BFCNs. Thus, present findings suggest that BFCNs may provide powerful growth- and/or survival-enhancing signals to a subset of cortical neurons.

Morphological and electrophysiological characteristics of noncholinergic basal forebrain neurons

Cholinergic neurons in the basal forebrain are the focus of considerable interest because they are severely affected in Alzheimer's disease. However, both cholinergic and noncholinergic neurons are intermingled in this region. The goal of the present study was to characterize the morphology and in vivo electrophysiology of noncholinergic basal forebrain neurons. Neurons in the ventral pallidum and substantia innominata were recorded extracellularly, labeled juxtacellularly with biocytin and characterized for the presence of choline acetyltransferase immunoreactivity. Two types of ventral pallidal cells were observed. Type I ventral pallidal neurons had axons that rarely branched near the cell body and tended to have smaller somata and lower spontaneous firing rates than did type II ventral pallidal neurons, which displayed extensive local axonal arborizations. Subtypes of substantia innominata neurons could not be distinguished based on axonal morphology. These noncholineregic neurons exhibited local axon arborizations along a continuum that varied from no local collaterals to quite extensive arbors. Substantia innominata neurons had lower spontaneous firing rates, more variable interspike intervals, and different spontaneous firing patterns than did type II ventral pallidal neurons and could be antidromically activated from cortex or substantia nigra, indicating that they were projection neurons. Ventral pallidal neurons resemble, both morphologically and electrophysiologically, previously described neurons in the globus pallidus, whereas the substantia innominata neurons bore similarities to isodendritic neurons of the reticular formation. These results demonstrate the heterogeneous nature of noncholinergic neurons in the basal forebrain.

Selective inhibition of magnocellular vasopressin neurons by hypoosmolality: effect on histamine- and stress-induced secretion of adrenocorticotropin and prolactin

We investigated the effect of selective inhibition of magnocellular arginine vasopressin (AVP) and oxytocin neurons on histamine (HA)- and restraint-stress-induced adrenocorticotropin (ACTH) and prolactin (PRL) secretion in conscious male rats. The inhibition of magnocellular neurons was obtained by inducing chronic hypoosmolality via continuous exposure of the rats to the AVP V2 receptor agonist 1-deamino(8-D-arginine)vasopressin (DDAVP) which was released from osmotic pumps implanted subcutaneously. In DDAVP-treated rats, plasma osmolality and sodium concentration were 273 mosm/l and 130 mmol/l, respectively. In control rats, the corresponding values were 291 mosm/l and 139 mmol/l. HA (270 nmol) administered intracerebroventricularly or 5 min of restraint stress stimulated ACTH and PRL secretion 4- to 11-fold in normoosmolar rats. In hypoosmolar rats, the HA-induced ACTH response was inhibited more than 40% whereas the restraint-stress-induced ACTH response was unaffected. Conversely, the PRL response to HA in hypoosmolar rats was unaffected whereas the PRL response to restraint stress was inhibited by 40%. In summary, chronic hypoosmolality inhibits HA-induced ACTH and restraint-stress-induced PRL secretion indicating involvement of magnocellular AVP in these responses.

Localization of the m2 muscarinic acetylcholine receptor protein and mRNA in cortical neurons of the normal and cholinergically deafferented rhesus monkey

The m2 muscarinic acetylcholine receptor in the cerebral cortex has traditionally been thought of as an autoreceptor located on cholinergic fibers that originate from neurons in the nucleus basalis of Meynert. We now provide evidence for widespread localization of the m2 receptor in noncholinergic neurons and fibers of the cerebral cortex. The cellular and subcellular distribution of the m2 receptor protein and mRNA were examined in normal monkeys and in monkeys in which the cortical cholinergic afferents were selectively lesioned by injection of the specific immunotoxin, anti-p75NTR-saporin into the nucleus basalis. Both in normal and immunolesioned monkeys, the m2 mRNA and protein were localized in pyramidal and nonpyramidal neurons. In pyramidal neurons, membrane-associated receptor immunoreactivity was found exclusively in dendritic spines receiving asymmetric synapses, indicating that the m2 receptor may modulate excitatory neurotransmission at these sites. In nonpyramidal neurons, the m2 immunoreactivity was present along the cytoplasmic surface of membranes in cell bodies, dendrites and axons. Both in pyramidal and nonpyramidal neurons of normal and lesioned monkeys, the m2 receptor was located peri- and extra-synaptically, suggesting that it may be contacted by acetylcholine via volume transmission. The localization of the m2 receptor in cortical neurons and the sparing of m2 immunoreactivity in lesioned monkeys indicates that the m2 receptor is synthesized largely within the cortex and/or is localized to noncholinergic terminals of either intrinsic or extrinsic origin. These findings open the possibility that the loss of the m2 receptor in Alzheimer's disease may in part be due to degenerative changes in m2 positive neurons of the cortex rather than entirely due to the loss of autoreceptors.

Pharmacological characterization and differentiation of non-cholinergic nucleus basalis neurons in vitro

Using intracellular recordings in guinea pig brain slices, the pharmacology of electrophysiologically identified and immunohistochemically confirmed non-cholinergic nucleus basalis neurons was studied to determine their response to the major neurotransmitters of the subcortical afferents to this region. The cells were differentiated into three types: Type A cells (approximately 44%) were depolarized by noradrenaline (NA) and muscarine, Type B cells (approximately 23%) were depolarized by NA but hyperpolarized by muscarine, and Type C cells (approximately 15%) were hyperpolarized by both agonists. These cell types were also differentially responsive to serotonin (hyperpolarizing B, C) and histamine (depolarizing A, B). Accordingly, the non-cholinergic neurons share certain discharge properties but appear nonetheless to comprise distinct types which respond differentially to the major modulatory neurotransmitters and thus play potentially different roles in cortical modulation across the sleep-wake cycle.

Developmental changes of GABA(A) receptor-chloride channels in rat Meynert neurons

The developmental changes of GABA(A) receptors were investigated in Meynert neurons freshly dissociated from day 0, 2 week-, and 6 month-old rats using both nystatin and gramicidin perforated patch recording modes under voltage-clamp conditions. The age-related changes in the current amplitude and threshold concentration in the concentration-response relationships for GABA indicated the developmental alteration of the GABA(A) receptor subunits and the channel density. The GABA-induced E(Cl-) measured by the gramicidin perforated patch mode shifted to more negative with development. The decay time constant of GABAergic inhibitory postsynaptic spontaneous currents (sIPSCs) in the synaptic active zone accelerated with aging. The GABA-induced currents were potentiated in a concentration dependent manner in the presence of benzodiazepine (BZP) agonists, diazepam (DZP) and zolpidem (ZPM). The potentiation rate of DZP on the GABA(A) response decreased with aging, but not in the case of ZPM, which demonstrated a stronger action in the aging rat neurons. These results suggested that the GABA(A) receptor x Cl- channel complexes may thus change both the assembly and interaction of subunits as well as their functional roles with aging.

Cosmic ray hit frequencies in critical sites in the central nervous system

One outstanding question to be addressed in assessing the risk of exposure to space travelers from galactic cosmic rays (GCR) outside the geomagnetosphere is to ascertain the effects of single heavy-ion hits on cells in critical regions of the central nervous system (CNS). As a first step toward this end, it is important to determine how many "hits" might be received by a neural cell in several critical CNS areas during an extended mission outside the confines of the earth's magnetic field. Critical sites in the CNS: the macula, and an interior brain point (typical of the genu, thalamus, hippocampus and nucleus basalis of Meynert) were chosen for the calculation of hit frequencies from galactic cosmic rays for a mission to Mars during solar minimum (i.e., at maximum cosmic-ray intensity). The shielding at a given position inside the body was obtained using the Computerized Anatomical Man (CAM) model, and a radiation transport code which includes nuclear fragmentation was used to calculate yearly fluences at the point of interest. Since the final Mars spacecraft shielding configuration has not yet been determined, we considered the minimum amount of aluminum required for pressure vessel-wall requirements in the living quarters of a spacecraft, and a typical duty area as a pressure vessel plus necessary equipment. The conclusions are: (1) variation of the position of the "target site" within the head plays only a small role in varying hit frequencies; (2) the average number of hits depends linearly on the cross section of the critical portion of the cell assumed in the calculation; (3) for a three-year mission to Mars at solar minimum (i.e., assuming the 1977 spectrum of galactic cosmic rays), 2% or 13% of the "critical sites" of cells in the CNS would be directly hit at least once by iron ions, depending on whether 60 micrometers2 or 471 micrometers2 is assumed as the critical cross sectional area; and (4) roughly 6 million out of some 43 million hippocampal cells and 55 thousand out of 1.8 million thalamus cell nuclei would be directly hit by iron ions at least once on such a mission for space travelers inside a simple pressure vessel. Also, roughly 20 million out of 43 million hippocampal cells and 230 thousand out of 1.8 million thalamus cell nuclei would be directly hit by one or more particles with z > or = 15 on such a mission.

Modulation of cholinergic nucleus basalis neurons by acetylcholine and N-methyl-D-aspartate

Known to exert an important modulatory influence on the cerebral cortex, the cholinergic neurons of the basal forebrain are modulated in turn by neurotransmitters which may include acetylcholine released from processes of brainstem or forebrain neurons. In the present study, we examined the effect of carbachol, a non-specific cholinergic agonist, either alone or in the presence of N-methyl-D-aspartate upon electrophysiologically identified cholinergic basalis neurons in guinea-pig basal forebrain slices. Carbachol produced a direct postsynaptic hyperpolarization, accompanied by a decrease in membrane resistance. Muscarine could mimic this hyperpolarizing effect, whereas nicotine produced a direct postsynaptic membrane depolarization. The interaction of carbachol with N-methyl-D-aspartate was subsequently tested since, in a prior study, N-methyl-D-aspartate was shown to induce rhythmic bursting in cholinergic cells when they were hyperpolarized by continuous injection of outward current. Applied simultaneously with N-methyl-D-aspartate in the absence of current injection, carbachol was also found to promote rhythmic bursting in half of the cells tested. Since the bursts under these conditions were markedly longer in duration than those observed in the presence of N-methyl-D-aspartate alone, it was hypothesized that carbachol might have another action, in addition to the membrane hyperpolarization. Using dissociated cells, it was found that brief applications of carbachol could indeed diminish the slow afterhyperpolarizations that follow single spikes, short bursts or long trains of action potentials in cholinergic basalis neurons. These results indicate that, through its dual ability to hyperpolarize cholinergic neurons and to reduce their afterhyperpolarizations, acetylcholine can promote the occurrence of rhythmic bursting in the presence of N-methyl-D-aspartate. Accordingly, whether derived from brainstem or local sources, acetylcholine may facilitate rhythmic discharge in cholinergic basalis neurons which could in turn impose a rhythmic modulation upon cortical activity during particular states across the sleep-waking cycle.

Age-related functional changes of the glutamate receptor channels in rat Meynert neurones

1. The developmental changes of glutamate receptors (GluRs) in acutely dissociated rat Meynert neurones were investigated using the conventional whole cell and nystatin perforated patch recording modes under voltage-clamp conditions. 2. The neurones became less responsive to N-methyl-D-aspartic acid (NMDA) with age, most dramatically between 1 day and 2 weeks, while the responses to kainic acid (KA) and L-alpha-amino-3-hydroxy-5-methyl-4-isoxazolepropionic acid (AMPA) gradually increased. The metabotropic GluR response appeared a few days after birth, but thereafter no further change was observed. 3. The decrease in the NMDA response during postnatal development was due to an abrupt reduction in the number of receptors without affecting the affinity, voltage-dependent Mg2+ blockade or high Ca2+ permeability (PCa/PCs approximately 7.0). 4. PCa/PCs in the presence of KA decreased from 2.8 in the 1-day-old (1D) rat neurones to 1.1 and 0.44 in the 2-week-old (2W) and 6-month-old (6M) rat neurones, respectively. The concentration-response relationship for KA shifted to the left with age. The KA response was not affected by NS-102, a KA-selective antagonist, thus indicating that the increased affinity of the receptor for the ligand resulted from the change in the AMPA receptor channel subunits. 5. The AMPA response in the presence of 10(-4) M cyclothiazide showed a change in the inward rectifying current-voltage relationship with age. The KA response was strongly cross-desensitized by the addition of AMPA and was also blocked by 6-cyano-7-nitroquinoxaline-2,3-dione (CNQX), whereas a rapid desensitization of the AMPA response was removed in a concentration-dependent manner by cyclothiazide. These results indicate that the non-NMDA receptor channels are assembled from the subunits of the AMPA receptor family without the GluR-2 subunit, thus resulting in a high Ca2+ permeability. 6. The L-glutamate (Glu)-induced responses were more sensitive to DL-2-amino-5-phosphonopentanoic acid (APV) in the 1D rat neurones than in the adult rat neurones. 7. Both NMDA and KA raised the intracellular Ca2+ concentration ([Ca2+]i) in all neurones of 1D, 2W and 6M rats, though the charybdotoxin-sensitive Ca(2+)-activated K+ current (IK(Ca)) did not appear in the 1D rat neurones. An age-related prolongation of both IK(Ca) decay and [Ca2+]i clearance was also seen after the removal of KA. 8. It was thus concluded that the age-related changes of ionotropic receptors appear to play a key role in the activities of immature and mature rat Meynert cholinergic neurones. The KA-induced IK(Ca), which developed with ageing, may thus function as one of the negative feedback systems, and thereby prevent excess cell excitation and neural damage, especially in adult rats.

Effect of corticosterone and adrenalectomy on NMDA-induced cholinergic cell death in rat magnocellular nucleus basalis

The present study demonstrates the effects of adrenalectomy and subcutaneously administered corticosterone on N-methyl-D-aspartate-induced neurodegeneration in the cholinergic magnocellular basal nucleus of the rat. NMDA was unilaterally injected into the nucleus basalis at different plasma corticosterone concentrations in adrenalectomized rats, in adrenalectomized animals with subcutaneously implanted cholesterol-corticosterone pellets containing 25% or 100% corticosterone, and in sham-adrenalectomized controls. The neurotoxic impact of the NMDA injection in the various experimental groups was assessed by the loss of cholinergic fibers stained with acetylcholinesterase histochemistry in the parietal neocortex. Reactive cortical astrocytes as a result of the treatments were detected by glial fibrillary acidic protein immunohistochemistry. Measurements of the densities of astrocytes and cholinergic fibers at the injected side of the brain were carried out by image analysis. Adrenalectomy significantly potentiated the NMDA-induced neurodegeneration by 50%, while chronic administration of corticosterone significantly attenuated the NMDA-neurotoxicity in a dose-dependent manner. Compared to the ADX group, 25% corticosterone application reduced the NMDA damage by 37%, whereas the 100% corticosterone pellet diminished NMDA neurotoxicity by 75%. Both ADX and ADX + corticosterone implantation enhanced the NMDA-induced GFAP immunoreactivity. The increase of GFAP immunoreactivity was most pronounced in the adrenalectomized rats supplied with the 100% corticosterone pellets. The results demonstrate that corticosterone exerts a potent neuroprotective effect on NMDA-induced neurotoxicity in the magnocellular nucleus basalis. The activated astroglia suggest that astrocytes may contribute to the beneficial effect of corticosterone in the neuroprotective mechanisms against excitotoxic neuronal injury.

Expression of Bcl-2 in adult human brain regions with special reference to neurodegenerative disorders

The expression of the protooncogene bcl-2, an inhibitor of apoptosis in various cells, was examined in the adult human brain. Several experimental criteria were used to verify its presence; mRNA was analyzed by northern blot with parallel experiments in mouse tissues, by RNase protection, and by in situ hybridization histochemistry. Bcl-2 protein was detected by western blot analysis and immunohistochemistry. Two bcl-2 mRNA species were identified in the human brain. The pattern of distribution of bcl-2 mRNA at the cellular level showed labeling in neurons but not glia. The in situ hybridization signal was stronger in the pyramidal neurons of the cerebral cortex and in the cholinergic neurons of the nucleus basalis of Meynert than in the Purkinje neurons of the cerebellum. Both melanized and nonmelanized neurons were labeled in the substantia nigra. In the striatum, bcl-2 mRNA was detected in some but not all neurons. In the regions examined for Bcl-2 protein, the expression pattern correlated with the mRNA results. In patients with Alzheimer's and Parkinson's diseases, quantification of bcl-2 mRNA in the nucleus basalis of Meynert and substantia nigra, respectively, showed that the expression was unaltered compared with controls, raising the possibility that the expression of other components of apoptosis is modulated.

Neurotrophic 3,9-bis[(alkylthio)methyl]-and-bis(alkoxymethyl)-K-252a derivatives

A series of 3,9 disubstituted [(alkylthio)methyl]- and (alkoxymethyl)-K-252a derivatives was synthesized with the aim of enhancing and separating the neurotrophic properties from the undesirable NGF (trk A kinase) and PKC inhibitory activities of K-252a. Data from this series reveal that substitution in the 3- and 9-positions of K-252a with these groups reduces trk A kinase inhibitory properties approximately 100- to > 500-fold while maintaining or in certain cases enhancing the neurotrophic activity. From this research, 3,9-bis[(ethylthio)methyl]-K-252a (8) was identified as a potent and selective neurotrophic agent in vitro as measured by enhancement of choline acetyltransferase activity in embryonic rat spinal cord and basal forebrain cultures. Compound 8 was found to have weak kinase inhibitory activity for trk A, protein kinase C1 protein kinase A, and myosin light chain kinase. On the basis of the in vitro profile, 8 was evaluated in in vivo models suggestive of neurological diseases. Compound 8 was active in preventing degeneration of cholinergic neurons of the nucleus basalis magnocellularis (NBM) and reduced developmentally programmed cell death (PCD) of female rat spinal nucleus of the bulbocavernosus motoneurons and embryonic chick lumbar motoneurons.

Nitric oxide synthase in ventral forebrain grafts and in early ventral forebrain development

Embryonic ventral forebrain (VFB) grafts to cortex contain neurons that synthesize acetylcholine and partially ameliorate behavioral deficits caused by excitotoxic damage to the nucleus basalis magnocelullaris in rats. An additional neurotransmitter, nitric oxide (NO), is synthesized by a subset of cholinergic neurons in rat ventral forebrain. If this neurotransmitter is expressed also by grafted cholinergic neurons (which include the embryonic medial septum and diagonal band), its functional contribution should be considered. Six to twelve months after transplantation of embryonic VFB tissue rats were sacrificed. Brain tissue was processed either for in situ hybridization of nNOS and neuropeptide Y (NPY) or for immunohistochemistry of choline acetyltransferase (ChAT) and neuronal nitric oxide synthase (nNOS). Quantification of messenger ribonucleic acid (mRNA) for nNOS was performed with radioactively labeled probes (silver grains were counted) and a preliminary comparison was made of graft sections to sections of the ventral forebrain of developing rats. Plots of silver grain counts against cell size revealed similar patterns in the grafts and in the ventral forebrain of developing rats. The rates of expression of mRNA for nNOS in the grafts were intermediate between those of the ventral forebrain of postnatal day 19 and those of postnatal day 12. Double immunohistochemical labeling revealed that 45.87 + 8.26% of cells expressing ChAT also expressed nNOS in the grafts, significantly higher than 33.16 + 3.9% which was the rate of co-expression observed in the adult ventral forebrain. This study suggests that possible contribution of NO to graft-associated modulation of behavior should be examined.

[The individual characteristics of the cytoarchitectonics of subcortical-stem formations in the human brain]

Both quantitative and qualitative analysis of individual cytoarchitectonic peculiarities of Meynart's nucleus as well as of external part of dorsomedial nucleus of thalamus was performed in mentally normal individuals. The series of brain's 20-microns sections stained with cresyl violet were studied. Some individual morphological qualitative and quantitative peculiarities were evaluated in Meynart's nucleus and in dorsomedial nucleus of thalamus. A number of pronounced cytoarchitectonic peculiarities were revealed in above-mentioned cerebral structures of the persons with outstanding abilities (the cases were taken from the special collection of Moscow Institute of Brain of Russian Academy of Medical Sciences).

Enhanced acetylcholine release in the hippocampus and cortex during acquisition of an operant behavior

The activity of the septo-hippocampal and nucleus basalis-cortical cholinergic pathways was investigated by measuring changes in the extracellular acetylcholine levels in the hippocampus and parietal cortex, by means of transversal microdialysis, during the acquisition and recall of a positively reinforced operant behavior. Adult male Wistar rats were trained in a sound-isolated operant chamber equipped with a single lever. The positive reinforcement was represented by food pellets and the number of cumulative reinforced responses was recorded every 30 min. Five groups of rats were used. Unoperated animals were used as controls. In two groups of untrained animals, the microdialysis tubes were transversally implanted in the parietal cortex, and hippocampus and the training in the operant behavior chamber began 24 h after surgery. In two further groups the microdialysis tubes were implanted in the parietal cortex, and hippocampus after training for 15 days in the operant chamber. Food was removed 12 h before training. The time needed by the control rats to reach a stable baseline of reinforced responses was 83 +/- 12 min, while in the untrained rats implanted with dialysis probes in the cerebral cortex and in the hippocampus was 621 +/- 129 and 521 +/- 126 min, respectively, and in those pretrained and implanted in cerebral cortex and in the hippocampus was 116 +/- 38 and 217 +/- 59 min, respectively. In the untrained operated rats, both cortical and hippocampal extracellular acetylcholine levels remained constant until the number of reinforced responses was low but increased significantly (+156% in the cortex and +183% in the hippocampus) in the first 30 min period in which there was a sharp rise in the reinforced responses. In the pretrained operated rats, neither in the cortex nor in the hippocampus was the increase in response rate accompanied by a statistically significant increase in extracellular acetylcholine levels. Our findings demonstrate that activation of the forebrain cholinergic pathways occurs during the acquisition of a rewarded operant responses, while recall of the same behavior is not associated with the activation of the cholinergic system.

Spatial relationship between neurotensinergic axons and cholinergic neurons in the rat basal forebrain: a light microscopic study with three-dimensional reconstruction

Cholinergic neurons of the basal forebrain are known to project to the hippocampus and cerebral cortex wherein they play an important role in cortical activation, attention and memory. These neurons have been shown to possess neurotensin binding sites and to respond electrophysiologically to local application of neurotensin, indicating the presence of functional receptors on their membrane. In the present light microscopic study, the spatial relationship between neurotensinergic axons and cholinergic nerve cell bodies and proximal dendrites was investigated in the basal forebrain of the rat by dual immunostaining for neurotensin and choline acetyltransferase. Rostrally, neurotensinergic fibres were concentrated in the lateral septum and anterior substantia innominata, whereas cholinergic neurons were located in the medial septum, diagonal band of Broca and magnocellular preoptic nucleus. At high magnification, a few neurotensinergic axonal varicosities were observed in the region of cholinergic neurons, and fewer still in close proximity to cholinergic perikarya and proximal dendrites. Caudally, neurotensinergic fibres formed a dense plexus of varicose axons in the same regions where cholinergic neurons were located in the posterior substantia innominata and in the ventral and caudal aspects of the globus paltidus. At high magnification, many of these neurotensinergic varicosities were seen in close proximity to the cholinergic perikarya. These results suggest that cholinergic cells receive a much denser neurotensinergic innervation in the caudal than in the rostral aspect of the basal forebrain. This differential distribution is not reflected in the uniform density of neurotensin receptors and potent responses to neurotensin through the cholinergic cell population, suggesting the possibility that neurotensin's effects are mediated in part by a paracrine mechanism.

Quantitative changes of dendrites in rat dentate gyrus and basal nucleus of Meynert after passive avoidance training in the neonatal period

Quantitative morphological analysis of the number of granule cell dendritic spines, as well as total dendritic length and dendritic branching of neurons in the dentate gyrus and the nucleus of Meynert was done in 11-day-old rats after passive avoidance training in the neonatal period. Learning improved stepwise and its neuromorphological sequels were characterized by a statistically significant enhanced number of dendritic spines, due to an increase of thin spines, enhanced dendritic branching in both structures, and increased total dendritic length in the dentate gyrus compared with the controls.

Ventral striatopallidothalamic projection: IV. Relative involvements of neurochemically distinct subterritories in the ventral pallidum and adjacent parts of the rostroventral forebrain

Retrograde and anterograde tract-tracing studies were carried out to determine whether the capacity of the nucleus accumbens to influence the thalamic mediodorsal nucleus via ventral striatopallidothalamic connections disproportionately favors the shell over the core subterritory. After injections of Fluoro-Gold into the mediodorsal thalamic nucleus, retrogradely labeled neurons were detected in sections also processed for calbindin-D 28-kD and neurotensin immunoreactivities to facilitate identification of subterritories in the ventral pallidum. Fluoro-Gold-labeled cells were counted in series of sections cut through the ventral pallidum, rostral globus pallidus, nucleus of the vertical limb of the diagonal band, preoptic region, lateral hypothalamus, and the sublenticular gray region, including parts of the extended amygdala. Data were expressed as cells/unit area and as percentages of all labeled forebrain cells. Mediodorsal nucleus-projecting rostroventral forebrain neurons were most numerous in the ventromedial part of the subcommissural ventral pallidum and pallidal parts of the olfactory tubercle. Few were observed in the dorsolateral part of the subcommissural ventral pallidum. In addition, following injections into the ventral pallidum, anterogradely transported biotinylated dextran amine was evaluated in sections processed for calbindin or tyrosine hydroxylase immunoreactivities. Injection into the ventromedial part of the subcommissural ventral pallidum resulted in robust anterograde labeling of the medial segment of the mediodorsal nucleus and ventral tegmental area and weak labeling of the substantia nigra and subthalamic nucleus. Conversely, after injection into the dorsolateral part of the subcommissural ventral pallidum, anterograde labeling was weak in the mediodorsal nucleus and ventral tegmental area, but robust in the substantia nigra and subthalamic nucleus. The results are consistent with a predominant accumbens shell influence on the mediodorsal nucleus and with cortico-ventral striatopallidal-thalamocortical pathways that begin and end in different parts of the frontal lobe.