Neuronal types and their percent distribution within the magnocellular nuclei of the human basal forebrain

Three neuronal types constituting the magnocellular nuclei of the human basal forebrain have been differentiated with the aid of preparations stained for both Nissl material and pigment deposits: type I = large multipolar neurons contain loosely packed and faintly stained lipofuscin granules occupying a large portion of the cell body; type II = large spindle-shaped neurons reveal a densely packed accumulation of coarse and intensely stained lipofuscin granules, and type III = small nerve cells, scattered among these large neuronal components, with only a small number of faintly stained lipofuscin granules. The determination of the projection areas of the somata of the three neuronal types has led to a distribution pattern with three peaks. The ratio of the nerve cell types has been evaluated: 73.6% type I; 8.6% type II, and 17.8% type III neurons.     

Expression of the CD15 epitope in the human magnocellular basal forebrain system

Summary The distribution of the carbohydrate epitope 3-fucosyl-N-acetyl-lactosamine (CD15) has been immunocytochemically evaluated in coronal paraffin sections through the magnocellular basal forebrain system—the nucleus basalis of Meynert, the nucleus of the diagonal band of Broca and the medial septal nucleus-of 202 human brains. The brains derived from differently aged controls (n=54) and from patients suffering from organic brain diseases (n=129), or psychiatric disorders (n=19). In 30 cases dementia was clinically diagnosed. CD15 first appeared around birth when it became localized on singular astrocytes. The astrocyte number and process density steadily increased, and at approximately 12 years the typical adult-type pattern was acquired. Considerable variations in the expression patterns were noted with regard to the astrocyte number, the intensity in immunostaining and the process relations of CD15-positive astrocytes with the magnocellular neurons. In the light of these variations, and of conflicting additional changes in other areas of most diseased brains, it was difficult to correlate different intensities and patterns to specific diseases. The results, however, provide evidence for an increase in CD15 expression and in process network density of astrocytes in the lateral part of the nucleus basalis of Meynert in cases of Huntington's disease.     

The human basal forebrain integrates the old and the new

Acquisition of new learning is challenged by the phenomenon of proactive interference (PI), which occurs when previous learning disrupts later learning. Whereas human neuroimaging studies have focused on the cortical contributions to interference resolution, animal studies demonstrate that efficient resolution of PI depends on cholinergic modulation from basal forebrain (BF). Whether the BF promotes PI resolution in humans is unknown. Here, we adapted a PI paradigm from animal studies for use in a functional MRI experiment. During PI resolution, neurologically intact subjects recruited a BF network that included afferent anterior and posterior cortical sites associated with efficient memory acquisition and perceptual processing. Despite normal performance, nonamnesic patients with alcoholism, which is known to disrupt BF function, did not activate a BF network but instead invoked anterior cortical sites traditionally associated with executive function. These results provide evidence for parallel neural systems, each with the potential to resolve interference in the face of competing information.     

The magnocellular preoptic nuclei and the reproduction in Rana temporaria

Summary In Rana temporaria, changes of activity of the magnocellular neurosecretory preoptic nuclei in close correlation with ovulation, spermiation and copulation were observed.In accordance with previous experiments, the present observations suggest that the neurosecretory nuclei could play a part in the mechanism of ovulation, spermiation and copulation.     

Cognitive functions of the basal forebrain.

Studies of the function of the basal forebrain have focused on cholinergic neurons that project to cortical and limbic structures critical for various cognitive abilities. Recent experiments suggest that these neurons serve a modulatory function in cognition, by optimizing cortical information processing and influencing attention.     

The neuropharmacological restoration of cognitive functions in cats after damage to the forebrain basal nuclei (Meynert's nucleus)]

The cognitive functions were studied on experimental model of Alzheimer's disease (destruction of the basal nuclei of Meynert in cats) using the stimulation and inhibition of Ach, GABA, and DA brain systems. Ach system was found to be essential to form generalization function, DA system to improve simple learning, and GABA system to involve in formation of complex associations.     

Microglial regulation of cholinergic differentiation in the basal forebrain

Because inflammation during pregnancy can lead to neurodevelopmental anomalies, we investigated the role of inflamed microglia on cholinergic precursors in the rat embryonic basal forebrain (BF) cultured on embryonic day 15. Conditioned medium (CM) taken from microglia stimulated variously (microglial CM; MCM) increased activity of choline acetyltransferase (ChAT), the enzyme responsible for acetylcholine biosynthesis and a phenotypic hallmark of the cholinergic neuron. There was a concomitant decline in glutamic acid decarboxylase expression. Of stimulators tested, only β-amyloid failed to produce effective MCM. Infection with a Lac-Z-containing retrovirus revealed that MCM promoted cholinergic differentiation from undifferentiated precursors in the population. Several candidates were tested for their ability to mimic MCM. Mature nerve growth factor (NGF) did not mimic MCM, but acted synergistically with it to promote enormous increases in ChAT activity. However, a microglial cell line produced high-molecular weight forms of NGF (pro-NGF) that were lethal to mature cholinergic neurons. Although bone morphogenetic proteins (BMP) 2, 4, and 9 increased ChAT activity dose-dependently, noggin did not inhibit the effects of the MCM, suggesting that BMPs were not the only active factor(s) in the MCM. Embryonic microglia isolated following maternal inflammation produced a variety of immune system cytokines and chemokines. One of these, interleukin-6 (IL-6), was tested for its ability to promote cholinergic differentiation. Although IL-6 alone did not mimic the action of MCM, neutralization of it inhibited MCM effectiveness. Thus, following maternal inflammation, a complex microglial-derived cocktail of factors can promote excess cholinergic differentiation in the embryonic BF.     

Functional difference between the magnocellular neurosecretory nuclei of the rat hypothalamus

The supraoptic, paraventricular, and postoptic nuclei (SON, PVN, and PON, respectively) of the hypothalamus were studied under conditions of 3 months training of rats to hypoxia (exposure for 6 h daily in a low pressure chamber under 7600m of simulated altitude). All the three nuclei were activated during the first 5 days, and then the state of the SON cells normalized. Functional activity of the PVN and PON decreased (the nucleolar volume of the neurosecretory cells diminished to 70--80%, the amount of the neurosecretory substance in the cells and the posterior lobe of the hypophysis was reduced). Such a decreased activity of the PVN and PON persisted till the end of the experiment. A positive correlation of the thyroid epithelium height and the nucleolar volume of the PVN and PON cells was established for both the PVN (r=0.81, P less than 0.05) and the PON (r=0.82; P less than 0.05); no significant correlation was revealed for the SON (r=0.51; P less than 0.05). Thus, functional similarity of the PVN and the PON, and some peculiarities in the SON reaction under conditions of the experiment described was demonstrated.     

Cholinergic differentiation in neurogenic basal forebrain cultures

To study early events in the central nervous system (CNS) cholinergic development, cells from rat basal fore brain tissue were placed in culture at an age when neurogenesis in vivo is still active [embryonic day (E) 15]. The rapid mortality of these cells in defined medium, with 50% mortality after 5–10 h, was blocked completely by soluble proteins from the olfactory bulb (a basal forebrain target), extending earlier observations (Lambert, Megerian, Garden, and Klein, 1988). Treated cultures were capable of incorporating thymidine into DNA, and most cells incorporating ³H-thymidine (>90%) also stained positive for neurofilament, confirming neuronal proliferation in the supplemented cultures. A small percentage of ³H-thymidine labelled cells were glial fibrillary acidic protein (GFAP) positive, but growth factors that support astroglial proliferation [epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), and insulin-like growth factor (IGF-1)] were not sufficient for neuronal support. After 5 culture days with supplemented medium, almost 50% of the cells showed choline acetyltransferase (ChAT) immunofluorescence. The cholinergic neurons typically formed clusters separate from noncholinergic cells. These mature cultures did not develop if young cultures were treated with aphidicolin to block DNA synthesis. The data show that cultures of very young rat basal forebrain cells can be neurogenic, giving rise to abundant cholinergic neurons, and that early cell proliferation is essential for long-term culture survival.     

Specific neuronal expression of human NGF receptors in the basal forebrain and cerebellum of transgenic mice

Transgenic mice carrying multiple copies of the human NGF receptor gene have been generated. Using a monoclonal antibody specific for the human receptor, we have detected specific expression in cholinergic neurons in the basal forebrain and Purkinje cells in the cerebellum during the postnatal period. Expression in the PNS was exemplified by immunostaining of sympathetic and sensory neurons during an early embryonic age. Transection of the sciatic nerve in transgenic animals resulted in induction of human NGF receptors, indicating that the inserted gene can be appropriately regulated. These transgenic mice will provide an opportunity to study the elements regulating the NGF receptor. Furthermore, the ability to obtain specific expression in transgenic mice will permit directed expression of heterologous genes in discrete cells important in the cholinergic septal-hippocampal pathway and the PNS.     

Distribution and cellular localization of caldendrin immunoreactivity in adult human forebrain.

We investigated by immunohistochemistry (IHC) the distribution of caldendrin, the founding member of a novel family of neuronal calcium-binding proteins closely related to calmodulin, in human forebrain. Caldendrin immunoreactivity was unevenly distributed, with prominent staining in the paleo- and neocortex, hippocampus, and hypothalamus. With the exception of the hypothalamus, labeling was restricted to the somato-dendritic compartment of neurons. This distribution completely matches that reported in rat, indicating that the cellular function is most likely conserved among species. Therefore, one prerequisite for functional studies in rodent models aimed at elucidation of mechanisms with relevance for humans can be based on the present findings.     

Intranuclear coupling of hypothalamic magnocellular nuclei by glutamate synaptic circuits

Magnocellular neurons of the supraoptic nucleus (SON) and paraventricular nucleus (PVN) display bursting activity that is synchronized under certain conditions. They receive excitatory synaptic inputs from intrahypothalamic glutamate circuits, some of which are activated by norepinephrine. Ascending noradrenergic afferents and intrahypothalamic glutamate circuits may be responsible for the generation of synchronous bursting among oxytocin neurons and/or asynchronous bursting among vasopressin neurons located in the bilateral supraoptic and paraventricular nuclei. Here, we tested whether magnocellular neurons of the PVN receive excitatory synaptic input from the contralateral PVN and the region of the retrochiasmatic SON (SONrx) via norepinephrine-sensitive internuclear glutamate circuits. Whole cell patch-clamp recordings were performed in PVN magnocellular neurons in coronal hypothalamic slices from male rats, and the ipsilateral SONrx region and contralateral PVN were stimulated using electrical and chemical stimulation. Electrical and glutamate microdrop stimulation of the ipsilateral SONrx region or contralateral PVN elicited excitatory postsynaptic potentials/currents (EPSP/Cs) in PVN magnocellular neurons mediated by glutamate release, revealing internuclear glutamatergic circuits. Microdrop application of norepinephrine also elicited EPSP/Cs, suggesting that these circuits could be activated by activation of noradrenergic receptors. Repetitive electrical stimulation and drop application of norepinephrine, in some cases, elicited bursts of action potentials. Our data reveal glutamatergic synaptic circuits that interconnect the magnocellular nuclei and that can be activated by norepinephrine. These internuclear glutamatergic circuits may provide the functional architecture to support burst generation and/or burst synchronization in hypothalamic magnocellular neurons under conditions of activation.     

NGF induction of NGF receptor gene expression and cholinergic neuronal hypertrophy within the basal forebrain of the adult rat

Chronic infusion of nerve growth factor (NGF) into the forebrain of the adult rat produced increases in NGF receptor (NGF-R) mRNA hybridization, NGF-R immunoreactivity, choline acetyltransferase (ChAT) mRNA hybridization, and neuronal hypertrophy, when compared with vehicle infusion or noninfused rat brain. In situ hybridization showed NGF induction of NGF-R gene expression, documented by increases in the number of NGF-R mRNA-positive cells within the medial septum, diagonal band, and nucleus basalis magnocellularis. NGF also produced hypertrophy of ChAT mRNA-positive neurons. These results suggest that NGF produces cholinergic neuronal hypertrophy through induction of NGF-R gene expression within the basal forebrain.     

Cholinergic differentiation in neurogenic basal forebrain cultures.

To study early events in the central nervous system (CNS) cholinergic development, cells from rat basal forebrain tissue were placed in culture at an age when neurogenesis in vivo is still active [embryonic day (E) 15]. The rapid mortality of these cells in defined medium, with 50% mortality after 5-10 h, was blocked completely by soluble proteins from the olfactory bulb (a basal forebrain target), extending earlier observations (Lambert, Megerian, Garden, and Klein, 1988). Treated cultures were capable of incorporating thymidine into DNA, and most cells incorporating 3H-thymidine (greater than 90%) also stained positive for neurofilament, confirming neuronal proliferation in the supplemented cultures. A small percentage of 3H-thymidine labelled cells were glial fibrillary acidic protein (GFAP) positive, but growth factors that support astroglial proliferation [epidermal growth factor (EGF), basic fibroblast growth factor (bFGF), and insulin-like growth factor (IGF-1)] were not sufficient for neuronal support. After 5 culture days with supplemented medium, almost 50% of the cells showed choline acetyltransferase (ChAT) immunofluorescence. The cholinergic neurons typically formed clusters separate from noncholinergic cells. These mature cultures did not develop if young cultures were treated with aphidicolin to block DNA synthesis. The data show that cultures of very young rat basal forebrain cells can be neurogenic, giving rise to abundant cholinergic neurons, and that early cell proliferation is essential for long-term culture survival.     

Anatomical substrate for neurotensin-acetylcholine interactions in the rat basal forebrain

We have previously shown by combined radioautography and acetylcholinesterase histochemistry that the distribution of ¹²⁵I-neurotensin (NT) binding sites was in register with that of cholinergic neurons in the rat nucleus basalis magnocellularis (NBM). The present study utilized three experimental approaches to elaborate on the type and cellular localization of NT binding sites in the NBM. Competition studies using levocabastine, a selective blocker of the low affinity NT binding component, revealed that most of the ¹²⁵I-NT binding sites labeled in the NBM are of the levocabastine-insensitive high affinity type, known to correspond to the physiologically active receptor. Ibotenic acid-induced lesions of the NBM produced a marked reduction in both cholinesterase reactivity and cellular ¹²⁵I-NT binding suggesting that most of the labeled sites are associated with the cholinergic neurons themselves rather than with an afferent input to those cells. Finally, examination of the high resolution radioautographic distribution of ¹²⁵I-NT binding sites in semithin sections revealed that a proportion of ¹²⁵I-NT-labeled receptors is associated with the plasma membrane of magnocellular perikarya and proximal processes, thereby providing an anatomical substrate for a local action of NT in the NBM.     

Comparative aspects of basal forebrain organization in vertebrates.

The present survey shows that basal ganglia organization in the three classes of amniotes has many features in common. Yet, there are several differences that are important to note since they contribute to a better understanding of the evolution of those brain structures. They also underscore once again that it is questionable to generalize the results obtained in a certain species. This question is the more important in view of the general practice in mammalian research. Comparative studies may be of great help to solve this problem. The reported differences in acetylcholine release after pharmacological treatment in the striatum of rats and reptiles have stimulated further research that has led to the conclusion that the nucleus accumbens in the rat is a very heterogeneous structure with respect to the regulation of the release of acetylcholine by D2 dopamine and NMDA receptor activation. In this regard, the striatum of reptiles may offer a model for studying the functioning of the caudomedial part of the rat nucleus accumbens.     

Ultrastructural features of presumptive vasopressinergic synapses in the hypothalamic magnocellular secretory nuclei of the rat

Despite convincing physiological evidences for vasopressin (VP) autoregulation in the supraoptic (SON) and paraventricular (PVN) nuclei, the morphological demonstration of VP synapses has lagged behind. The present work investigates the possible existence of such synapses in the SON and PVN of the rat. Electron microscopy of sections immunostained with VP antibody (1:5,000) and conjugated with avidin-biotin demonstrated presynaptic terminals containing neurosecretory granule (NSG)-like bodies, 80-100 nm in diameter. The terminals formed axodendritic, axosomatic and axoaxonic synapses, though the postsynaptic elements remained largely unidentified. Other ultrastructural features of synaptic specialization were evident. The NSG-like bodies exhibited a varying and dynamic relationship to the presynaptic membrane, suggesting their involvement in synaptic mechanisms.