Synaptic remodeling induced by gonadal hormones: neuronal plasticity as a mediator of neuroendocrine and behavioral responses to steroids.

During recent decades, it has become a generally accepted view that structural neuroplasticity is remarkably involved in the functional adaptation of the CNS. Thus, cellular morphology in the brain is in continuous transition throughout the life span, as a response to environmental stimuli. The effects of the environment on neuroplasticity are mediated by, to some extent, the changing levels of circulating gonadal steroid hormones. Today, it is clear that the function of gonadal steroids in the brain extends beyond simply regulating reproductive and/or neuroendocrine events. In addition, or even more importantly, gonadal steroids participate in the shaping of the developing brain, while their actions during adult life are implicated in higher brain functions such as cognition, mood and memory. A large body of evidence indicates that gonadal steroid-induced functional changes are accompanied by alterations in neuron and synapse numbers, as well as in dendritic and synaptic morphology. These structural modifications are believed to serve as a morphological basis for changes in behavior and cellular activity. Due to their growing functional and clinical significance, the specificity, timeframe, as well as the molecular and cellular mechanisms of hormone-induced neuroplasticity have become the focus of many studies. In this review, we briefly summarize current knowledge and the most significant recent discoveries from our laboratories on estrogen- and dehydroepiandrosterone-induced synaptic remodeling in the hypothalamus and hippocampus, two important brain areas heavily involved in autonomic and cognitive operations, respectively.

Hormonal regulation of hippocampal spine synapse density involves subcortical mediation.

It is well established that estrogen has positive effects on the density of pyramidal cell spines in the hippocampal CA1 subfield. This study explored whether afferent connections of the hippocampus that come from estrogen-sensitive subcortical structures, including the septal complex, median raphe and supramammillary area, play a role in this estrogen-induced hippocampal synaptic plasticity. These particular subcortical structures have major influences on hippocampal activity, including theta rhythm and long-term potentiation. The latter also promotes the formation of new synapses. All of the rats were ovariectomized; the fimbria/fornix, which contains the majority of subcortical efferents to the hippocampus, was transected unilaterally in each, and half of the animals received estrogen replacement. Using unbiased electron microscopic stereological methods, the CA1 pyramidal cell spine synapse density was calculated. In the estrogen-treated rats, contralateral to the fimbria/fornix transection, the spine density of CA1 pyramidal cells increased dramatically, compared to the spine density values of both the ipsilateral and contralateral hippocampi of non-estrogen-treated animals and to that of the ipsilateral hippocampus of the estrogen replaced rats. These observations indicate that fimbria/fornix transection itself does not considerably influence CA1 area pyramidal cell spine density and, most importantly, that the estrogenic effect on hippocampal morphology, in addition to directly affecting the hippocampus, involves subcortical mediation.

The supramammillo-hippocampal and supramammillo-septal glutamatergic/aspartatergic projections in the rat: a combined [3H]D-aspartate autoradiographic and immunohistochemical study.

It is well established that the supramammillary nucleus plays a critical role in hippocampal theta rhythm generation/regulation by its direct and indirect (via the septal complex) connections to the hippocampus. Previous morphological and electrophysiological studies indicate that both the supramammillo-hippocampal and supramammillo-septal efferents contain excitatory transmitter. To test the validity of this assumption, transmitter specific retrograde tracer experiments were performed. [3H]D-aspartate was injected into different locations of the hippocampus (granular and supragranular layers of the dentate gyrus and CA2 and CA3a areas of the Ammon's horn) and septal complex (medial septum and the area between the medial and lateral septum) that are known targets of the supramammillary projection. Consecutive vibratome sections prepared from the entire length of the posterior hypothalamus, including the supramammillary area, were immunostained for calretinin, tyrosine hydroxylase, or calbindin, and further processed for autoradiography. Radiolabeled, radiolabeled plus calretinin-containing, and calretinin-immunoreactive neurons were plotted at six different oro-caudal levels of the supramammillary area. The results demonstrated that following both hippocampal and septal injection of the tracer, the majority of the retrogradely radiolabeled (glutamatergic/aspartatergic) cells are immunoreactive for calretinin. However, non-radiolabeled calretinin-containing neurons and radiolabeled calretinin-immunonegative cells were also seen, albeit at a much lower density. These observations clearly indicate the presence of glutamatergic/aspartatergic projections to both the hippocampus and septal complex. It may be assumed that this transmitter could play a role in hippocampal theta rhythm generation/regulation.

Opioids suppress IPSCs in neurons of the rat medial septum/diagonal band of Broca: involvement of mu-opioid receptors and septohippocampal GABAergic neurons.

The medial septum/diagonal band region (MSDB), which provides a major cholinergic and GABAergic input to the hippocampus, expresses a high density of opioid receptors. Behaviorally, intraseptal injections of opioids produce deficits in spatial memory, however, little is known about the electrophysiological effects of opioids on MSDB neurons. Therefore, we investigated the electrophysiological effects of opioids on neurons of the MSDB using rat brain slices. In voltage-clamp recordings with patch electrodes, bath-applied met-enkephalin, a nonselective opioid receptor agonist, decreased the number of tetrodotoxin and bicuculline-sensitive inhibitory synaptic currents in cholinergic- and GABA-type MSDB neurons. A similar effect occurred in brain slices containing only the MSDB, suggesting that opioids decrease GABA release primarily by inhibiting spontaneously firing GABAergic neurons located within the MSDB. Accordingly, in extracellular recordings, opioid-sensitive, spontaneously firing neurons could be found within the MSDB. Additionally, in intracellular recordings a subpopulation of GABA-type neurons were directly inhibited by opioids. All effects of met-enkephalin were mimicked by a mu receptor agonist, but not by delta or kappa agonists. In antidromic activation studies, mu-opioids inhibited a subpopulation of septohippocampal neurons with high conduction velocity fibers, suggestive of thickly myelinated GABAergic fibers. Consistent with the electrophysiological findings, in double-immunolabeling studies, 20% of parvalbumin-containing septohippocampal GABA neurons colocalized the mu receptor, which at the ultrastructural level, was found to be associated with the neuronal cell membrane. Thus, opioids, via mu receptors, inhibit a subpopulation of MSDB GABAergic neurons that not only make local connections with both cholinergic and noncholinergic-type MSDB neurons, but also project to the hippocampus.

Median raphe serotonergic innervation of medial septum/diagonal band of broca (MSDB) parvalbumin-containing neurons: possible involvement of the MSDB in the desynchronization of the hippocampal EEG.

Activation of median raphe serotonergic neurons results in the desynchronization of hippocampal electroencephalographic (EEG) activity. This could be a direct effect, because serotonin (5-HT) fibers terminate on a specific population of hippocampal interneurons. On the other hand, it could be an indirect action through the medial septum/diagonal band of Broca (MSDB) pacemaker cells, because, in addition to previously described inhibitory effects, excitatory actions of 5-HT have been demonstrated on MSDB gamma-aminobutyric acid (GABA)-containing neurons through 5-HT2A receptors. Electron microscopic double immunostaining for Phaseolus vulgaris-leucoagglutinin (PHA-L) injected into the median raphe (MR) and parvalbumin, choline acetyltransferase, or calretinin as well as double immunostaining for 5-HT and parvalbumin, and colocalization for parvalbumin and 5-HT2A receptors were done in rats. The results demonstrated that: 1) MR axons form perisomatic and peridendritic baskets and asymmetric synaptic contacts on MSDB parvalbumin neurons; 2) these fibers do not terminate on septal cholinergic and calretinin neurons; 3) 5-HT fibers form synapses identical to those formed by PHA-L-immunolabeled axons with parvalbumin neurons; and 4) MSDB parvalbumin cells contain 5-HT2A receptors. These observations indicate that 5-HT has a dual action on the activity of hippocampal principal cells: 1) an inhibition of the input sector by activation of hippocampal GABA neurons that terminate exclusively on apical dendrites of pyramidal cells, and 2) a disinhibition of the output sector of principal neurons. MSDB parvalbumin-containing GABAergic neurons specifically innervate hippocampal basket and chandelier cells. Thus, 5-HT-elicited activation of MSDB GABAergic neurons will result in a powerful inhibition of these GABA neurons.

Hypothalamo-septal enkephalinergic fibers terminate on AMPA receptor-containing neurons in the rat lateral septal area.

A large number of septal neurons express alpha-amino-3-hydroxy-5-methyl-4-isoxazoleproprionate (AMPA)-type excitatory glutamate receptors. It has been demonstrated that in the mediolateral part of the rat lateral septum, calbindin-containing neurons are heavily innervated by hypothalamic, enkephalinergic fibers forming exclusively asymmetric synaptic contacts. This connection was suggested to be excitatory. In order to further elucidate this hypothesis, the aim of the present study was to determine whether these enkephalinoceptive neurons express GluR1 and GluR2/3 AMPA receptor subunits. Correlated light and electron microscopic analysis, using single immunostaining for GluR1 and GluR2/3, and double immunostaining for Leu-enkephalin and GluR1 or GluR2/3, was performed on vibratome sections of the rat lateral septal area. The studies revealed that while GluR1 is mainly associated with dendritic and somatic spines, GluR2/3 is mostly present in the perisomatic area. Leu-enkephalin boutons establish asymmetric synaptic contacts at the level of the soma and initial dendrites of both of these cells. A semiquantitative analysis showed that these enkephalin-targeted cells represent 50% of the total number of both GluR1 and GluR2/3-containing lateral septal neurons. These results suggest that: (1) AMPA receptor-expressing neurons appear to be the exclusive recipient of hypothalamic Leu-enkephalin boutons; (2) these enkephalinoceptive neurons contain both GluR1 and GluR2/3 AMPA receptor subunits; however, (3) only the GluR2/3 subtype, located in the perisomatic area, may be associated with Leu-enkephalin-containing inputs.

Parvalbumin-containing cells of the angular portion of the vertical limb terminate on calbindin-immunoreactive neurons located at the border between the lateral and medial septum of the rat.

In the septal complex, both parvalbumin and calbindin neurons cocontain GABA. In the same area, a large number of GABA-GABA synaptic connections can be observed. In order to further characterize their neurochemical nature, as well as the extrinsic and/or intrinsic origin of these GABA terminals, the following experiments were performed: (1) correlated light- and electron-microscopic double immunostaining for calbindin and parvalbumin on septal sections of control rats: (2) light microscopic parvalbumin immunostaining of septal sections after surgical isolation (5 days) of the septum from its telencephalic or (3) hypothalamic afferents; and (4) parvalbumin immunostaining of sections prepared from the entire brain 2 days following horseradish peroxidase injection into the border between the lateral and medial septum. The results demonstrated that: (1) in a well-circumscribed, vertically longitudinal area located between the lateral and medial septum, 0.1-0.6 mm anterior to the bregma, a group of calbindin-containing, nonsomatospiny neurons are surrounded by parvalbumin-immunoreactive baskets; (2) these basket-forming axon terminals establish symmetric synaptic contacts with their targets; and (3) their cells of origin are not in the medial septum, but in the angular portion of the vertical limb. These observations indicate that a portion of the septal complex GABA-GABA synaptic connections represent functional interaction between two different types of GABAergic neurons. The presynaptic GABAergic neurons contain parvalbumin, and the postsynaptic GABAergic cells are immunoreactive for calbindin. Furthermore, a population of the medial septum/diagonal band parvalbumin neurons project only to the hippocampus, while others, which may also send axons to the hippocampus, terminate on lateral septum calbindin cells as well.

Morphological and pharmacological evidence for neuropeptide Y-galanin interaction in the rat hypothalamus.

Galanin (GAL) and neuropeptide Y (NPY) have been shown to play important roles in the regulation of pituitary hormone secretion, as well as ingestive and sexual behaviors, by acting within the hypothalamus. While the mechanism of action of these regulatory peptides is under intensive investigation, less attention has been paid to the possible interaction between them in influencing these central regulatory processes. Because NPY and GAL augment pituitary gonadotropin release, the present study was undertaken to evaluate the nature of morphological and functional relationships between these excitatory hypothalamic peptidergic systems. Double immunolabeling for NPY and GAL was carried out on vibratome sections taken from the hypothalamus of colchicine-pretreated female rats. Avidinbiotin peroxidase technique and a dark blue diaminobenzidine reaction was used to visualize NPY profiles, while the GAL neurons were labeled with a light brown diaminobenzidine reaction using either the avidin-biotin peroxidase or the peroxidase antiperoxidase technique. Light microscopic examination of the immunostained material showed that in the arcuate nucleus, paraventricular nucleus, supraoptic nucleus, anterior hypothalamus, and medial preoptic area, an abundant network of NPY-immunoreactive axons surrounded GAL-immunostained cells. Numerous dark blue NPY-containing putative boutons were observed in close proximity to GAL-immunolabeled cell bodies and dendrites. Correlated light and electron microscopic examination revealed that most of the immunoreactive NPY axon terminals established synaptic connections with GAL-expressing cells. Synaptic connections were most frequently found in the medial preoptic area and in the magnocellular region of the paraventricular nucleus and arcuate nucleus. Fewer connections were observed in the supraoptic nucleus. These morphological observations demonstrate the existence of a strong NPY input to hypothalamic GAL neurons, thereby suggesting a modulatory role for NPY in monitoring GAL release. To evaluate the functional relevance of this anatomical relationship, the effects of intraventricular injection of a GAL receptor antagonist, galantide, were examined on NPY-induced LH release in ovarian steroid-primed ovariectomized rats. As expected, intraventricular injection of NPY readily stimulated LH release. Although, while on its own, galantide was ineffective in altering basal LH release, it markedly attenuated the NPY-induced LH response, thereby suggesting that GAL released in response to NPY administration may, in part, mediate the excitatory effects of NPY. These experimental results, taken together with the morphological observations, document the involvement of an NPY --> GAL signaling modality in the release of gonadotropins and, likewise, raise the possibility of a similar signaling process in the release of other pituitary hormones and elicitation of behavioral effects attributed to NPY and GAL.

Extrinsic and intrinsic substance P innervation of the rat lateral septal area calbindin cells.

The electrophysiological observations that substance P administration to the lateral septal area elicits both excitatory and inhibitory responses, together with earlier reports on the multiple sources of substance P innervation of the septum, implies that these axons with distinct origins have different functions. This prompted us to examine the origin and neurochemical character of substance P afferents to the lateral septal area. Chronic surgical isolation of the septum from its ventral afferents and retrograde tracer experiments using wheat germ agglutinin-conjugated horseradish peroxidase, both followed by an immunostaining for substance P, were employed to elucidate the origin of these axon terminals. In order to assess the possible co-existence of substance P with other neurotransmitter substances in the parent cells of the septopetal projections, co-localization studies for substance P and choline acetyltransferase, as well as substance P and GABA, were performed. The comparative distribution of substance P fibers and septal calbindin-containing neurons was also investigated using correlated light and electron microscopic double immunostaining. The results are summarized as follows: (i) the substance P innervation of the lateral septal area derives from several hypothalamic nuclei (including the lateral and lateroanterior hypothalamic area, tuber cinereum and ventromedial hypothalamic nucleus) and tegmental nuclei (the majority of fibers from the laterodorsal and a few from the pedunculopontine tegmental nucleus), as well as intrinsic septal cells; (ii) the septopetal substance P fibers of tegmental origin are cholinergic; intraseptal substance P neurons located in the dorsolateral part of the lateral septum also contain GABA, while substance P neurons seen on the border between the medial and lateral septal area and septopetal hypothalamic substance P cells do not contain GABA or acetylcholine; (iii) substance P fibers from pericellular baskets around calbindin-containing lateral septal neurons with a high degree of selectivity; (iv) approximately 90% of the entire calbindin cell population are postsynaptic targets of substance P axons; (v) their terminals contact the soma and the dendrites of these cells, among them the somatospiny neurons; and (vi) the extrinsic substance P boutons establish asymmetric, while the intrinsic substance P axon terminals form symmetric membrane specializations. Because neurons in the lateral septal area receive hippocampal input and project massively to hypothalamic areas, the different types of substance P input on these neurons can modify the information flow arriving from the hippocampus to diencephalic brain structures at the level of the lateral septal area.

Hypothalamic Leu-enkephalin-immunoreactive fibers terminate on calbindin-containing somatospiny cells in the lateral septal area of the rat.

Correlated light and electron microscopic double-immunostaining experiments for Leu-enkephalin and calbindin were employed to determine the postsynaptic targets in the septal complex of Leu-enkephalin fibers. Chronic surgical isolation of the septal complex from its hypothalamic afferents and retrograde tracer studies using wheat germ agglutinin-conjugated horseradish peroxidase, both followed by an immunostaining for Leu-enkephalin, were performed to elucidate the location of the origin of these axon terminals. Furthermore, a colocalization study for glutamic acid decarboxylase and Leu-enkephalin was carried out on hypothalamic sections to determine their possible coexistence in cells projecting to the lateral septum. These studies revealed that 1) Leu-enkephalin-immunoreactive axons form pericellular baskets around a population of lateral septal area neurons; 2) they establish exclusively asymmetric synaptic contacts on their soma and initial dendritic segments; 3) 10% of the lateral septal area calbindin-containing cells, which are all of the gamma-aminobutyric acid (GABA)-ergic somatospiny type, are innervated by Leu-enkephalin-immunoreactive baskets; 4) only 40% of the Leu-enkephalin target neurons are calbindin immunopositive; 5) the septopetal Leu-enkephalin fibers derive from neurons located in the ipsilateral perifornical area and anterior hypothalamus; and 6) none of their cells of origin cocontains the inhibitory transmitter GABA. These observations indicate that hypothalamic Leu-enkephalin-containing neurons are non-GABAergic excitatory cells. Hence, they can effectively stimulate a population of lateral septal area neurons, including the somatospiny cells, which are all GABAergic. Therefore, after stimulatory Leu-enkephalin action, these neurons can inhibit their postsynaptic targets, including other projective lateral septal neurons.

Distribution of estrogen receptor-immunoreactive cells in monkey hypothalamus: relationship to neurones containing luteinizing hormone-releasing hormone and tyrosine hydroxylase.

The precise sites and mechanisms by which gonadal steroids influence the activity of neuroendocrine cells controlling pituitary hormone secretion are poorly understood. The present study has determined the distribution of estrogen receptor (ER)-immunoreactive cells in the monkey hypothalamus and examined whether ERs are expressed by luteinising hormone-releasing hormone (LHRH)-and/or dopamine-containing neurones. The distribution of ER-immunoreactive cells was determined in ovariectomised (n = 2) and estrogen plus progesterone-treated (n = 2) cynomolgus macaques and in a single ovariectomised African green monkey. Large numbers of cells immunoreactive for the ER were detected in the preoptic area, bed nucleus of the stria terminalis, periventricular area and ventromedial and arcuate nuclei of all monkeys irrespective of the steroid status. Smaller numbers of ER-immunoreactive cells were found in the paraventricular, but not supraoptic nucleus. Double-labeling experiments in sections from all 5 monkeys revealed that none of the 432 LHRH neurons examined possessed detectable ER immunoreactivity. Neurones stained for tyrosine hydroxylase (TH) were identified in the A11, A12, and A14 cell groups and, although A11 and A12 neurones were intermingled amongst and found adjacent to ER-immunoreactive cells, none of the 1,652 TH-immunoreactive cells examined contained ER immunoreactivity. These results show that ER-immunoreactive cells in the monkey hypothalamus are distributed in a manner similar to that observed in other mammalian species although not all brain regions reported to contain progesterone receptors (PRs) in these species of monkey were found to express ERs. The double-labelling experiments provide further evidence that LHRH neurones do not possess ERs and indicate that, as in other species, estrogen influences on primate LHRH neurones are indirect and/or non-genomic in nature. Unlike the rat and sheep, no evidence was found for ER immunoreactivity in hypothalamic dopaminergic neurones of the monkey. The discrepancy in ER and reported PR receptor localisation within specific hypothalamic nuclei as well as in dopaminergic neurones raises the possibility that not all PR-containing cells may express ERs in the primate hypothalamus.

Naloxone reduces the feeding evoked by intracerebroventricular galanin injection.

Central injection of galanin elicits feeding in satiated rats. We recently observed galanin-immunoreactive fibers in synaptic connection with a population of beta-endorphin-immunopositive cell bodies and dendrites in the basal hypothalamus. Because beta-endorphin also stimulates food intake, these morphological findings raised the possibility that stimulation of feeding by galanin may, in part, be mediated by beta-endorphin release. First, we observed that ICV injection of galanin (1.5-6.0 nmol) stimulated feeding in a dose-related fashion. Next, the effect on food intake of the opioid receptor antagonist naloxone (20-200 micrograms, ICV) administered immediately preceding galanin (3 nmol, ICV) was evaluated. Galanin-induced feeding was suppressed by naloxone in a dose-dependent manner with a maximal suppression of 76% at the highest naloxone dose. These findings support the existence of a functional link between galanin and beta-endorphin and are in accord with the view that stimulation of food intake by galanin may, in part, be mediated by increased beta-endorphin release.

Morphological evidence that hypothalamic substance P-containing afferents are capable of filtering the signal flow in the monkey hippocampal formation.

This study in the African green monkey (Cercopithecus aethiops) was designed to characterize the neurochemical features of hippocampal nonpyramidal neurons that are specific synaptic targets of substance P-containing projective neurons located in the supramammillary nucleus. Our previous studies provided evidence for an excitatory nature to this hypothalamo-hippocampal pathway and described the mode of termination of these afferents on hippocampal principal neurons. The present correlated light and electron microscopic immunocytochemical analysis, using the nickel-diaminobenzidine/diaminobenzidine double-labeling technique, revealed that this hippocampal afferent system establishes multiple, exclusively asymmetric synapses with three specific subpopulations of nonpyramidal cells: (1) a small portion of parvalbumin-containing basket cells located periodically in or adjacent to the granule cell layer of the dentate gyrus, which therefore inhibit only a subpopulation of granule cells; (2) some of the calbindin-immunoreactive local circuit neurons located in the hilar area; and (3) calbindin-positive cells occurring exclusively in the stratum molecular of the middle portion of the CA3 subfield. Postembedding studies revealed that the aforementioned calbindin-containing cells are GABAergic inhibitory neurons. Our studies indicate that hypothalamic afferents can effectively filter the information flow at different levels of the excitatory signal loop in the monkey hippocampal formation. Dentate granule cells, which are only stimulated by hypothalamic afferents, will transfer excitatory signals differently than those that are controlled by a feedforward inhibitory mechanism initiated by these fibers. In the CA3 subfield, the signal flow can again be depressed by those pyramidal neurons that are inhibited by calbindin-containing cells receiving an excitatory hypothalamic input.

Substance P-containing hypothalamic afferents to the monkey hippocampus: an immunocytochemical, tracing, and coexistence study.

In order to identify the synaptic connections of substance P-containing afferents within the hypothalamo-hippocampal projection of the monkey, we performed a combined light and electron microscopic, immunocytochemical study, made lesions of the fimbriafornix, and employed retrograde tracing using WGA-HRP. Furthermore, coexistence studies for substance P and GAD were performed to identify the putative transmitters of these hypothalamic projection neurons. A plexus of large substance P-immunoreactive terminals was identified in both the innermost portion of the molecular layer and in CA2. Axon terminals in both plexuses established exclusively asymmetric synapses with spines and dendritic shafts. Substance P-immunoreactive boutons were degenerating 5 days after lesioning, and had disappeared 10 days after ipsilateral fimbria-fornix transection. Thus, these terminals were of extrinsic origin. In contrast, immunoreactive fibers in the outer third of the dentate molecular layer remained unaffected by the lesion. Retrograde tracing combined with immunostaining for substance P revealed the parent cell bodies of the extrinsic substance P-containing afferents in the supramammillary nucleus. Colocalization studies employing a consecutive semi-thin sections technique indicate that these large substance P-containing projection neurons lack GABA as an inhibitory transmitter. These results suggest that hypothalamic afferents of the monkey hippocampus contain substance P. Because these afferents lack GABA as an inhibitory transmitter and establish exclusively asymmetric synapses, this projection may excite hippocampal target neurons.

Sprouting of remaining substance P-immunoreactive fibers in the monkey dentate gyrus following denervation from its substance P-containing hypothalamic afferents.

This study analyzed the response of intrinsic substance P-immunoreactive fibers in the monkey dentate gyrus to disruption of the supramammillo-hippocampal projection. This projection normally forms a thin plexus of large, substance P-immunoreactive terminals in the innermost portion of the dentate molecular layer and establishes exclusively asymmetric synapses with dendritic shafts and spines of dentate neurons. Conversely, substance P-containing terminals have never been observed in synaptic contact with granule cell bodies. Ten days after ipsilateral fimbria-fornix transection, the prominent band of large immunostained axons in the inner molecular layer of the ipsilateral fascia dentata disappeared. Four and five weeks following transection, however, some small, substance P-containing terminals were observed in the innermost portion of the dentate molecular layer and the granule cell layer. These terminals established exclusively symmetric synapses with the somata and proximal dendritic shafts of granule cells. These results suggest that, following transection of the hypothalamo-hippocampal fiber tract, presumptive intrinsic substance P-containing axons are capable of sprouting into the granule cell layer and the former termination field of the hypothalamic fibers. The symmetric synapses established with granule cell bodies and their proximal dendrites might indicate a shift from an extrinsic excitation to an intrinsic inhibition of granule cells following disruption of substance P-containing hypothalamic afferents.

Neuropeptide-Y innervation of estrogen-induced progesterone receptor-containing dopamine cells in the monkey hypothalamus: a triple labeling light and electron microscopic study.

Light and electron microscopic triple immunostaining was performed on coronal vibratome sections prepared from the hypothalamus of ovariectomized (OVX) and OVX plus estrogen-treated African green monkeys (Cercopithecus aethiops). Immunoreactivity for progesterone receptors (PRs) and neuropeptide-Y (NPY) was visualized by a dark blue to black nickel diaminobenzidine reaction, while the tyrosine hydroxylase-containing perikarya were labeled with a light brown diaminobenzidine reaction. In the OVX plus estrogen-treated material, 30% of the tyrosine hydroxylase-immunoreactive neurons contained PR-immunopositive nuclei. The majority of these cells were found in the central portion of the periventricular area, and a few could be observed in the anterior hypothalamus and the arcuate and dorsomedial hypothalamic nuclei. These tyrosine hydroxylase-immunoreactive PR-containing cells were surrounded with NPY-immunoreactive axon terminals. A correlated electron microscopic analysis of the same sections revealed synaptic contacts between these NPY-immunoreactive boutons and the PR-containing tyrosine hydroxylase-immunoreactive neurons. In contrast, in the OVX animals, no PR-containing tyrosine hydroxylase-immunoreactive neurons could be detected. In these monkeys, the frequency of synaptic contacts between the NPY-immunoreactive axon terminals and tyrosine hydroxylase-immunopositive cells was similar to that in the OVX plus estrogen-treated monkeys. These observations indicate that in a population of hypothalamic dopamine cells, the presence of nuclear PRs is estrogen dependent, show that these cells are innervated by NPY axons, and suggest that these estrogen-induced PR-containing dopamine neurons are involved in mediation of the effect of NPY on hypophyseal hormone secretion, including ovarian steroid hormone-dependent LH and PRL release.

Estrogen induces synaptic plasticity in adult primate neurons.

The number of axosomatic synapses, the length of the synaptic plates and the perimeter of the post synaptic neuronal perikarya were assessed on thin sections from the infundibular hypothalamic nucleus and from the ventrobasal thalamus of 3 adult ovariectomized African green monkeys that were treated with estradiol valerate and of 3 control animals that were injected with vehicle. Estradiol valerate treatment resulted in a 61% [corrected] decrease in the number of axosomatic synapses in the infundibular hypothalamic nucleus. The length of the synaptic plates and the perimeter of the postsynaptic cells were not affected by the hormonal treatment. The decrease in the number of axosomatic synaptic inputs in the infundibular hypothalamic nucleus was accompanied by a significant increase in the glial ensheathing of neuronal somas. No effect of the hormonal treatment was detected in the ventrobasal thalamus. The results indicate that estrogen may induce glial and synaptic plasticity in the hypothalamus of adult primates.

Presence of somatostatin or neurotensin in lateral septal dopaminergic axon terminals of distinct hypothalamic and midbrain origins: convergence on the somatospiny neurons.

In the lateral septal area (LSA), both inhibitory and excitatory dopamine (DA) actions, as well as hypothalamic and midbrain DA efferents, have been described. Some neurons of the hypothalamic and midbrain DA systems contain somatostatin (SOM) or neurotensin (NT), and, in the LSA, the distribution of fibers containing these peptides overlaps with DA fibers. These data prompted us to test for the presence of SOM and NT in LSA dopaminergic axon terminals of hypothalamic and midbrain origins. To verify the origins of SOM and NT innervation of the LSA, the retrograde tracer horseradish peroxidase conjugated with wheat germ agglutinin (HRP-WGA) was injected into the LSA, and alternate brain sections were immunostained for SOM, NT, or tyrosine hydroxylase (TH) in group 1 rats. Numerous retrogradely labeled neurons were found immunopositive for SOM in the periventricular and basolateral hypothalamus, many HRP-WGA labeled cells contained NT immunoreactivity in the ventral tegmental area, and TH-immunoreactive retrogradely labeled neurons were observed in both brain areas. In a new approach, the presence of these peptides in dopaminergic boutons was assessed by combining peptide immunocytochemistry with acute 6-hydroxydopamine (6-OHDA) induced lesioning of DA cell groups. These groups of rats were treated with desipramine to protect the noradrenergic fibers, and 45 min later 1 microgram 6-OHDA (in 0.5 microliter saline) was unilaterally injected into the periventricular hypothalamus (group 2) or the ventral tegmental area (group 3). After 48 h the rats were killed and alternate septal sections of both groups were immunostained for TH, SOM, or NT. On the operated side of the LSA in both groups, electron microscopy revealed numerous axon terminals that were immunopositive for TH and contained autophagous cytolysosomes, an early sign of catecholamine fiber degeneration induced by 6-OHDA. In group 2, phagosome-containing boutons were found immunopositive for SOM, but not for NT; vice versa, in group 3, only NT-positive degenerated boutons were detected. SOM- and NT-positive degenerated axon terminals in both groups formed synaptic contacts with LSA neurons, in particular with somatospiny cells. On the contralateral side of the LSA, all of the axon terminals were intact. It has been shown that SOM exerts an inhibitory action, whereas NT has an excitatory effect on limbic area neurons. Thus, the results implicate that the differential peptide content of dopamine fibers marks their functional differences. It appears that LSA neurons receive double innervation from an inhibitory "somatostatinergic" DA system of the hypothalamus, and from an excitatory "neurotensinergic" DA system of the midbrain.

Beta-endorphin innervation of dopamine neurons in the rat hypothalamus: a light and electron microscopic double immunostaining study.

Pharmacological data suggest that opiates, acting indirectly via the catecholaminergic system, are involved in the inhibition of LH release and the stimulation of PRL secretion. The aim of this study was to demonstrate on the ultrastructural level whether beta-endorphin-immunoreactive fibers form synaptic contacts with hypothalamic dopaminergic neurons. Light and electron microscopic double immunostaining experiments were performed on vibratome sections prepared from the hypothalamus of acrolein-fixed female rat brains. Immunoreactivity for beta-endorphin was visualized by a dark blue to black nickel ammonium sulfate-intensified diaminobenzidine reaction, and in a consecutive immunostaining procedure, the tyrosine hydroxylase-immunoreactive dopamine cells were labeled with the brown diaminobenzidine reaction product. Under the light microscope, beta-endorphin axon terminals were found to contact dopamine cell bodies and dendrites throughout the hypothalamus. The majority of opiate target dopamine neurons were found in the periventricular area, retrochiasmatic area, and lateral part of the zona incerta. A much smaller number was observed in the dorsomedial hypothalamic nucleus and the anterior hypothalamus, and only a very few dopamine cells could be detected in contact with beta-endorphin axons in the arcuate nucleus (particularly in the posterior part where the beta-endorphin cells are located) and the medial part of the zona incerta. After light microscopic examination and color photography, the double immunostained sections were embedded for correlated electron microscopy to verify and characterize the putative synaptic connections. Electron microscopy revealed symmetric synaptic connections between beta-endorphin-immunoreactive boutons and tyrosine hydroxylase-immunopositive cell bodies and dendrites. These results together with the observation of dopamine innervation of LHRH-producing neurons and progesterone receptor-containing cells indicate that neurons of the hypothalamic dopaminergic system probably mediate opiate effects on hypophyseal hormone secretion.

Intraseptal connections redefined: lack of a lateral septum to medial septum path.

The integrity of the septohippocampal system is essential for memory formation and spatial behavior as well as for the electrical stability of the hippocampus. For many years it has been tacitly assumed or explicitly stated that the reciprocal septohippocampal loop is closed by a massive lateral septum-medial septum path. In the present study we reexamined the intraseptal connectivity with Phaseolus vulgaris leucoagglutinin tracing combined with choline acetyltransferase and parvalbumin immunohistochemistry at both the light and electron microscopic levels. We found that the previously hypothesized lateral septum to medial septum projection is extremely sparse and that the major medial septum to lateral septum path is parvalbumin-immunoreactive (likely GABAergic). The redefined circuitry has important implications for the understanding of the septal regulation of hippocampal electrical activity and the operations of the septo-hippocampal system.