An androgen-dependent sexual dimorphism visible at puberty in the rat hypothalamus.

Morphological studies in rodents have well documented the masculinization of the perinatal brain by estradiol derived from aromatized testosterone, and the resulting irreversible quantitative sex-differences generated in cell numbers or expression of chemical phenotypes. Here, using immunohistochemistry, we explored how this applies to the postnatal development and masculinization of the neurokinin B (NKB)-containing system of the arcuate nucleus/median eminence complex (ARC/ME). In adult rats, NKB-immunoreactive neurons exhibit an unusual, qualitative sexual dimorphism of their ventral axonal projections: to the neuropil in females, to capillary vessels in males. In adults, there was no sex-difference in the numbers of NKB-immunoreactive perikarya or capillary vessels in the ARC/ME, suggesting that this sexual dimorphism cannot be explained by the existence of supernumerary structures. At birth (day 0) the NKB system was immature in both sexes, and while its adult features emerged progressively until puberty in females, they did not develop before puberty (day 40) in males, revealing a sexual dimorphism only late postnatally. When males were orchidectomized at day 30, the masculine distribution of NKB-immunoreactive axons expected at day 40 was not seen, while it was apparent after chronic treatment with testosterone or dihydrotestosterone, suggesting a testicular masculinizing action via androgen receptors at puberty. Moreover in these prepubertal-orchidectomized males, the distribution of NKB-immunoreactive axons was surprisingly feminized by chronic estradiol alone, suggesting that NKB neurons are not irreversibly programmed before puberty. Last, in adult females, the distribution of NKB-immunoreactive axons was feminine 30 days after ovariectomy, and it was masculinized after concurrent chronic dihydrotestosterone, suggesting that NKB neurons remain responsive to androgens late in reproductive life. Thus, the sexual differentiation of the hypothalamus proceeds well beyond the perinatal period and includes the epigenetic action of non-aromatizable androgens upon subsets of neurons that have retained bipotent features.

Sexual dimorphism in the organization of the rat hypothalamic infundibular area.

The hypothalamic infundibular area is located outside the blood-brain barrier and includes, the ventromedial arcuate nucleus (vmARC) sensing circulating substances, and the median eminence (ME) where neurohormones are released into the hypothalamo-hypophysial vasculature. This integrated functional unit, pivotal in endocrine control, adjusts neuroendocrine output to feedback information. Despite a differing physiology in males and females, this functional unit has not appeared differently organized between sexes. Using immunocytochemistry, we describe here for the first time in adult rats, a conspicuous sex-difference in its axonal wiring by intrinsic glutamatergic neurons containing the neuropeptides neurokinin B (NKB) and dynorphin. In the male, NKB neurons send axons to capillary vessels of the vmARC and of the ME (only where gonadotropin-releasing hormone (GnRH) axons terminate). Electron microscopy revealed that NKB axons target the barrier of tanycytes around fenestrated capillary vessels (in addition to GnRH axons), suggesting a control of regional bidirectional permeability. In the female, NKB neurons send axons to the neuropile of the vmARC, suggesting a direct control of its sensor neurons. The other projections of NKB neurons, studied by surgical isolation of the ARC-ME complex and confocal microscopy, are not sexually dimorphic and target both integrative and neuroendocrine centers controlling reproduction and metabolism, suggesting a broad influence over endocrine function. These observations demonstrate that the mechanisms subserving hypothalamic permeability and sensitivity to feedback information are sexually dimorphic, making the infundibular area a privileged site of generation of the male-to-female differences in the adult pattern of pulsatile hormonal secretions.

Immunocytochemical detection of cholecystokinin and corticotrophin-releasing hormone neuropeptides in the hypothalamic paraventricular nucleus of the jerboa (Jaculus orientalis): modulation by immobilisation stress.

The hypothalamic response to an environmental stress implicates the corticotrophin-releasing hormone (CRH) neuroendocrine system of the hypothalamic parvicellular paraventricular nucleus (PVN) in addition to other neuropeptides coexpressed within CRH neurones and controlling the hypothalamo-pituitary-adrenal (HPA) axis activity as well. Such neuropeptides are vasopressin, neurotensin and cholecystokinin (CCK). It has previously been demonstrated that the majority of the CRH neuronal population coexpresses CCK after a peripheral stress in rats. In the present study, we explored such neuroendocrine plasticity in the jerboa in captivity as another animal model. In particular, we studied CCK and CRH expression within the hypothalamic PVN by immunocytochemistry in control versus acute immobilisation stress-submitted jerboas. The results show that CCK- and CRH-immunoreactive neuronal systems are located in the hypothalamic parvicellular PVN. The number of CCK-immunoreactive neurones within the PVN was significantly increased (138% increase) in stressed animals compared to controls. Similarly, the number of CRH-containing neurones was higher in stressed jerboas (128%) compared to controls. These results suggest that the neurogenic stress caused by immobilisation stimulates CCK as well as CRH expression in jerboas, which correlates well with previous data obtained in rats using other stressors. The data obtained also suggest that, in addition to CRH, CCK is another neuropeptide involved in the response to stress in jerboa, acting by controlling HPA axis activity. Because CCK is involved in the phenotypical plasticity of CRH-containing neurones in response to an environmental stress, we also explored their coexpression by double immunocytochemistry within the PVN and the median eminence (i.e. the site of CRH and CCK corelease in the rat) following jerboa immobilisation. The results show that CCK is not coexpressed within CRH neurones in either control or stressed jerboa, suggesting differences between jerboas and rats in the neuroendocrine regulatory mechanisms of the stress response involving CRH and CCK. The adaptative physiological mechanisms to environmental conditions might vary from one mammal species to another.

Oestradiol effect on galanin-immunoreactive neurones in the diencephalon of the ewe.

Galanin is a neuropeptide involved in the regulation of numerous functions such as reproduction. In female rats, this peptide stimulates gonadotropin-releasing hormone (GnRH)/luteinizing hormone release and its synthesis is stimulated by oestradiol. It could therefore be an intermediary between the oestrogenic signal from the ovaries and the GnRH neurones (e.g. during the time course leading to the preovulatory GnRH surge). However, although the involvement of galanin is well-known in rodents, it is poorly understood in ewes. Using immunohistochemistry with a specific antigalanin antiserum, we detected the peptide in neurones of two groups of ovariectomized ewes treated for 6 h with subcutaneous implants, either with oestradiol (experimental group) or empty (control group). The galanin-immunoreactive neurones were counted in three areas, the preoptic area, the bed nucleus of the stria terminalis and the infundibular nucleus, using a computerized image analysis system. There was no change in the mean number of galanin-immunoreactive (GAL-ir) neurones in the infundibular nucleus (37 +/- 12 neurones/section in treated animals and 31 +/- 11 in controls) or in the bed nucleus of the stria terminalis (22 +/- 5 neurones/section in treated animals and 16 +/- 4 in controls), but the number of GAL-ir neurones was higher in the preoptic area in treated than in control ewes (35 +/- 4 versus 14 +/- 10, P < 0.001). To determine whether the neurones of the preoptic area were directly sensitive to oestradiol, we performed double immunohistochemical labelling for oestradiol receptor alpha and galanin. More than 50% of the GAL-ir neurones contained the oestradiol receptor alpha and therefore could be directly regulated by oestradiol. These results indicate that oestradiol might act directly on a GAL-ir neuronal population situated in the preoptic area, without any effect on the GAL-ir neurones of the infundibular nucleus or the bed nucleus of the stria terminalis. Because a 6-h oestradiol treatment can induce a preovulatory GnRH surge in ewes, the GAL-ir neuronal population of the preoptic area might be one of the neuronal systems by which oestradiol activates the GnRH neurones. However, although the morphological relationships between galanin and GnRH neurones have been described in rodents, they remain to be demonstrated in the ewe.

Mapping of tachykinins in the cat spinal cord.

Using an indirect immunoperoxidase technique, the location of cell bodies and fibers containing substance P, neurokinin A and neurokinin B was studied in the cat spinal cord. The former two neuropeptides showed a widespread distribution throughout the whole spinal cord, whereas the distribution of neurokinin B was more restricted. Neurokinin A-immunoreactive structures showed a more widespread distribution and a higher density than the immunoreactive structures observed to contain substance P. In the cat spinal cord, we observed cell bodies containing neurokinin A, but no cell bodies containing neurokinin B or substance P were found. These cell bodies were located in laminae V (sacral 1 and 2 levels), VI (sacral 1 and 3), VII (lumbar 7, sacral 1 and 3, caudal 1) and X (sacral 1). Laminae I and II showed the highest density of immunoreactive fibers for each of the three tachykinins studied, being in general lamina IV who showed the lowest number of immunoreactive fibers containing substance P, neurokinin A or B. The anatomical distribution of the three tachykinins studied in the cat spinal cord indicates that the neuropeptides could be involved in the neurotransmission and/or in the neuromodulation of nociceptive information, as well as in autonomic and affective responses to pain. Moreover, the involvement of substance P, neurokinin A or B in other functions unrelated to the transmission of pain is also possible (autonomic and motor functions). The distribution of the neuropeptides studied in the cat is compared with the location of the same neuropeptides in the spinal cord of other species. The possible origin of the tachykinergic fibers in the cat spinal cord is also discussed.

Molecular and electrophysiological evidence for a GABAc receptor in thyrotropin-secreting cells.

In the pituitary, GABA regulates the release of several hormones via different receptors. GABA(C) receptors are heterooligomers that differ from GABA(A) receptors in that they contain p-subunits and are insensitive to bicuculline. However, molecular and functional evidence for the presence of GABA(C) receptors outside the retina has yet to be established. The present work was performed on guinea pig and rat pituitaries. Both Northern blot and RT-PCR analysis showed that, although rho1- and rho2-subunits were expressed at similar levels in the rat retina, rho1 messenger RNA (mRNA) was enriched, relative to rho2 mRNA in the rat pituitary. Northern blot experiments also showed that, in the pituitary, rho1 and rho2 mRNAs are shorter in size than those expressed in the retina. The use of a subunit-specific antibody revealed colocalization of rho1-subunit and anti-TSH labeling on rat pituitary sections. TSH guinea pig pituitary cells were also labeled with a rho-subunit antiserum. Moreover, whole-cell patch clamp on single guinea pig TSH cells showed that GABA induced a bicuculline-insensitive Cl- current. In contrast to the Cl- current generated by GABA(C) receptors in the retina, the bicuculline-insensitive Cl- currents in TSH cells quickly desensitized. These results suggest that a novel GABA(C) receptor may regulate TSH secretion and that the structure and/or biochemical regulation of this pituitary receptor is different from that found in the retina.

Expression of neuropeptide Y precursor-immunoreactivity in the hypothalamic dopaminergic tubero-infundibular system during lactation in rodents.

Evidence from physiological studies in rats shows that neuropeptide Y (NPY) has marked neuroendocrine effects on anterior pituitary function, and especially on LHRH and LH secretions. However, previous immunohistochemical studies in rats have revealed only scarce NPY-axons of medullary origin in the external zone of the hypothalamic median eminence, the common termination site of neuroendocrine adenohypophysiotropic systems. In view of this apparent contradiction, we used light microscopic immunohistochemistry to reassess the distribution of NPY in the hypothalamus of rodents of both sexes under physiological (estrous cycle in rats, pregnancy in rats, and lactation in both rats and mice) and experimental (gonadectomy in rats and adrenalectomy in both rats and mice) conditions with alterations of reproductive functions. We reasoned that such manipulations could induce changes in immunoreactivity in the NPY system involved in neuroendocrine regulation and would thus make it apparent to us. We show here that immunoreactivity for NPY and its carboxyterminal precursor-associated peptide are dramatically increased in the external median eminence of lactating female animals when compared to the other animal groups. This NYP-precursor-immunoreactivity is present, throughout lactation, in the tyrosine hydroxylase-immunoreactive (and therefore possibly dopaminergic) tubero-infundibular system. This immunoreactivity disappears rapidly from the median eminence after pup-removal. These observations suggest a role for NPY-precursor-derived peptides in the control of the suckling-induced PRL secretion and also demonstrate the chemical plasticity of the median eminence during a normal physiological event. Since in nonlactating animals and especially in normal cycling females NPY-precursor-immunoreactivity was detected in the system of medullary origin only, we conclude that, by exclusion, this system might be the one responsible for modulating gonadotropic secretion at the median eminence and/or pituitary levels.

Localization, identification, and action of galanin in the frog adrenal gland.

The distribution of galanin-like immunoreactivity was studied in the adrenal gland of the frog Rana ridibunda using the indirect immunofluorescence technique. A dense network of varicose fibers immunoreactive to galanin was found in the adrenal tissue. A combination of HPLC analysis and RIA detection was used to characterize galanin-like immunoreactivity in frog adrenal gland extracts. The elution profile revealed the existence of a single form of galanin exhibiting the same retention time as synthetic frog galanin. The possible involvement of galanin in the regulation of corticosteroid secretion was investigated in vitro using a perifusion system for frog adrenal slices. For concentrations ranging from 10(-9) to 3 x 10(-6) M, synthetic frog galanin induced a dose-dependent inhibition of corticosterone and aldosterone release. Repeated pulses of galanin (10(-6) M), given at 90-min intervals, resulted in a reproducible inhibition of corticosteroid secretion without any apparent tachyphylaxis. During prolonged administration of galanin (10(-6) M), the steroidogenic effect of ACTH (10(-9) M) was significantly reduced. In contrast, galanin did not attenuate the stimulation of corticosteroid secretion induced by the angiotensin II analog [Sar1,Val5]angiotensin II. These results show the occurrence of galanin in fibers innervating the frog adrenal gland. The data also demonstrate that synthetic galanin inhibits spontaneous and ACTH-induced corticosteroid release. Taken together, these findings suggest that galanin, released by nerve fibers in the adrenal tissue, can act locally as a modulator of steroid secretion.

Distribution of cholecystokinin-like-immunoreactive neurons in the guinea pig forebrain.

The distribution of cholecystokinin (CCK)-immunoreactive nerve fibers and cell bodies was studied in the forebrain of control and colchicine-treated guinea pigs by using an antiserum directed against the carboxyterminus of CCK octapeptide (CCK-8) in the indirect immunoperoxidase technique. Virtually all forebrain areas examined contained immunoreactive nerve fibers. A dense innervation was visualized in; neocortical layers II-III, piriform cortex, the medial amygdala, the medial preoptic area, a circumventricular organ-like structure located at the top of the third ventricle in the preoptic area, the subfornical organ, the posterior bed nucleus of the stria terminalis, the posterior globus pallidus (containing labeled woolly fiber-like profiles), the ventromedial hypothalamus, the median eminence, and the premammillary nucleus. A moderately dense innervation was visualized elsewhere excepted in the septum and thalamus where labeled axons were comparatively few. Immunoreactive perikarya were abundant in: neocortex (especially layers II-III), piriform cortex, amygdala, the median preoptic nucleus, the bed nucleus of the stria terminalis, the hypothalamic paraventricular (parvicellular part), arcuate, and dorsomedial (pars compacta) nuclei, the dorsal and perifornical hypothalamic areas, and throughout the thalamus. Areas also containing a moderate number of labeled cell bodies were the medial preoptic area, the globus pallidus, the caudate-putamen, and the periventromedial area in the hypothalamus. Immunostained perikarya were absent or only occasionally observed in the septum, the suprachiasmatic nucleus, the magnocellular hypothalamoneurohypophyseal nuclei, and the ventral mesencephalon. In the adenohypophysis, corticomelanotrophs were labeled in both males and females, and thyrotrophs were labeled in females only. This distribution pattern of CCK-8 immunoreactivity is compared to those previously recorded in other mammals. This shows that very few features are peculiar to the the guinea pig. It is discussed whether some interspecific differences in immunostaining are real rather than methodological.

Fine structural studies of growth-hormone-releasing-factor (GRF)-immunoreactive neurons and their synaptic connections in the guinea pig arcuate nucleus.

The fine structure of neurons containing human growth-hormone-releasing factor (hGRF) immunoreactivity located in the arcuate nucleus of the guinea pig was studied by means of the preembedding immunohistochemical technique. The perikaryon of labeled neurons was fusiform or ovoid; the nucleus was regular in shape and contained a prominent nucleolus. The main ultrastructural features of the hGRF-immunoreactive neurons were the presence of numerous labeled secretory granules (100-120 nm in diameter) and the abundance and the enlargement of the organelles involved in the synthesis of the peptides: a well-developed rough endoplasmic reticulum and a conspicuous Golgi apparatus. Synaptic inputs were observed on immunoreactive perikarya but, above all, on the labeled dendrites. The unstained presynaptic nerve endings most often contained only small clear vesicles and formed symmetrical contacts. In rare cases, the presynaptic terminals exhibited both small clear and large dense vesicles and constituted asymmetrical contacts. Immunoreactive nerve endings were also observed in this area: the synaptic boutons contained large, stained vesicles and small, unlabeled, clear vesicles. These axon terminals made synaptic contacts with unstained dendritic processes; the contacts were symmetrical. The results indicate that hGRF-immunoreactive neurons of the guinea pig arcuate nucleus present morphological features of neuroendocrine cells. Moreover, the presence of hGRF-labeled nerve endings in the arcuate nucleus itself suggests that a substance related to hGRF might be a neuromodulator, at least in this area.

GABA and enkephalin in the lateral septum of the guinea pig: light and electron microscopic evidence for interrelations.

Tract tracing techniques combined with immunohistochemistry in rats and guinea pigs have demonstrated the existence of a hypothalamo-lateral septum enkephalinergic pathway. Numerous enkephalinergic nerve endings encompass cell bodies located in the lateral septum. The present immunocytochemical study, at light and electron microscopic levels, was undertaken in the guinea pig brain to determine whether the contacted perikarya contain gamma-aminobutyric acid (GABA). The antisera against GABA revealed the presence of immunoreactive cell bodies throughout the lateral septum. At the light microscopic level, most GABA neurons appeared round while others were oval with one or two emerging dendrites. Ultrastructurally, cell bodies displayed a moderate number of organelles and a pale nucleus with frequent indentations of the nuclear envelope. The precise relationship between GABA neurons and enkephalinergic terminals was examined by means of a double-immunostaining method showing that 60% of cell bodies receiving synaptic inputs from enkephalinergic afferents contained GABA. These results show that the hypothalamo-septal enkephalinergic pathway prominently innervates GABA-containing neurons and also provide anatomical basis suggesting a disinhibitory role for this enkephalinergic tract.

Comparative distribution of mammalian GnRH (gonadotrophin-releasing hormone) and chicken GnRH-II in the brain of the immature Siberian sturgeon (Acipenser baeri).

The brain of the sturgeon has recently been shown to contain at least two forms of GnRH (gonadotropin-releasing hormone), mammalian GnRH (mGnRH) and chicken GnRH-II (cGnRH-II). In this study, we compared the distribution of immunoreactive (ir) mGnRH and cGnRH-II in the brain of immature Siberian sturgeons (Acipenser baeri). The overall distribution of mGnRH was very similar to the distribution of sGnRH in teleosts such as salmonids or cyprinids. mGnRH-ir perikarya were observed in the olfactory nerves and bulbs the telencephalon, the preoptic region, and the mediobasal hypothalamus. All these cell bodies are located along a continuum of ir-fibers that could be traced from the olfactory nerve to the hypothalamopituitary interface. No ir-fibers were observed in the anterior lobe of the pituitary, but a few were seen to enter the neurointermediate lobe. mGnRH-ir fibers were detected in many parts of the brain, particularly in the forebrain. mGnRH-ir cerebrospinal fluid-contacting cells were observed in the telencephalon, the preoptic region, and the mediobasal hypothalamus. In contrast, cGnRH-II was present mainly in the posterior brain, although a few ir axons were seen in the above-mentioned territories. In particular, cGnRH-II-ir cells bodies, negative for mGnRH, were consistently observed in the nucleus of the medial longitudinal fasciculus of the midbrain tegmentum. The cGnRH-II innervation in the optic tectum, cerebellum, vagal lobe, and medulla oblongata was more abundant than the mGnRH innervation in the same areas. This study provides evidence that the organization of the GnRH systems in a primitive bony fish is highly similar to that reported in teleosts and further documents the differential distribution of two forms of GnRH in the brain of vertebrates.

Characterization of trout galanin and its distribution in trout brain and pituitary.

Galanin was purified from an extract of the stomach of the rainbow trout, Oncorhynchus mykiss, and its primary structure was established as Gly-Trp-Thr-Leu-Asn-Ser- Ala-Gly-Tyr-Leu10-Leu-Gly-Pro-His-Gly-Ile-Asp-Gly-His-Arg20- Thr-Leu-Ser-Asp- Lys-His-Gly-Leu-Ala. Trout galanin shows six amino acid substitutions compared with pig galanin, but the N-terminal region (residues 1-14) has been fully conserved. The distribution of galanin-immunoreactive (GAL-IR) structures in the trout brain and pituitary was studied via immunohistochemistry. GAL-IR cell bodies were observed only in the caudal telencephalon, the preoptic region, and the mediobasal hypothalamus. GAL-IR fibers, however, are widely distributed throughout the brain, with a much lower density in the midbrain and posterior brain than in the tel- and diencephalon. Particularly dense innervation of the mediobasal hypothalamus, the ventral and supracommissuralis parts of the caudal telencephalon, and the region above and below the anterior commissure was observed. A heavy innervation of the pituitary was consistently detected. GAL-IR fibers were present in neurohypophyseal digitations of both the anterior and intermediate lobes with highest density in the region of the proximal pars distalis, where growth hormone and gonadotropic cells are located. Fibers were also seen in digitations of the rostral pars distalis, in particular between the prolactin follicles. The distribution of GAL-IR neurons in the central nervous system and pituitary of the trout suggests that the peptide may exercise an important role in the regulation of neuroendocrine functions, particularly those related to reproduction.

Comparative distribution of neurotensin-like immunoreactivity in the brain of a teleost (Carassius auratus), an amphibian (Hyla meridionalis), and a reptile (Gallotia galloti).

The distribution of neurotensin (NT) was studied in the brain of three species belonging to the three major classes of cold-blooded vertebrates: teleost fishes (Carassius auratus), anuran amphibians (Hyla meridionalis), and reptiles (Gallotia galloti; Lacertidae). By using antibodies directed against synthetic bovine NT in the three species, immunoreactive cell bodies were discovered mostly in the telencephalon and diencephalon, in particular at the level of the preoptic region the mediobasal hypothalamus, and the thalamus. In the frog and the lizard, additional immunoreactive (ir) structures were observed in the optic tectum and the tegmentum of the mesencephalon. In the goldfish pituitary, an extensive innervation was consistently observed at the level of the rostral pars distalis, whereas in both frog and lizard, positive fibers were only detected in the external layer of the median eminence. In the three species there is a striking overlap between the distribution of the NT-ir cell bodies and that of the target cells for sexual steroids. The results are discussed in relation with those reported in birds and mammals, and with the possible interactions among NT, sexual steroids, and the neuroendocrine control of pituitary hormone release, in particular prolactin and gonadotrophin.

Simultaneous depletion of neurokinin A, substance P and calcitonin gene-related peptide from the caudal trigeminal nucleus of the rat during electrical stimulation of the trigeminal ganglion.

The central terminals of the primary sensory trigeminal ganglion (TG) neurons projecting into the caudal trigeminal nucleus (CTN) of the rat exhibit neurokinin A (NKA)-, substance P (SP)-, and calcitonin gene-related peptide (CGRP)-immunoreactivities (IRs). We stimulated the TG in the rat to induce some of the alterations which might occur during migraine (neurogenic inflammation). Under a stereotaxic apparatus and by means of a bipolar electrode, one-side TG of the animals were electrically stimulated (7.5 Hz, 5 ms, 0.8-1. 4 mA) with square pulses for 5 min. Then, using immunohistochemical methods, the lower medulla of each rat was studied for NKA-, SP- and CGRP-IRs. Light microscopic examination of brain-stem sequencial sections revealed a simultaneous decrease in the immunoreactivities of all neuropeptides (NKA, SP and CGRP) in the CTN ipsilateral to TG stimulation in comparison with the other (not stimulated) side CTN. It is suggested that this decrease in immunoreactivity would be due to the co-release of neuropeptides following noxious stimuli and that NKA, SP and CGRP might therefore act as co-transmitters or co-modulators at the first central synapses of the trigeminal sensory pathway.

Control of rat hypothalamic pro-opiomelanocortin neurons by a circadian clock that is entrained by the daily light-off signal.

Previous studies have clearly demonstrated that the immediate-early gene, c-fos can regulate, through its protein product Fos, the expression of the pro-opiomelanocortin gene. In the present study, immunohistochemistry for Fos and beta-endorphin was used to assess the basal activity of hypothalamic pro-opiomelanocortin-producing neurons throughout a 12 h light/12 h dark cycle. Here, we showed that Fos is undetectable in most beta-endorphin neurons from late morning until 30 min after light offset in the evening, whereas Fos is spontaneously expressed in these neurons after 1 h following dark onset. The number of beta-endorphin neurons expressing Fos increases continuously during the first half of the dark phase, is maximal at the middle of this phase and decreases through late night and early morning, reaching a nadir 2-3 h after light onset. Acute shifts of lighting parameters allowed us to demonstrate that the light-off signal per se is neither sufficient nor necessary for Fos expression in beta-endorphin neurons. However, when recurrent, this signal is able to entrain Fos expression after a period of adaptation to the new light/dark schedule. Moreover, an expression of Fos in beta-endorphin neurons persists during subjective night in rat exposed to constant light or constant dark for two to three days. Thus, the occurrence of the daily rhythmic increase in the expression of Fos protein in hypothalamic pro-opiomelanocortin neurons exclusively at (subjective) night suggests that these neurons are, most likely, controlled by a (circadian) nocturnal oscillator. Our data also reveal an interesting property of this oscillator: its entrainment by the daily light-to-dark transition signal.

Direct and indirect enkephalinergic synaptic inputs to the rat arcuate nucleus studied by combination of retrograde tracing and immunocytochemistry.

The origin of both direct and indirect enkephalinergic innervation potentially able to influence neurons of the rat arcuate nucleus has been investigated by combining enkephalin immunocytochemistry and retrograde axonal transport of a wheatgerm agglutinin-Apo horseradish peroxidase-gold complex. Twenty four hours after tissue injections of small volumes (20 nl) of the tracer into the arcuate nucleus, rats were treated with colchicine and killed. In order to localize the enkephalinergic cells which directly innervate the arcuate nucleus, Vibratome sections were first silver-stained for detection of the wheatgerm agglutinin-Apohorseradish peroxidase-gold complex and then processed for enkephalin immunohistochemistry. To study the indirect enkephalinergic input to the arcuate nucleus, an electron microscope detection of immunoreactive synapses was carried out in areas rich in retrogradely labeled perikarya. Perikarya both immunoreactive and retrogradely labeled were observed ipsilaterally to the injection site in telencephalic structures such as the bed nucleus of the stria terminalis, medial preoptic and adjacent periventricular areas. Hypothalamic ipsilateral doubly labeled cells were localized principally in the dorsomedial nucleus and rostral arcuate nucleus. The major direct inputs arising from brainstem structures concerns the dorsal and ventral parabrachial nuclei. Moreover, at the ultrastructural level, numerous enkephalinergic terminals were demonstrated to synapse with retrogradely labeled perikarya and dendrites localized in the medial preoptic area, the hypothalamic paraventricular nucleus and the parabrachial nuclei providing evidence for an important enkephalinergic input on neurons projecting to the arcuate nucleus. Taken together, our light and electron microscope studies strongly suggest that the arcuate nucleus is the target of an enkephalinergic control originating from several regions and acting either directly or indirectly on neurons projecting to the arcuate nucleus.

Localisation of GABA(A) receptor epsilon-subunit in cholinergic and aminergic neurones and evidence for co-distribution with the theta-subunit in rat brain.

In situ hybridisation and immunohistochemical methodologies suggest the existence of a large diversity of GABA(A) receptor subtypes in the brain. These are hetero-oligomeric proteins modulated by a number of clinically important drugs, depending on their subunit composition. We recently cloned and localised the rat GABA(A) receptor epsilon-subunit by in situ hybridisation and immunohistochemical procedures. Here, in a dual-labelling immunohistochemical study in the rat brain, we used our affinity-purified antiserum to epsilon with antisera to markers of cholinergic, catecholaminergic, and serotonergic neurones. As far as cholinergic systems were concerned, epsilon-immunoreactivity was expressed in all forebrain cell-groups, as well as in the caudal lateral pontine tegmentum and dorsal motor nucleus of the vagus nerve. As far as dopaminergic systems were concerned, epsilon-immunoreactivity was found to be expressed in a great number of hypothalamic cell-groups (A15, A14 and A12) and in the substantia nigra pars compacta. The noradrenergic, and to a lesser extent, adrenergic cell-groups were all epsilon-immunoreactive. Also, epsilon-immunoreactivity was detected in all serotonergic cell-groups. We also revealed by in situ hybridisation in a monkey brain that epsilon mRNA was expressed in the locus coeruleus, as previously observed in rats. Finally, by using in situ hybridisation in rat brains, we compared the distribution of the mRNA of epsilon with that of the recently cloned theta-subunit of the GABA(A) receptor. Both subunits showed strikingly overlapping expression patterns throughout the brain, especially in the septum, preoptic areas, various hypothalamic nuclei, amygdala, and thalamus, as well as the aforementioned monoaminergic cell-groups. No theta-mRNA signals were detected in cholinergic cell-groups. Taken together with previously published evidence of the presence of the alpha3-subunit in monoamine- or acetylcholine-containing systems, our data suggest the existence of novel GABA(A) receptors comprising alpha3/epsilon in cholinergic and alpha3/theta/epsilon in monoaminergic cell-groups.

Corticoliberin-immunoreactive cell bodies localised in two distinct areas of the sheep hypothalamus.

The localisation of corticoliberin producing neurones in the sheep hypothalamus was attempted with an antiserum directed against synthetic ovine CRF by the indirect immunofluorescence procedure. Synthetic ovine corticoliberin-immunoreactive fibres were detected, in order of decreasing importance, in the external median eminence, in the caudal neural lobe around capillaries, at the boundary of the neural and intermediate lobe, around the anterior commissure, in the paraventricular nuclei and in the posterior hypothalamus and midbrain, suggesting that synthetic ovine corticoliberin-related substances act not only on anterior pituitary tissue, but also on the intermediate lobe, on central neurones and on peripheral target organs. Two groups of cell bodies reacted to the anti-synthetic ovine corticoliberin antiserum. The first group was located in the paraventricular nuclei and consisted of 15-20 microns diameter cell bodies with a granular cytoplasm. The second group was located mainly in the dorsolateral caudal hypothalamus, and the cell bodies were smaller (10-15 microns) and had a smooth cytoplasm. No cell bodies were detected in the basal hypothalamus). Synthetic ovine corticoliberin-immunoreactive structures did not contain immunoreactive neurophysin. The synthetic ovine corticoliberin-immunoreaction in the paraventricular neurones was abolished by preincubating the antiserum with synthetic ovine corticoliberin but not with sauvagine or several other peptides. The immunoreaction in the posterior hypothalamic groups was abolished by preincubating the synthetic ovine corticoliberin antiserum with both synthetic ovine corticoliberin and sauvagine, but not with other peptides. The results suggest that the immunoreaction was specific for synthetic ovine corticoliberin in the paraventricular but not posterior hypothalamic region. The relative contribution of both areas to synthetic ovine corticoliberin-like peptides containing nerve terminals of the median eminence remains to be established.

Cholecystokinin-like immunoreactivity in the dorsal horn of the spinal cord of the rat: a light and electron microscopic study.

Cholecystokinin-like immunoreactivity was investigated with an indirect immunoperoxidase technique in the whole spinal cord with the light microscope and in the dorsal horn with the electron microscope. Intraparenchymal injections of colchicine were performed to allow the detection of cholecystokinin-like immunoreactive cell bodies. Rats treated at birth with capsaicin were also studied at the light microscope. Numerous cholecystokinin-like immunoreactive fibres and varicosities were found in the two superficial layers of the dorsal horn and in the intermedio-medial nucleus; cholecystokinin-like immunoreactive cell bodies were also present in these two regions. After neonatal capsaicin treatment, the number of cholecystokinin-like immunoreactive fibres and varicosities was strongly reduced in the dorsal horn. At the electron microscope level, cholecystokinin-like immunoreactivity was localized in numerous neurites often filled with vesicles (axon terminals and dendrites containing vesicles) and in few cell bodies and dendrites. The immunoreaction was found mainly associated with ribosomes, granular reticulum, neurotubules and vesicles. Large granular vesicles were filled with the reaction product whereas small and medium-sized vesicles showed a varying degree of immunoprecipitate around their membrane. In addition dense "granules" of precipitate were observed in numerous presynaptic neurites. Cholecystokinin-like immunoreactive axons were of small calibre and mostly unmyelinated. Cholecystokinin-like immunoreactive axon terminals made asymmetric synaptic contacts with generally unlabelled dendrites or dendritic spines. A single labelled nerve terminal could contact several different dendrites in structures resembling glomeruli. Few axo-somatic synapses but a relatively high number of axo-axonic contacts were seen. About half of these axo-axonic contacts involved pre- and postsynaptic profiles. Both light and electron microscopic observations led us to the conclusion that some of the cholecystokinin-like immunoreactive fibres of the dorsal horn originate in the spinal ganglia via capsaicin-sensitive C afferents; and some from intrinsic neurons, particularly islet cells. Other fibres may come from supraspinal centres, other local neurons or capsaicin-insensitive afferents from the spinal ganglia. The results are discussed with regard to data in the literature, particularly those concerned with the specificity of the cholecystokinin antibodies; it is hypothesized that several types of cholecystokinin-like immunoreactive peptides may be present in the dorsal horn, depending on their origin (supraspinal, intrinsic or peripheral).(ABSTRACT TRUNCATED AT 400 WORDS)