Preserved memory capacities in aged Lou/C/Jall rats.

Although memory impairments are a hallmark of aging, the degree of deficit varies across animal models, and is likely to reflect different states of deterioration in metabolic and endocrinological properties. This study investigated memory-related processes in young (3-4 months) and old (24 months) Sprague-Dawley rats (SD), which develop age-linked pathologies such as obesity or insulin-resistance and Lou/C/Jall rats, which do not develop such impairments. In short- and long-term memory recognition tasks, old Lou/C/Jall rats were never impaired whereas old SD rats were deficient at 1 and 24h latencies. The expression of N-methyl-d-aspartate receptors (NMDAR)-mediated synaptic plasticity in CA1 hippocampal networks shifted towards lower activity values in old Lou/C/Jall rats whereas long-term potentiation was impaired in age-matched SD rats. Age-related decrease in NR2A subunits occurred in both strains, extended to NR2B, NR1 and GluR1 subunits in older animals (28 months) but only in SD rats. Therefore, the Lou/C/Jall rats can be considered as a model of healthy aging, not only in terms of its preserved metabolism, but also in terms of cognition and synaptic plasticity.

Sexually dimorphic distribution of sst2A receptors on growth hormone-releasing hormone neurones in mice: modulation by gonadal steroids.

The ultradian pulsatile pattern of growth hormone (GH) secretion is markedly sexually dimorphic in rodents as in primates, but the neuroanatomical mechanisms of this phenomenon are not clear. In the arcuate nucleus of the hypothalamus, GH-releasing hormone (GHRH) neurones receive somatostatinergic inputs through the sst2A receptor (sst2A-R) and the percentage of GHRH neurones bearing sst2A-R is higher in female than in male GHRH-enhanced green fluorescent protein (eGFP) mice. In the present study, we hypothesised that sst2A-R expression on GHRH neurones is modulated by gonadal steroids and constitutes a mechanism for sexually differentiated GH secretion. The distribution of sst2A-R on GHRH neurones was evaluated by immunohistochemistry in adult GHRH-eGFP mice gonadectomised and treated for 3 weeks with oestradiol or testosterone implants. In gonadectomised females supplemented with testosterone, sst2A-R distribution on GHRH neurones was reduced to the level seen in intact males, whereas oestradiol implants were ineffective. Conversely, orchidectomy induced a female 'sst2A phenotype', which was reversed by testosterone supplementation. Changes in the hepatic expression of GH-dependent genes for major urinary protein-3 and the prolactin receptor reflected the altered steroid influence on GH pulsatile secretion. In the ventromedial-arcuate region, GHRH and sst2-R, as well as GHRH and somatostatin expression as measured by the real-time polymerase chain reaction, were positively correlated in both sexes. By contrast, the positive correlation between ventromedial-arcuate GHRH and periventricular somatostatin expression in males was reversed to a negative one in females. Moreover, the positive correlation between periventricular somatostatin and ventromedial-arcuate sst2-R expressions in males was lost in females. These results suggest that, in the adult mouse, testosterone is a major modulator of sst2A distribution on GHRH neurones. This marked sex difference in sst2A-R distribution may constitute a key element in the genesis of the sexually differentiated pattern of GH secretion, possibly through testosterone-modulated changes in somatostatin inputs from hypophysiotrophic periventricular neurones.

Brain-derived neurotrophic factor but not neurotrophin-3 enhances differentiation of somatostatin neurons in hypothalamic cultures.

The present work investigated whether neurotrophins could differentially affect in vitro growth and maturation of two related subsets of hypothalamic neurons, hypophysiotropic somatostatin (SRIH) neurons projecting from the periventricular area and arcuate SRIH interneurons. For this purpose, the hypothalamus of 17-day-old rat fetuses was sampled and separated into a ventral and a dorsal fragment containing respectively periventricular and arcuate regions. Each fragment was dissociated and seeded separately in defined medium. Brain-derived neurotrophic factor (BDNF) or neurotrophin-3 (NT-3), two important members of the neurotrophin family involved in neuronal differentiation and plasticity, were added to the cultures at seeding time. After 6 or 11 days in vitro, neurons were labeled with an anti-SRIH antiserum and submitted to morphometric analysis. In parallel, SRIH mRNA was estimated by semiquantitative reverse-transcriptase-polymerase chain reaction, and neuronal SRIH content, basal and depolarisation-stimulated releases measured by radioimmunoassay. The response of control, non-labeled neurons was estimated by neuronal counts and by assaying glutamic acid decarboxylase, a marker of a large majority of hypothalamic neurons. BDNF markedly increased the size and the branching number of SRIH periventricular cell bodies. Expression of SRIH mRNA, as well as SRIH content and release into the culture medium, were also stimulated by the neurotrophin. Non-SRIH neurons were not affected by the treatment. Under the same conditions, arcuate neurons exhibited a weak, mostly transient response to BDNF. NT-3 was ineffective on either neuronal subset. Immunoneutralization of Trk receptors provided further evidence for BDNF effect specificity. The results indicate that BDNF is a selective activator of the differentiation of hypophysiotropic SRIH neurons in the periventricular area of the hypothalamus.

Membranes from pituitary intermediate lobe cells enhance differentiation of fetal hypothalamic dopaminergic neurons in primary culture.

Coculture of adult pituitary intermediate lobe (IL) cells, a target for hypothalamic dopaminergic neurons, with fetal rat hypothalamic cells accelerate differentiation of dopaminergic neurons. This involves long range diffusible as well as additional factors which may be membrane-bound. To determine whether IL membrane-bound factors contribute to the differentiating effect of IL cells, IL membranes were added to dispersed fetal hypothalamic neurons. This stimulated the outgrowth of dopaminergic neurites and elevated TH levels. Limited trypsin proteolysis of IL cell surface abolished the effect on TH levels. Addition of adenohypophyseal membranes was ineffective. Joint treatment with IL membranes, and medium conditioned (CM) over IL cells, produced the same effect on TH levels as did coculture with the same number of IL cells. The results demonstrate that IL cells express on their surface a membrane-bound factor promoting differentiation of fetal dopaminergic neurons in vitro; this factor acts in addition to diffusible activities.

Distinct populations of hypothalamic dopaminergic neurons exhibit differential responses to brain-derived neurotrophic factor (BDNF) and neurotrophin-3 (NT3).

We have previously demonstrated that differentiation of hypothalamic dopaminergic (DA) neurons can be induced in culture by their pituitary intermediate lobe target cells, through both membrane and diffusible factors. We also showed that subpopulations of DA neurons from the arcuate nucleus only, not the periventricular area, can respond to the target. Here we investigated the possibility that both neuronal subsets could also respond differentially to brain-derived neurotrophic factor (BDNF) or neurotrophin-3 (NT3). Addition of NT3, but not BDNF, enhanced growth and branching of neurites, tyrosine hydroxylase (TH) as well as increasing levels of cultured arcuate DA neurons. Conversely, BDNF, but not NT3, affected the same parameters in cultured periventricular DA neurons. The neurotrophins thus affect DA neurons in a structure and neuronal type-selective manner, since general neuronal markers were not affected by either neurotrophin. Neurotrophin effects were reversed by addition of specific antibodies directed against them or their respective receptors, TrkB or TrkC. By themselves, the antibodies inhibited development of DA neurons below that of control cultures, suggesting involvement of endogenous neurotrophins. BDNF and NT3 were indeed found in both arcuate and periventricular neurons and in the intermediate lobe. BDNF was always present as the mature peptide. The mature form of NT3 was only detected in the periventricular area; a precursor-like heavier form was present in all tissues studied. The present data suggest that NT3, but not BDNF, could participate in the differentiating action of intermediate lobe cells on arcuate DA neurons.

Somatostatin receptor subtypes sst1 and sst2 elicit opposite effects on the response to glutamate of mouse hypothalamic neurones: an electrophysiological and single cell RT-PCR study.

We have previously shown that somatostatin can either enhance or decrease AMPA/kainate receptor-mediated responses to glutamate in mouse-dissociated hypothalamic neurones grown in vitro. To investigate whether this effect is due to differential activation of somatostatin (SRIF) receptor subtypes, we compared modulation of the response to glutamate by SRIF with that induced by CH-275 and octreotide, two selective agonists of sst1 and sst2/sst5 receptors, respectively. Somatostatin either significantly decreased (49%) or increased (30%) peak currents induced by glutamate, and was ineffective in the remaining cells. Only the decreased response was obtained with octreotide, whereas only increased responses were elicited by CH-275 (47 and 35% of the tested cells, respectively). Mean amplitude variations under somatostatin or octreotide on the one hand, and under somatostatin or CH-275 on the other hand, were equivalent. Pertussis toxin pretreatment significantly decreased the number of cells inhibited by somatostatin or octreotide, but had no effect on the frequency of neurones showing increased sensitivity to glutamate during somatostatin or CH-275 application. About half of the neurones tested by single cell reverse transcriptase polymerase chain reaction (RT-PCR) expressed only one sst receptor (sst1 in 26% and sst2 in 22% of studied cells). Out of the remaining neurones, 34% displayed neither sst1 nor sst2 mRNAs, whereas 18% showed a simultaneous expression of both mRNA subtypes. Expression of sst1 or sst2 mRNA subtypes matched totally with the effects of somatostatin on sensitivity to glutamate in 79% of the neurones processed for PCR after recordings. These data show that pertussis toxin-insensitive activation of the sst1 receptor subtype mediates somatostatin-induced increase in sensitivity to glutamate, whereas decrease in the response to glutamate is linked to pertussis toxin-sensitive activation of the sst2 receptor subtype.

Profiles of amyloid precursor and presenilin 2-like proteins are correlated during development of the mouse hypothalamus.

The amyloid precursor protein (APP) and APP-like (APLP) material, as visualized with the Mab22C11 antibody, have previously been shown to be associated with radial glia in hypothalamus, which are known to promote neurite outgrowth. By Northern blot analysis, APP 695 mRNA levels increased steadily over hypothalamic development, APP 770 mRNA was transiently expressed at 12 days postnatally, and APLP mRNA was only weakly expressed in the hypothalamus. The developmental pattern of APP moeities in mouse hypothalamus and in fetal hypothalamic neurons in culture was compared with a presenilin 2 (PS2) related protein using an antibody developed against the N-terminal part of PS2. By Western blot analysis, APP and PS2-like immunoreactivity were visualized as a 100-130 and 52 kDa bands, respectively. An APP biphasic increase was observed during hypothalamic development in vivo. APP immunoreactivity was equally detected in neuronal and glial cultures, while PS2-like material was more concentrated in neurons. A correlation between APP/APP-like and PS2-like levels was observed during development in vivo. While APP was mostly associated with membrane fractions, a significant portion of PS2-like material was also recovered from cytosolic fractions in vitro. In contrast to native PS2 in COS-transfected cells, the PS2-like material did not aggregate after heating for 90 s at 90 degrees C. These results indicate a close association between APP and PS2-like material during hypothalamic development in vivo, and suggest that neuronal and glial cultures may provide appropriate models to test their interactions.

Distinct patterns of expression and physiological effects of sst1 and sst2 receptor subtypes in mouse hypothalamic neurons and astrocytes in culture.

Somatostatin (SRIF) receptor subtypes (sst) were characterized in hypothalamic neurons and astrocytes by quantitative reverse transcription-polymerase chain reaction and radioreceptor assays using [125I-Tyr0,D-Trp8]SRIF-14 as a ligand in ionic conditions discriminating between SRIF-1 (sst2, -3, and -5 receptors) and SRIF-2 (sst1 and -4 receptors) binding sites. In neurons, sstl mRNA levels were twofold higher than those of sst2, and sst3-5 expression was only minor. Astrocytes expressed 10-fold less sst mRNAs than neurons, which corresponded mostly (80%) to sst2. SRIF-1 binding site radioautography indicated that 10% of hypothalamic neurons were labelled on both cell bodies and neuritic processes, as were 35% of astrocytes. On neuronal and glial membranes, SRIF-14 and octreotide, an sst2/sst3/sst5-selective analogue, completely displaced SRIF-1 binding, whereas des-AA(1,2,5)[D-Trp8,IAmp9]SRIF (CH-275), an sst1-selective analogue, was ineffective. Using SRIF-2 conditions, only SRIF-14 and CH-275 displaced the binding on neurons. No SRIF-2 binding was observed on glia. SRIF-14 and octreotide inhibited forskolin-stimulated adenylyl cyclase activity in neurons and glia, whereas CH-275 was effective in neurons only. In patch-clamp experiments, SRIF-14 modulated the glutamate sensitivity of hypothalamic neurons with either synergistic or antagonistic effects; CH-275 was only stimulatory and octreotide inhibitory. It is concluded that hypothalamic neurons express primarily sst1 and sst2, sst2 predominates in astrocytes, and both receptors induce distinct biological effects.

Polysialylated neural cell adhesion is involved in target-induced morphological differentiation of arcuate dopaminergic neurons.

We have previously shown that the morphological and biochemical maturation of developing rat hypothalamic dopaminergic neurons is accelerated when they are cocultivated with pituitary intermediate lobe cells, one of their targets. Only two subsets of hypothalamic dopaminergic neurons (arcuate, A12, and periventricular, A14, nuclei) may project to the pars intermedia. In order to determine whether the two populations are equally responsive to coculture conditions, we microdissected the hypothalamus of 17-day-old rat fetuses in two fragments containing cell bodies from the A12 and from the A14 regions, prepared neuronal cultures from both portions and incubated them separately with intermediate lobe cells. The presence of intermediate lobe cells increased tyrosine hydroxylase levels in both dopaminergic neuron subsets, but morphological differentiation was accelerated in dopaminergic neurons originating in the arcuate nucleus only. We then investigated whether physical contact between developing arcuate neurons and their target cells was a prerequisite of the morphological effect by interposing a semipermeable membrane between cultivated neurons and intermediate lobe cells in transwell culture dishes. The morphological effect was no longer observed under transwell coculture conditions, pointing to the involvement of membrane-bound molecules. Accordingly, the stimulating effect of coculture on arcuate dopaminergic neurons was completely abolished by the removal of polysialic acid on neural cell adhesion molecules by endoneuraminidase N treatment. Thus, maturation of A12 and A14 dopaminergic neurons exhibits differential susceptibility to intermediate lobe target cells, and polysialylated-NCAM is required for the contact-dependent effect.

Differential expression of somatostatin receptors by quantitative PCR in the rat brain.

Five subtypes of somatostatin receptors (sst) have recently been cloned and reported to be expressed in rat brain. However, conventional mRNA measurement techniques do not allow to accurately compare the levels of expression of the 5 sst. Thus, we established a quantitative reverse transcriptase polymerase chain reaction method for the 5 sst. A cRNA internal standard was constructed by inserting in msst1 plasmid sequences corresponding to specific sense primers for amplification of each sst. Using a common reverse primer, a unique primer pair by receptor amplifies both wild type and standard RNAs with the same efficiency. The technique was validated by evaluating sst mRNAs in 3 brain structures in which different somatostatin receptor binding levels were previously reported. While the absolute level of expression is similar between regions, sst3 is the major subtype in cerebellum, sst1 predominates in spinal cord and sst4 and sst2 are equally expressed in the hypothalamus.

Modulation by somatostatin of glutamate sensitivity during development of mouse hypothalamic neurons in vitro.

Glutamate sensitivity development and interactions of somatostatin (SRIF) with AMPA/Kainate receptor-mediated glutamate responses were studied in dissociated hypothalamic neurons from 16-day-old mouse embryos grown in vitro. Only 18% of functionally innervated cells could be found at 6-9 DIV whereas the percentage of innervated neurons progressively increased thereafter to reach 100% at 19-22 DIV. The glutamate sensitivity, estimated from glutamate-induced peak inward current, was very low at 6-9 DIV, sharply increased at 11-14 DIV and developed at a low increase rate thereafter. SRIF either unaffected glutamate peak current (27% of the cells), or significantly decreased (50%) or increased it (23%). Pertussis Toxin pretreatment abolished the SRIF-induced decrease of the glutamate response without affecting the excitatory effect. The number of glutamate responsive neurons inhibited by SRIF increased with time in culture whereas that of neurons responding to SRIF by an increased glutamate response was not statistically modified by functional innervation. The present data suggest that increased glutamate sensitivity coincides with the onset of functional synaptogenesis in mouse hypothalamic neurons in culture. SRIF can modulate glutamate sensitivity of hypothalamic neurons with either synergistic or antagonistic effects. Since glutamate has been shown to stimulate SRIF synthesis and secretion from hypothalamic neurons, the reverse capacity of SRIF to modulate the glutamate response suggests that both transmitters exhibit complex reciprocal interactions.

Molecular pharmacology of somatostatin receptors.

Somatostatin was discovered for its ability to inhibit growth hormone (GH) secretion. Later, it was found to be widely distributed in other brain regions, in which it fulfills a neuromodulatory role, and in several organs of the gastrointestinal tract where it can act as a paracrine factor or as a true circulating factor. In mammals, two molecules of 14 (somatostatin 14) and 28 (somatostatin 28) amino acids are the only biologically active members of the family. They originate from a single gene which gives rise to a single propeptide alternately cleaved in different tissues. In 1992, a major breakthrough in our understanding of somatostatin functions was made with the cloning of five different receptor genes (sstr1 to sstr5) which belong to the seven transmembrane domain receptor family. Their closer relatives are opioid receptors. In first approximation, the tissular expression of the sstrs matches quite well with the distribution of somatostatin binding sites in the "classical" targets of the peptide ie brain, pituitary pancreatic islets and adrenals. The pharmacology of GH inhibition is very close to sstr2 binding but other actions of somatostatins have not yet been attributed clearly to a single receptor subtype. All clinically relevant agonists tested so far (octreotide, lanreotide and vapreotide) are selective of sstr2 being less potent on sstr3 and inactive for sstr1 and sstr4. Surprisingly, rat sstr5 displays nanomolar affinities for octreotide and vapreotide while these agonists are only active at much higher concentrations on human sstr5. All five receptors can be more or less efficiently coupled to inhibition of adenylate cyclase activity in transfected cell systems.(ABSTRACT TRUNCATED AT 250 WORDS)

Selective patterns of expression of G protein alpha subunits during in vitro development of hypothalamic neurons.

Expression of different alpha subunits of G proteins was studied in hypothalamic primary cultures grown in defined medium and enriched in either neurons or glial (astrocyte) cells. In parallel, the cellular distribution of Gi, Gs, and GoA subunits was visualized by in situ hybridization. Immunoblots using specific antisera and hybridization of mRNAs with specific oligonucleotide probes allowed us to characterize Gs, Gi2, and GoA as major neuronal G proteins in the hypothalamus, whereas the glial cells expressed mostly Gs, Gi2, and GoB forms. Gi was found to be expressed very early and transiently in the culture, whereas expression of Gs and GoA increased regularly with time.

Decreased choline acetyltransferase activity in nerve growth factor-transgenic mice during brain development.

Activity of the synthetic enzyme for acetylcholine, choline acetyltransferase was investigated during development and in adult nerve growth factor-transgenic mice. A conspicuous reduction of choline acetyltransferase activity was observed in the anterior brain of nerve growth factor-transgenic embryos from embryonic days 13 to 16 (E13 to E16). Choline acetyltransferase activity levels subsequently resumed to normal levels, with the exception of a 15% increase in the adult hippocampus. Nerve growth factor contents followed a similar time-course and regional distribution in normal and nerve growth factor-transgenic animals and displayed significantly higher values from E14 to the early postnatal period. Nerve growth factor contents were normal in the adult brain. In vitro experiments confirmed the involvement of nerve growth factor in the decrease of choline acetyltransferase activity levels observed in transgenic neurons during development. These results suggest a role for nerve growth factor in the initial phase of the phenotypic differentiation of cholinergic neurons. They show that nerve growth factor may, under specific development conditions, lead to a paradoxical down-regulation of choline acetyltransferase activity.

Coculture of rat melanotrophs with hypothalamic cells enhances differentiation of dopaminergic neurons.

The interaction between a glandular target and hypothalamic dopaminergic neurons during development was studied by cocultivating dispersed fetal hypothalamic and adult intermediate lobe rat cells in serum-free medium. In such conditions, hypothalamic neurons aggregated around intermediate lobe cells and were interconnected by well-developed neurites. They could be grown in coculture at lower density than alone. In regard to dopaminergic activity, both tyrosine hydroxylase content and accumulation of [(3)H]DA in the cells were significantly increased in coculture after 6 days in vitro (DIV). These effects persisted until 18 DIV, but were progressively reduced with time. Other neuronal activities (choline acetyltransferase activity or thyroliberin content) were not modified by coculture. Furthermore, dopaminergic activity was not stimulated when hypothalamic neurons were grown in the presence of anterior pituitary cells, nor mesencephalic neurons together with intermediate lobe cells, suggesting selectivity of intermediate lobe cells on hypothalamic DA neurons. After radioautographic labeling of DA neurons at 6 DIV, morphometric analysis revealed that the presence of intermediate lobe cells increased the number of branching points and the total neuritic length, without changing the number of DA neurons, the size of cell bodies, nor the number of neurites emerging from the soma. Cocultured DA neurons at 6 DIV exhibited morphological features of more differentiated neurons, as estimated by morphological analysis of 12 DIV control neurons. Thus, intermediate lobe cells induce in vitro clustering of fetal hypothalamic neuronal somata and accelerate specifically hypothalamic dopaminergic neuron maturation.

Ontogeny of thyrotropin-releasing hormone biosynthesis and release in hypothalamic neurons.

Thyrotropin-releasing hormone (TRH) is expressed at early postmitotic stages of hypothalamic neuron development, in the mouse and rat, as revealed by the presence of the mature peptide, of pro-TRH mRNAs, and of large precursor forms. This indicates a coordinate expression of several genes encoding, respectively, pro-TRH, its processing enzymes, and the cell machinery for intracellular transport, sorting, and release of TRH. During development, an acceleration of pro-TRH processing is revealed by an increased proportion of the mature peptide. This is correlated with changes in the respective distribution of pro-TRH and TRH along neurites and the ontogenesis of neurosecretory granules.

Differential expression and subcellular localization of secretogranin II and synaptophysin during early development of mouse hypothalamic neurons in culture.

Mature neurons contain two distinct regulated secretory pathways, characterized electron microscopically by so-called large dense core vesicles and small synaptic vesicles, respectively. Each vesicle type is characterized by vesicle-specific proteins, such as the granins (chromogranins/secretogranins) for the matrix of large dense core vesicles and synaptophysin for the membrane of small synaptic vesicles. So far, no data exist on the biogenesis of these two distinct vesicle types during neuronal development. We have used secretogranin II and synaptophysin as markers for the biogenesis of these two vesicle types during the development of mouse hypothalamic neurons in culture, using immunocytochemistry and biochemical analyses. By immunofluorescence, we found that secretogranin II appears as early as synaptophysin, but in a subset of neurons only, and with different subcellular localizations. It was observed in cytoplasmic areas where little or no synaptophysin immunofluorescence was detected, such as lamellipodia, emerging neurites and growth cones. At later stages, the proportion of secretogranin II-containing varicosities remained steady whereas that of synaptophysin-containing varicosities increased dramatically. By quantitative analysis we found that the level of expression of synaptophysin increased several-fold during synaptogenesis whereas that of secretogranin II decreased. These data suggest that large dense core vesicles and small synaptic vesicles can be formed separately and expressed at different levels. They provide evidence for a differential biogenesis of these two distinct vesicle types.

Alpha 1-adrenergic receptor coupling with phospholipase-C is negatively regulated by protein kinase-C in primary cultures of hypothalamic neurons and glial cells.

In the present work we evaluated the interactions of adrenergic receptors with phospholipase-C (PLC) and protein kinase-C (PKC), using an in vitro system of hypothalamic neurons and astroglial cells in primary cultures. The study was performed on immature neurons after 7 days in vitro (7 Div), that is before synaptogenesis, as well as on mature cells (14 Div). Comparisons were made between neurons and glial cells at the corresponding developmental stages. Norepinephrine (NE) increased inositol phosphates (IPs) formation in a dose- and time-dependent manner. The NE effect was mediated by alpha 1-receptor (alpha 1R) and was observed in young cells before synaptogenesis as well as in mature neuronal cultures; its amplitude was enhanced during the latter stage of the neuronal development. The coupling of alpha 1R with PLC was partially sensitive to pertussis toxin treatment and did not implicate the activation of calcium voltage-dependent channels. Activation of PKC by 12-O-Tetradecanoylphorbol 13-acetate (TPA) inhibited in a time-dependent manner the NE-stimulated production of IPs in young and mature hypothalamic neurons; however, in PKC depleted cells NE-induced IPs formation remained unchanged. In hypothalamic astroglial cell cultures the adrenergic stimulus of IPs generation was also mediated by alpha 1R. The effect was observed at both developmental stages, with a greater response in 14 Div cultures, and was insensitive to pertussis toxin treatment. As in neurons, activation of PKC resulted in inhibition of NE-induced IPs formation. These data indicate that functional interrelation between alpha 1R, PLC, and PKC is already present in immature neurons and glial cells and progressively develops in culture.

Subcellular distribution of clathrin in cultured hypothalamic neurons.

The subcellular distribution of clathrin has been examined in developing hypothalamic neurons cultured in a chemically defined medium up to synapse formation (12-13 days in vitro) and exposed, or not, to a depolarizing concentration of KCl (60 mM for 3 min) followed, or not, by a return to control KCl concentration (3 mM KCl for 3 min). Previous studies have shown that such treatments induce in synaptic boutons a rapid vesicle depletion followed by massive restoration. Using an enzyme immunoassay, we have compared the relative proportion of assembled and unassembled pools of clathrin as a function of exposure to depolarizing or repolarizing concentrations of KCl. In parallel we have localized clathrin at the electron microscopic level using immunoperoxidase. Clathrin concentration in culture is lower (0.36 vs 0.75%) and the proportion of unassembled clathrin is much higher than in the adult brain (82 vs 14%). These proportions were not affected by depolarizing or repolarizing treatments. Morphologically clathrin was exclusively detected in two neuron compartments: perikarya and synaptic boutons. In perikarya clathrin was localized as a thick coat on plasma membrane coated pits and in the Golgi zone on coated buds and vesicles, presumably located in a trans compartment. In synaptic boutons clathrin immunoreaction was found as an irregular thin rim around synaptic vesicles, whatever the polarization state of the cells, but coated vesicles were extremely rare. Taken together these findings raise the problem of the functional meaning and localization of the large unassembled pool of clathrin in such neurons and question its role in vesicular traffic in synaptic boutons.