Identification of catecholamine and luteinizing hormone-releasing hormone (LHRH)-containing neurons in primary cultures of dispersed cells of the basal hypothalamus

A chemiluminescent catecholamine assay: its application for monitoring adrenergic transmitter release

A chemiluminescent procedure for measuring catecholamines (dopamine, norepinephrine, epinephrine) is described. It is based on the observation that lactoperoxidase catalyses both the oxidation of catecholamines, and the chemiluminescent reaction of luminol with their oxidation product. The assay has been adapted for continuously monitoring the release of catecholamines from adrenergic tissues, from cell suspensions and from cells loaded in culture with dopamine.

Effects of thyrotropin-releasing hormone and phorbol ester on dopamine release from dispersed rat tuberoinfundibular dopaminergic neurons

We have investigated the intracellular mechanisms underlying thyrotropin-releasing hormone (TRH)-mediated [3H]dopamine ([3H]DA) release from dispersed rat tuberoinfundibular dopaminergic (TIDA) neurons. The specific binding of [3H]Me-TRH to these cells is characterized by a single, high-affinity binding site (Kd = 1.2 nM) with a Bmax value of 178 fmol/mg protein. Thyrotropin-releasing hormone markedly increased [3H]DA release and intracellular free calcium concentration ([Ca2+]i) in TIDA neurons, and its effect was abolished by treatment with EGTA (5 mM) or chlordiazepoxide, a specific TRH receptor antagonist (10 microM). Furthermore, to examine the involvement of protein kinase C on [3H]DA release, we investigated the effect of phorbol myristate acetate (PMA), which is known to activate protein kinase C directly. Phorbol myristate acetate induced a significant increase in [3H]DA release in a concentration-dependent manner. Treatment with TRH (1 microM) plus PMA (100 nM) resulted in an additive increase in [3H]DA release. Thyrotropin-releasing hormone (1 microM) still increased [3H]DA release even after preincubation with PMA (500 nM) for 24 h, but PMA (100 nM) did not under the same conditions. These results suggest that TRH may induce DA release in dispersed rat TIDA cells by increasing calcium influx and activating the protein kinase C system.

Gene transfer of a reserpine-sensitive mechanism of resistance to N-methyl-4-phenylpyridinium

The toxin N-methyl-1,2,3,6-tetrahydropyridine produces a model of neural degeneration very similar to idiopathic Parkinson disease. To understand the cellular mechanisms that modulate susceptibility to its active metabolite N-methyl-4-phenylpyridinium (MPP+), we have transfected a cDNA expression library from the relatively MPP(+)-resistant rat pheochromocytoma PC12 cells into MPP(+)-sensitive Chinese hamster ovary (CHO) fibroblasts. Selection of the stable transformants in high concentrations of MPP+ has yielded a clone extremely resistant to the toxin. Reserpine reverses the resistance to MPP+, suggesting that a transport activity protects against this form of toxicity, perhaps by sequestering the toxin within an intracellular compartment. In support of this hypothesis, dopamine loaded into the CHO transformant shows a localized distribution that is distinct from the pattern observed in wild-type cells and is also reversed by reserpine.

Cytocidal effects of bromocriptine, somatostatin analog, and heat on growth hormone-secreting pituitary adenoma in vitro

The effects of bromocriptine (BC), a somatostatin analog (SMS), and heat on the secretion of growth hormone (GH) and prolactin (PRL), and on the morphologic features of human GH-secreting pituitary adenoma were studied in vitro. The treatment with BC, SMS, or heat (41.5 degrees C and 42.5 degrees C) markedly suppressed the secretion of GH and PRL from the adenoma cells and reduced the number of cells immunoreactive with GH or PRL. The combined treatment with BC and heat induced a marked reduction in the number of GH and PRL cells consistent with the effect on the secretion of GH and PRL. These results suggest that BC, SMS, and heat treatments produced the cytotoxic effects on pituitary adenoma cells, and that the simultaneous treatment of BC and heat enhanced this effect.

Solitary hypothalamic neurons inherently express vasopressin and tyrosine hydroxylase

Hypothalamic neurons were grown as single cells in three-dimensional culture. Solitary neurons lacking cell contacts were immunocytochemically examined for inherent expression of vasopressin (VP), tyrosine hydroxylase (TH), and luteinizing hormone releasing hormone (LHRH). Immunoreactive VP and TH were detected within a day. Sixty to eighty-five percent of neurons displayed homogeneously distributed reaction product for VP or TH. One percent exhibited intense punctate staining of somas and varicosities. Few neurons stained for LHRH. Results indicate that hypothalamic neurons can express appropriate neuropeptides and transmitter-specific products without contacting other neurons or nonneuronal cells. Thus, this culture system may provide a useful model to study intrinsic neuronal processes.

An immunochemical and biochemical study of catecholaminergic activity in dissociated hypothalamic cultures

Dopamine (DA)-containing cells of the medial basal hypothalamus (MBH) were dissociated and maintained in culture for up to 9 days. Cultures were evaluated both biochemically and immunochemically for DA activity. DA biosynthesis was determined using incorporation of [3H]tyrosine and was analyzed by HPLC with electrochemical detection. Immunochemical studies were performed to identify tyrosine hydroxylase (TH)-positive and neuron-specific enolase (NSE)-positive cells. Morphometric analyses determined the cell size, density, process length and the percent of neurons which were catecholaminergic. TH-positive neurons ranged from 6 to 8% of the total neuronal population when examined over days 3-9 of culture and the length of TH-positive neurites was significantly greater than that of NSE-positive cells. There was incorporation of [3H]tyrosine into DA as evidenced by the presence of [3H]DA in both the media and tissue and the inhibition of synthesis with alpha-methyl-p-tyrosine. There was a greater amount of labeled DA in the media than in the tissue at every time point examined. On the other hand, biosynthesis of DA in fresh brain tissue revealed approximately equal levels of DA in the media and tissue. These studies indicate that DA continues to be synthesized in dissociated cultures of MBH as evidenced by both the biochemical and immunochemical analyses and that there appears to be some alteration in the ability of these neurons to store the newly synthesized amine.

Corticosteroid effects on cholinergic enzymes in ethanol-treated fetal brain cell cultures

In the presence of ethanol, corticosterone and dexamethasone inhibit choline acetyltransferase and acetyl-cholinesterase activities in cultured fetal brain cells of the rat. These results suggest that corticosteroids may have an important influence on the activity of cholinergic enzymes in the fetal brain may antagonize the effects of ethanol in this setting.

Studies of neurotransmitter chemistry of central nervous system neurons in primary tissue culture

Primary tissue culture methods have been applied to various areas of the central nervous system, including cerebral cortex, spinal cord, cerebellum, hippocampus, hypothalamus, striatum, mesencephalon, lower brain stem and retina. Experimental studies in vitro involving central neurotransmission are discussed here. Information gleaned from such studies impacts on neurotransmitter identification, neuronal development, patterns of receptor distribution, peptidergic transmission, transmitter metabolism, synaptogenesis and the regulation of synaptic development.

Different developmental schedules of dopaminergic and noradrenergic neurons in dissociation culture of fetal rat midbrain and hindbrain

The development of dopaminergic and noradrenergic neurons in dissociation cultures of mesencephalon and rhombencephalon obtained from 18-day-old rat fetuses was characterized by their capacity to take up and release catecholamines. In both types of cultures, uptake of [3H]dopamine and [3H]noradrenaline was obtained which could be inhibited by reserpine. Autoradiographic studies demonstrated an almost exclusive neuronal localization of the labeled catecholamines. The transmitters could be released by depolarization with K+ in a Ca2+-dependent manner during the entire cultivation period. In contrast, catecholamine uptake by cultures of neocortex was minimal, could not be inhibited by reserpine, and the accumulated radioactivity could not be released upon depolarization. These points provide evidence for an active accumulation of the exogenous transmitters and for the presence of stimulus-secretion coupling in a distinct population of neurons of both brain stem cultures. Striking differences between the two brain stem cultures concerned their sensitivity to desmethylimipramine and benztropine as well as the time course of the development of the uptake capacity. Desmethylimipramine inhibited the uptake of both catecholamines in rhombencephalic, but not in mesencephalic cultures. The reverse was true for benztropine. It is concluded that cultures of rhombencephalon contain predominantly noradrenergic, and those of mesencephalon dopaminergic cells. Comparison of the uptake behaviour suggested that noradrenergic neurons mature considerably later than dopaminergic neurons. The results show that dissociation cultures of mid- and hindbrain, inspite of their heterogeneous composition, can serve as valuable models for the study of development and function of dopaminergic and noradrenergic neurons, respectively.

Methods for the isolation of viable gonadotropin-releasing hormone (LRF) neurons

Studies were conducted in order to determine if selected neurons could be isolated from the brain using Sepharose-linked recognition complexes directed against or related to the biosynthetic/neurosecretory product of the desired neuronal population. Immunoreactive LRF neurons were precipitated when dispersed cells of adult male rats were incubated successively in media containing free LRF antiserum followed by the exposure of LRF bound to Sepharose-4B. The radioimmunoassayable LRF content of the isolated cells was 88% of that contained in fresh frozen tissue of a contemporary group of rats and trypan blue exclusion indicated that at least 85% of the neurons were viable. Furthermore, based on immunocytochemistry and cresyl violet staining in combination with immunocytochemistry, the isolated cell fraction appeared to be free from other types of cells and also exhibited assayable LRF release when challenged with potassium. These results suggest that the neuroendocrine properties of hypothalamic neurons may be exploited in order to isolate viable cells for acute in vitro experiments.

Primary explants as a model of the hypothalamus in situ

Anatomical and electrophysiological studies with neurotensin and somatostatin were performed to assess the integrity of primary explants of the preoptic anterior hypothalamus (POAH) maintained in organ culture as a model to study peptidergic neurons in vitro. POAH neurons maintained in vitro were found to be morphologically similar to those visualized histologically in situ. Somatostatin- and neurotensin-immunoreactive neurons were also present in both preparations. Additionally, electrophysiological responses of neurons in vitro to neurotensin and somatostatin were qualitatively similar to neuronal responses in situ. The striking morphological and pharmacological similarity between POAH neurons in vitro and in situ suggests that primary explants of the POAH are organotypic.

Long-term suspension culture of isolated hypothalamic nuclei of the rat: morphological differentiation and release of substances influencing corticotropin and growth hormone secretion

Individual hypothalamic nuclei were removed from 17-day-old rat embryos with 300 microns punches and maintained in suspension culture. Suspension culture of isolated nuclei appears to be suitable for studying morphological and functional differentiation of neural tissue and release of bioactivity influencing corticotropin and growth hormone release. During the 4 weeks in culture, neurons and glial cells differentiated well in each nucleus studied. The fine structure of the arcuate, periventricular, ventromedial and dorsomedial nuclei resembled that of the adult nuclei with many mature synapses; in contrast, in the neuropil of cultured preoptic, paraventricular and posterior hypothalamic nuclei mature synapses were very few or absent. The release of substances influencing corticotropin and growth hormone secretion by the cultured nuclei was tested in bioassays using anterior pituitary cell cultures and radioimmunoassay of hormones released into the medium. Corticotropin-releasing bioactivity was tested at weekly intervals. Cultured preoptic and paraventricular nuclei released corticotropin-releasing activity for up to 4 weeks whereas arcuate nuclei released corticotropin-releasing activity at 1 week only. The ventromedial and dorsomedial nuclei did not release corticotropin-releasing activity. The release of substances influencing growth hormone secretion was studied between 3 and 11 days in culture. After 3 days the medium of some hypothalamic nuclei stimulated growth hormone secretion, but after 7 and 11 days all cultured nuclei strongly inhibited it. The present findings demonstrate that hypothalamic nuclei can be cultured separately and suggest that neurons capable of releasing corticotropin-releasing activity(ies) are present in the preoptic and paraventricular nuclei of the rat whereas all hypothalamic nuclei studied contain intrinsic neurons capable of synthesizing and secreting somatostatin-like bioactivity.

Use of central neuronal cultures for the detection of neuronotrophic agents

Neuronotrophic factors, a class of macromolecules thought to be present within the neuronal environment are required to support the survival in vitro of peripheral neurons. In the present study we have established bioassay culture systems suitable for the identification of similar agents for intrinsic neurons of the central nervous system. The striatum, hippocampus and septum of 18 day fetal rats were dissociated and plated in a serum-free medium on a neurite conducive substratum which allows an easy recognition of neurons under phase contrast microscopy. These cultures contain predominantly neurons as assessed by tetanus toxin labelling, a well recognized neuronal marker. Seeding the cell suspensions at decreasing densities yields after 24 h a density dependent survival of the neuronal population. Thus a low seeding density could be chosen where survival of these neurons required an exogenous source of trophic factors. Survival of central neurons was promoted by several conditioned media derived from rodent glial cell cultures, both primary (astroglia, Schwann) and clonal (C6 glioma, Schwannoma). Serial dilutions of these media allowed the titration of their respective neuronotrophic activities. In addition, conditioned media derived from the central neuronal cultures themselves, when seeded at a high density, were also able to support the survival of low density seeded central neurons.

Cells in neonatal rat hypothalamus primary culture--an immunofluorescence study

Hypothalami from 1 day neonatal rats were dissociated and cultured for 4-16 days. Using immunofluorescence and antisera against neurofilament (NF) peptides, glial fibrillary acidic protein (GFAP), galactocerebroside and fibronectin we have distinguished neurons, astrocytes, oligodendrocytes and fibroblast-like cells in culture. Astrocytes initially grew as islets of 15-30 cells which dispersed as the culture aged. These cells, together with fibronectin-reactive flat cells, formed a monolayer upon which ovoid and process-bearing cells grew after 4 days in culture. Neurofilament-positive neurons constituted 5-10% of the total cell population. In maturing cultures the number of neurons decreased and fibroblasts increased. Oligodendrocytes represented less than 1% of total cell population. These studies emphasize the necessity of using the complementary techniques of morphology and immunocytochemistry for the characterization of hypothalamic neural cells in vitro.

Triiodothyronine enhances the morphological maturation of dopaminergic neurons from fetal mouse hypothalamus cultured in serum-free medium

In dissociated hypothalamic cell cultures of 16-day mouse embryos, growing in chemically defined medium, the catecholaminergic neurons were identified by autoradiography after labelling with [3H]dopamine and by immunocytochemistry with an anti-tyrosine hydroxylase antibody. Using selective inhibitors of amine transport and radioenzymatic determination of amine levels in these cultures, we show that these neurons were mostly dopaminergic. The number of dopaminergic neurons identified by the two techniques increased between days 5 and 8 and decreased after 15 days in vitro. The same number of neurons were identified by autoradiography and by immunocytochemistry and consisted of fusiform and multipolar neurons. The proportion of both types remained steady until 15 days in vitro. Under these conditions, the addition of triiodothyronine (10(-9) M) at the initiation of the culture increased the size but not the number of dopaminergic neurons after 8 days in vitro. Furthermore, triiodothyronine significantly increased the dopaminergic neurite length and arborization. This morphological effect of triiodothyronine was associated with an increase of 35% in [3H]dopamine uptake. Our study shows that hypothalamic dopaminergic neurons are responsive to triiodothyronine which acts as a maintenance or trophic factor having an effect on neurite extension and arborization.

Angiotensin II stimulates changes in the norepinephrine content of primary cultures of rat brain

Interactions between norepinephrine and angiotensin II were investigated in neuron-enriched primary brain cell cultures, which have been demonstrated to contain catecholamines, angiotensin II-like immunoreactivity and specific receptors for angiotensin II. Angiotensin II (7.5 and 15.0 micrograms/ml) caused significant increases in both neuronal and growth media norepinephrine levels, which were inhibited by saralasin. These observations suggest that angiotensin acts at its specific receptors to alter neuronal norepinephrine levels.

Rat brain cells in primary culture: visualization and measurement of catecholamines

Catecholamines have been visualized and quantified in primary cultures of whole rat brain. Twenty-one-day old cultures treated with glyoxylic acid and viewed under a fluorescence microscope revealed neurons stained specifically with blue-green catecholamine fluorescence. Brightly stained multipolar cell bodies were seen, along with stained neurites and varicosities, and there was no staining associated with the non-neuronal portion of the culture. Twenty-one-day-old non-neuron-enriched cultures contained 10-20 times less norepinephrine and dopamine than cytosine arabinoside-treated neuron-enriched cultures. The latter cultures contained 10-12 times more norepinephrine than 1-day-old rat brains, demonstrating maturation and differentiation of the cultured neurons. Norepinephrine levels of neuron-enriched cultures were, however, 3 times less than those in 21-day-old rat brains. The cultured neurons had the ability to synthesize catecholamines since levels were decreased with alpha-methyl-p-tryosine. On the other hand, the growth medium contained significant amounts of norepinephrine, but did not have the ability to synthesize catecholamines. It may be concluded that the cellular catecholamines are not derived from the medium in any great amounts. This study provides the basis of a system in which to examine catecholaminergic neurotransmission and peptide catecholamine interactions at the cellular level under semi-defined conditions.

Cultured neurones from the mature bovine mediobasal hypothalamus contain LHRH but not catecholamine

The in vitro culture of mature neurones from bovine mediobasal hypothalamus (MBH) is reported, providing a model for studies of mammalian neurosecretion at the cellular level. Explant tissue cultures of mature bovine MBH containing the arcuate nucleus were examined for LHRH, ACTH and catecholamines with a view to investigating the control of prolactin and gonadotropin secretion. LHRH immunoreactivity was found in both neuronal and non-neuronal cells in the outgrowth monolayer region of the explant. Neurones in this region appeared able to attach to a substrate and regenerate, in monolayer culture, well developed neurites characterized by beaded swellings as observed in vivo. Neither ACTH immunoreactivity nor catecholamine fluorescence was detected. Cultured neurones and astrocytes were labelled by tetanus toxin and anti-GFAP, respectively. Double labelling of cultures with tetanus toxin and anti-LHRH demonstrated the neuronal nature of many LHRH-immunoreactive cells. Radio-immunoassay data confirmed the presence of LHRH in the cultures but application of 60 mM KC1 failed to evoke hormone release. These studies have confirmed the view of previous workers that hypothalamic control of prolactin secretion in the bovine may be very different from that thought to occur in non-ruminants such as the rat and guinea pig. Finally, this work demonstrates that a cultured system from the mature bovine may prove a good model for study of neuronal regulation of gonadotropin secretion by the bovine mediobasal hypothalamus.

Hypothalamic neurons in dissociated cell culture: the mechanism of increased survival times in the presence of non-neuronal cells

Rat hypothalamic neurons were cultured in the presence of fluorodeoxyuridine to inhibit nonneuronal cell proliferation. Under these conditions, neuronal cell survival was dependent on contact with homologous nonneuronal cells. This phenomenon did not seem to be due to the release of diffusable trophic factors, since neither growth on polylysine in the close proximity of nonneuronal cells nor the use of preconditioned medium significantly increased neuronal survival. However, metabolically active cell layers were required, since growth on heat-killed or fixed homologous nonneuronal cells did not increase neuronal survival. The increased survival of neurons seen here in the presence of homologous nonneuronal cells therefore appears to be due to metabolic co-operation mediated by specific, direct cell-cell contact.

Opiate peptides modulate somatostatin release from dispersed hypothalamic cells

An in vitro dispersed hypothalamic cell system was developed and utilized to investigate the effect of exposure to cold stress prior to sacrifice on release of somatostatin-like immunoreactivity (SRIF-LI). Exposure of the rats to cold stress prior to sacrifice significantly increased basal (or control) release of SRIF-LI from dispersed hypothalamic cells. The endogenous opiate peptides (beta-endorphin, Met-enkephalin and Leu-enkephalin)significantly inhibited the basal release of SRIF-LI from dispersed hypothalamic cells obtained from rats exposed to the cold prior to sacrifice. Naloxone, a specific opiate antagonist, had no effect on basal release but blocked inhibition by the endogenous opiate peptides. In marked contrast, the endogenous opiate peptides had no effect on basal release of SRIF-LI from dispersed hypothalamic cells of rats exposed to room temperature prior to sacrifice.

[3H]GABA uptake as a marker for cell type in primary cultures of cerebellum and olfactory bulb

Uptake of [3H]GABA into cell cultures of rat cerebellum and olfactory bulb was studied by autoradiography, using beta-alanine and aminocyclohexane carboxylic acid to distinguish neuronal-specific and glial-specific uptake. Neurons and astrocytes were also labeled by tetanus toxin and anti-GFAP respectively. This combination of markers allowed identification and quantification of several cell types. Cerebellar cultures were found to contain 77% granule neurons, 7.5% inhibitory neurons (probably stellate and basket cells) and 15% astrocytes. Olfactory bulb cultures were over 50% in small neurons which accumulated GABA, the olfactory bulb granule neuron being GABAergic in vivo.

Primary cultures of dispersed hypothalamic cells from fetal rats: morphology, electrical activity, and peptide content

Cultures prepared from dispersed fetal hypothalamic tissue have cells which can be identified as neurons by their morphology and electrical activity. The elongation of neuritic processes in these cultures is increased by treatment with 1-beta-D arabinofuranosylcytosine (ara-C). Hypothalamic cultures have measurable quantities of immunoreactive substance P and neurotensin, and the neurons can accumulate (3H)GABA.

Immunological evidence for thyroliberin (TRH) neurons in primary cultures of fetal mouse brain cells. Ontogenic aspects

Primary cultures of dissociated cells were initiated from fetal mouse hypothalami and brain hemispheres, on the 13th and the 16th day of gestation (respectively 12-day and 15-day-old fetuses). After 10 days in vitro, the cultured cells were collected, pooled in an appropriate medium and thyroliberin (TRH) was assayed in the cell extracts using a specific radioimmunoassay. TRH was found in every type of culture. For hypothalami, higher levels of TRH were found when when starting from older embryos, while in brain hemisphere cultures the TRH content increased in culture of 12-day-old fetal cells only, whereas it decreased in cultures of 16-day-old fetal cells. Immunocytochemical staining allows visualization of TRH positive cells in all cultures except in hypothalamic cultures from 12-day-old embryos. This is consistent with the radioimmunoassay data. TRH was localized exclusively in some of the overlying cells, whereas the basal cells were always negative. Specificity of the staining was assessed by immunochemistry and radioimmunoassay. At the electron microscope level, the positive cells display neuronal features. The immunoprecipitate was found in both perikaryon and axons as well as in axonal dilatations.

Uptake and metabolism of female sex steroids by isolated small neurons and other cell fractions from the rat medial basal hypothalamus

Rat medial basal hypothalami (MBH) and sections of cerebral cortex (CC) were dissociated with trypsin to prepare single cells and subcellular fractions. They were then separated into four fractions on a discontinuous sucrose gradient. The small neurons in Fraction D were highly purified. Fraction A had synaptosomes, myelin and other cell particulates. Fraction B had glial cells, neurons and a few synaptosomes. Fraction C had large neurons and red blood cells. All four fractions contained LHRH, but most (62.5%) of this hormone was present in Fraction A. Dissociated cell suspensions were incubated with [3H]-steroids, with and without a 100-fold excess of unlabeled steroids, then separated on sucrose gradients. In most fractions the total uptake and specific uptake of [3H]-progesterone, [3H]-5 alpha-pregnane-3,20-dione (5 alpha-dihydroprogesterone) and [3H]-17 beta-estradiol were greater for the dissociated cells from the MBH than the CC. The dissociated cells and cell particulates in all four fractions from the MBH and CC metabolized progesterone, 5 alpha-dihydroprogesterone and 17 beta-estradiol. These results indicate that hypothalamic neurons contain small amounts of LHRH and retain the ability to take up and metabolize progesterone, 5 alpha-dihydroprogesterone and 17 beta-estradiol.