Magnocellular neuroendocrine neurons: update on intrinsic properties, synaptic inputs and neurophamacology

Activation of an inwardly rectifying K+ conductance by orphanin-FQ/nociceptin in vasopressin-containing neurons

The orphanin-FQ/nociceptin (OFQ/N) receptor (previously, ORL1, LC132) has been shown to be coupled to an inwardly rectifying K+ conductance in several neuronal populations. Although OFQ/N receptor mRNA is densely expressed in the supraoptic nucleus (SON), little is known about its coupling to effector system(s). The present study examined the effects of OFQ/N on guinea pig magnocellular neurons within the SON using intracellular recording from hypothalamic slices. In the presence of tetrodotoxin, OFQ/N hyperpolarized 48 of 48 SON magnocellular neurons, 24 of which were subsequently identified by immunocytochemistry as arginine vasopressin positive (AVP+). Nineteen of the 48 SON neurons, including 7 which were AVP+, responded to OFQ/N with an outward current that reversed at the K+ equilibrium potential (EK+) and a decrease in slope resistance consistent with the activation of an inwardly rectifying K+ channel. In 4 of these neurons, BaCl2 significantly attenuated both the hyperpolarization and the decrease in slope resistance induced by OFQ/N. Twenty-one SON neurons, 13 of which were AVP+, responded to OFQ/N with an increase in slope resistance which did not reverse at EK+. An additional 5 neurons (2 were AVP+) were treated with the gap junction blocking agent carbenoxolone (CARB). CARB induced a small hyperpolarization, increased slope resistance and significantly reduced the subsequent OFQ/N-induced hyperpolarization. However, when the CARB and CARB plus OFQ/N hyperpolarizations were summed in these 5 cells, they were no different than the OFQ/N hyperpolarization alone. The effect of two putative OFQ/N receptor antagonists was also evaluated. The kappa3-opioid antagonist naloxone benzoylhydrazone was without effect (n = 3), and the 13-amino-acid [Phe1Psi(CH2-NH)Gly2]OFQ/N(1-13)NH2 OFQ/N analog produced a small hyperpolarization on its own in addition to partially antagonizing the effects of OFQ/N (n = 3). Taken together, these results suggest that OFQ/N acts upon SON neurons through two mechanisms, one which hyperpolarizes the neuron by activating an inwardly rectifying K+ conductance, and another which may increase membrane resistance by closing the low-resistance gap junctions.

Physiological pathways regulating the activity of magnocellular neurosecretory cells

Magnocellular oxytocin and vasopressin cells are among the most extensively studied neurons in the brain; their large size and high synthetic capacity, their discrete, homogeneous distribution and the anatomical separation of their terminals from their cell bodies, and the ability to determine their neuronal output readily by measurements of hormone concentration in the plasma, combine to make these systems amenable to a wide range of fundamental investigations. While vasopressin cells have intrinsic burst-generating properties, oxytocin cells are organized within local pattern-generating networks. In this review we consider the rôle played by particular afferent pathways in the regulation of the activity of oxytocin and vasopressin cells. For both cell types, the effects of changes in the activity of synaptic input can be complex.

Microinjections of angiotensin II into the supraoptic and paraventricular nuclei produce potent antidiureses by vasopressin release mediated through adrenergic and angiotensin receptors

We investigated the effects of angiotensin II (Ang II), microinjected into the supraoptic (SON) and paraventricular (PVN) nuclei of rats, on the urine outflow rate and underlying mechanisms. Ang II produced antidiuretic effects in a dose-dependent manner with ED50 values of 0.1 and 0.05 nmol in the SON and PVN, respectively. [Sar1, Ile8]Ang II at 0.1 nmol diminished the Ang II (0.5 nmol)-induced antidiureses in the SON more markedly than in the PVN. A high dose of [Sar1,Ile8]Ang II, 1 nmol, completely inhibited the effects in both the nuclei. In addition, the Ang II (1 nmol)-induced antidiuretic effects were partially inhibited by phenoxybenzamine (80 nmol) in the SON and by phenoxybenzamine, timolol (100 nmol) and propranolol (100 nmol) in the PVN. The microinjection of Ang II (1 nmol) into both the nuclei, after pretreatment with a vasopressin V1V2-antagonist, d(CH2)5-D-Tyr(Et)VAVP (i.v.) significantly increased the urine outflow rate. These findings suggest that 1) Two mechanisms account for the Ang II receptor-mediated antidiureses resulting from an increase in vasopressin release: direct stimulation on vasopressin-containing neurons and indirect stimulation on them through alpha-adrenoceptors in the SON and alpha- and beta-adrenoceptors in the PVN; 2) The Ang II-induced antidiuretic effect in the SON is slightly less potent than that in the PVN; and 3) Ang II receptors in the nuclei may possibly produce the diureses through mechanisms that are not presently understood.

Parabrachial nucleus projection towards the hypothalamic supraoptic nucleus: electrophysiological and anatomical observations in the rat

It has been proposed that the pontine parabrachial nucleus (PBN) participates in the regulation of body fluid balance and the release of vasopressin from the neurohypophysis, although the pathways mediating the latter response are uncertain. This study in the rat, utilizing anatomical and electrophysiological methods, describes a projection from the lateral PBN towards the hypothalamic supraoptic nucleus (SON). Rats received iontophoretic injections of the anterograde tracer Phaseolus vulgaris leucoagglutinin (PHA-L, 2% solution). After 14-17 days, rats were sacrificed and their brains prepared for immunofluorescent visualization of projections to the SON region. PHA-L-labelled terminals were found primarily in perinuclear regions immediately dorsal to the SON. In contrast, injections within the medial PBN and the nearby Kölliker-Fuse nucleus did not reveal labelling in or around the SON. Extracellular recordings from 86 of 118 antidromically identified neurons in anaesthetized rats revealed a set of complex synaptic responses after stimulation in the PBN. Excitatory responses (in 82 of 86 cells) of short (less than 100 msec, 39/82 cells) and long (greater than 100 msec, 43/82) duration were observed in both vasopressin- and oxytocin-secreting cells of the SON, while 4/86 cells displayed a depressant response to PBN stimulation. In the adjacent perinuclear zone, 22/39 nonneurosecretory cells responded with an increase in their excitability consequent to an identical stimulus. These data suggest a predominantly facilitatory influence of lateral PBN neurons on SON neurosecretory cells in the rat, and that the PBN-SON projection is an indirect one that utilizes an interneuronal network located in the perinuclear zone adjacent to the SON.

Membrane properties of rat magnocellular neuroendocrine cells in vivo

Membrane properties of rat magnocellular neuroendocrine cells (MNCs) were examined during intracellular recordings in vivo. Current-clamp experiments revealed sustained outward rectification positive to -55 mV and transient outward rectification of depolarizing responses elicited from negative holding potentials. Trains of impulses were associated with a progressive increase of spike duration. Such features, which were not observed in neighboring non-neuroendocrine cells, are similar to those of MNCs in slices or explants of rat hypothalamus. In contrast, however, cells recorded in vivo were characterized by intense synaptic inhibition and a lower specific impedance than commonly observed from MNCs impaled in vitro.

The hypothalamic paraventricular nucleus is a site of action for the central effect of tachykinins on plasma vasopressin

The intracerebroventricular injection of eledoisin (ELE), or of other tachykinins with potent agonist activity at neurokinin B (NK-3) receptors, increases plasma vasopressin in the rat. The effect is antagonized by saralasin pretreatment, thus suggesting that it is mediated by angiotensin receptor activation. Since the magnocellular part of the hypothalamic paraventricular nucleus (PVN) is very rich in NK-3 receptors, the present study was aimed at investigating the role of this nucleus in the effect of ELE on plasma vasopressin. Direct injection of ELE into the PVN increased plasma vasopressin levels more potently than the injection of the same doses into the lateral ventricle. Lesioning of the magnocellular part of the PVN completely abolished the increase in plasma vasopressin induced by the injection of ELE 100 ng/rat into the lateral ventricle. Pretreatment into the PVN either with saralasin or with captopril resulted in a marked suppression of the effect of ELE on plasma vasopressin. These findings indicate the PVN as a site of action for the central effect of tachykinins on plasma vasopressin and suggest that the angiotensin mediation of the effect might take place in the same nucleus.

The response of nucleus preopticus neurosecretory cells to ovarian pressure in the frog, Rana tigrina

Intraovarian pressure (IOP) of 5, 15, and 25 mm Hg was administered in the frog, Rana tigrina, and the response of the nucleus preopticus (NPO) pars magnocellularis was investigated with aldehyde fuchsin (AF) stain and immunocytochemical method using neurophysin (NP) antisera. The 5 mm Hg IOP treatment resulted in cell and cell nuclear hypertrophy (P less than 0.001); discrete signs of de novo synthesis of AF-positive and NP-immunoreactive material in the perikarya and remarkable increases in the number and size of "Herring bodies" in the processes were observed. Stimulatory response after 15 mm Hg IOP treatment was characterized by dramatic augmentation of the AF-positive and NP-immunoreactive material in the processes; the engorged and coalescing Herring bodies totally predominated the lateral preoptic area. IOP of 25 mm Hg resulted in extensive loss of secretory material; the processes revealed the presence of vacuoles indicative of the rapid anterograde transport of the neurosecretory material. Furthermore, the application of IOP seemed to promote the transport of NP-immunoreactive material toward the anterior preoptic area and amygdala pars medialis and the release of secretory material into the cerebrospinal fluid. No changes were observed in the NPO when treatment was preceded by the transection of ipsilateral dorsal spinal nerve roots or the spinal cord. The results suggest the existence of an afferent neural pathway from the ovary capable of conducting the stretch signals to the NPO and triggering the synthesis and release of neurohypophysial hormones.

Vasopressin gene expression is stimulated by cyclic AMP in homologous and heterologous expression systems

The possible role of cyclic AMP (cAMP) in the regulation of the vasopressin (VP) gene was tested in two cellular expression systems: one cell line with endogenous VP expression and the other which was transiently with a VP promoter-luciferase fusion gene. 8,Bromo-cAMP stimulated the VP mRNA content about 4-fold in the human VP-expressing small cell lung carcinoma cell line GLC-8. The luciferase activity in P19 embryonal carcinoma cells which were transiently transfected with -174 to +44 of the 5'-flanking region of the human VP gene linked to the firefly luciferase gene, was stimulated about 2-fold by the cAMP analogue. The results indicate that cAMP plays a role in the upregulation of the VP gene and hence point to several putative nucleotide motives in the promoter functionally conferring this response.

Atrial natriuretic peptide-induced suppression of basal and dehydration-induced vasopressin secretion is not mediated by hypothalamic tuberohypophysial or tuberoinfundibular dopaminergic neurons

The purpose of this study was to examine the effects of atrial natriuretic peptide (ANP) on the secretion of vasopressin and the activities of hypothalamic tuberohypophysial and tuberoinfundibular dopaminergic neurons in normal and dehydrated male rats. Neuronal activity was estimated by measuring the concentrations of 3,4-dihydroxyphenylacetic acid (DOPAC) and dopamine (DA) in brain and posterior pituitary regions containing terminals of tuberohypophysial (neural lobe; intermediate lobe) and tuberoinfundibular (median eminence) DA neurons. Intracerebroventricular (icv) administration of 20 micrograms ANP decreased basal arginine vasopressin concentrations in the plasma, but had no effect on the concentrations of DOPAC or DA in any region examined. Water deprivation caused a time-dependent increase in plasma arginine vasopressin concentrations, with maximal levels measured 2 days after removal of water bottles. Water deprivation had no effect on DOPAC concentrations in the neural lobe, intermediate lobe or median eminence, but increased DA concentrations in the neural lobe. ANP (20 micrograms/rat; icv) decreased arginine vasopressin concentrations in the plasma of water-deprived rats without altering DOPAC or DA concentrations in the neural lobe, intermediate lobe or median eminence. These results indicate that ANP-induced suppression of basal and dehydration-induced vasopressin secretion is not mediated by tuberohypophysial or tuberoinfundibular DA neurons.

Inward Rectification (I) in Immunocytochemically-ldentified Vasopressin and Oxytocin Neurons of Guinea-Pig Supraoptic Nucleus

Intracellular recordings of magnocellular neurons from the supraoptic nucleus of guinea-pigs were made with KCI/K citrate- and biocytin-filled electrodes. Fifty of 99 cells exhibited a time-dependent inward rectification (TDR). The TDR was activated during hyperpolarizing current pulses to membrane potentials more hyperpolarized than -75 mV. In voltage-clamp recordings, an inward current appeared at voltage steps more hyperpolarized than -75 mV, with properties similar to the slow inward rectifier (I(h)) described in other tissues. The I(h) was blocked by 2 mM CsCI. BaCI(2) (100 to 500 muM) did not block the I(h). Immunocytochemical identification of the recorded cells revealed that both vasopressin (AVP)- and oxytocin (OT)- containing neurons exhibited an I(h).

Direct effects of an opioid peptide selective for mu-receptors: intracellular recordings in the paraventricular and supraoptic nuclei of the guinea-pig

Responses to [D-Ala2, MePhe4, Gly-ol5]enkephalin, a selective agonist for mu-receptors, were recorded intracellularly from 26 neurons in slices of guinea-pig hypothalamus. Of eight cells tested in the supraoptic nucleus, all of which had electrical properties characteristic of magnocellular neuroendocrine cells, four were sensitive to the agonist applied in the perfusion bath or with microdrops. The main effect was a decrease or suppression of spontaneous firing. In the paraventricular nucleus, seven of 18 cells tested also had electrophysiological characteristics similar to magnocellular neurons: two of them were sensitive to the mu-agonist and the effect was similar to that observed in the supraoptic nucleus. The remaining paraventricular neurons displayed low-threshold Ca2+ spikes, and thus had electrophysiological characteristics different from putative magnocellular neurons. Ten of 11 cells with low-threshold Ca2+ spikes were hyperpolarized by more than 10 mV by the mu-agonist, and showed a 33 +/- 1.9% (S.E.M.) decrease in input resistance. In both types of cells, when synaptic transmission was blocked with tetrodotoxin, the mu-agonist could still induce a hyperpolarization, suggesting that the effect was in part direct. Hyperpolarization was also obtained when the Cl- reversal potential was shifted to more positive values by using KCl electrodes, thus excluding a Cl- conductance mechanism. These results provide evidence that opioid peptides can directly inhibit hypothalamic neurons, that the mechanism is an increase in K+ conductance, and that two types of hypothalamic neurons appear to have different sensitivities to a mu-agonist.

Discharge induction in molluscan peptidergic cells requires a specific set of autoexcitatory neuropeptides

The peptidergic caudodorsal cells of the pond snail Lymnaea stagnalis generate long lasting discharges of synchronous spiking activity to release their products. During caudodorsal cell discharges a peptide factor is released which induces similar discharges in silent caudodorsal cells [Ter Maat A. et al. (1988) Brain Res. 438, 77-82]. To identify this factor, the electrophysiological effects of putative caudodorsal cell gene products, calfluxin, caudodorsal cell hormone, four alpha caudodorsal cell peptides and three beta caudodorsal cell peptides, were tested individually and in various combinations. Calfluxin, alpha caudodorsal cell peptide and beta 1 caudodorsal cell peptide each had no effect on membrane potential or excitability of the caudodorsal cells. All other caudodorsal cell peptides caused excitatory responses, but did not induce discharges. Instead, only a specific combination of four caudodorsal cell peptides, caudodorsal cell hormone and alpha caudodorsal cell peptide (1-11, 3-11 and 3-10), evoked caudodorsal cell discharges with similar characteristics to electrically evoked discharges. Incomplete versions of this combination failed to cause a discharge. In addition, antibodies to caudodorsal cell hormone or alpha caudodorsal cell peptide reduced caudodorsal cell excitability and prevented the generation of discharges by electrical stimulation. These results suggest that excitatory autotransmission caused by four caudodorsal cell peptides provides a means to amplify excitatory inputs, thus leading to the generation of the all-or-nothing caudodorsal cell discharge.

Release of atrial natriuretic factor from intact and hypophysectomized rat hypothalamic expiants

Abstract Experiments examined release of atrial natriuretic factor (ANF), measured by radioimmunoassay, from acutely prepared explants of rat hypothalamus maintained in vitro by intra-arterial perfusion of artificial cerebrospinal fluid. Perfusates collected from intact preparations contained 6.1 +/- 0.6 pg (mean +/- SEM) of ANF per 2-min sample. Following a 3-min infusion of noradrenaline (60 muM), ANF release increased significantly (P<0.05) to 11.4+/-1.4 pg/sample. Media collected from hypophysectomized preparations showed the same basal ANF release (6.8 +/- 0.9 pg/sample) as intact preparations, but demonstrated no significant increase after noradrenaline infusions. Levels of spontaneous ANF release were not appreciably affected by the absence of the paraventricular nuclei and/or the anteroventral third ventricle area. Extracted material from the perfusate by reverse-phase high performance liquid chromatography revealed two main peaks of immunoreactive ANF: a small molecular weight form that coeluted with synthetic ANF (99-126) and with similar biological activity in a radioreceptor assay, and a larger molecular weight form with the same elution profile as the ANF (1-126) prohormone. These observations indicate that the ANF released from perfused rat hypothalamic explants contains distinct contributions from the hypothalamus (sites undetermined) and the neurointermediate lobe.

Diagonal band projection towards the hypothalamic supraoptic nucleus: light and electron microscopic observations in the rat

Supraoptic nucleus (SON) neurons receive a prominent gamma-amino-butyric acid (GABA) input. This study evaluated the hypothesis, partly on the basis of recent electrophysiological data, that this innervation might arise from GABAergic neurons located in the ventral diagonal band of Broca area. For retrograde transport studies, pentobarbital-anesthetized male Long-Evans rats received 0.03-0.20-microliter injections of a suspension of rhodamine tagged latex microspheres into the SON. In two cases where such injections were confined to the SON, less than 60 retrogradely labeled neurons were detected in the ipsilateral diagonal band. In three animals where injections extended into the perinuclear zone around the SON, more than 2,000 retrogradely labeled cells were counted in the ipsilateral diagonal band. For anterograde transport studies, another group of animals received either 30% horseradish peroxidase (HRP) in 0.5% poly-L-ornithine (0.05-0.10 microliter injections) or Phaseolus vulgarus (iontophoresed from a 2% solution) into the diagonal band. After survivals of 18-24 hours (HRP) or 5 days (PHAL-L) labeled axon terminals invested the perinuclear zone above the SON. The presence of just a single fiber within the nucleus indicated a minor projection to the SON itself. The HRP-injected material was processed for ultrastructural examination and revealed dense HRP-labeled axon terminals in this perinuclear zone, most often (98%) forming axodendritic appositions. A postembedding colloidal gold technique to visualize GABA-synthesizing terminals revealed that fewer than 5% of these perinuclear HRP-labeled terminals also exhibited GABA-like immunoreactivity. Within the SON, where GABAergic axon terminals are abundant, few (less than 5%) GABAergic terminals contained HRP.(ABSTRACT TRUNCATED AT 250 WORDS)

Vasopressin release induced by intracranial injection of eledoisin is mediated by central angiotensin II

Pulse intracerebroventricular injection of eledoisin, but not of substance P, markedly increases plasma vasopressin levels in the rat. Intracerebroventricular pretreatment with sarcosine1, alanine8-angiotensin II, 1 microgram/rat, completely suppresses the effect of eledoisin, suggesting that it is mediated by angiotensin release and angiotensin II receptor activation. The vasopressin releasing effect of eledoisin is neither due to peripheral haemodynamic alterations, nor to activation of the peripheral renin-angiotensin system. It is apparently related to central angiotensin release in a specific neuronal pathway subserving vasopressin release. This effect is not secondary to inhibition by tachykinins of the brain mechanisms for angiotensin-induced drinking, but is probably expression of direct activation of specific tachykinin receptors controlling vasopressin release.

Cardiovascular input to hypothalamic neurosecretory neurons

In vivo extracellular recordings from rat supraoptic and paraventricular magnocellular neurosecretory cells (MNCs) indicate that putative vasopressin-secreting MNCs may be identified by an abrupt and brief cessation in firing consequent to a transient drug-induced rise in arterial pressure sufficient to activate arterial baroreceptors. In the diagonal band of Broca (DBB), a population of neurons projecting towards the supraoptic nucleus are activated during this drug-induced hypertension. Electrical stimulation in DBB selectively depresses supraoptic vasopressin-secreting MNCs. Intracellular recordings in perfused hypothalamic explants confirm a DBB-evoked bicuculline-sensitive and chloride-dependent postsynaptic inhibition, similar to that associated with the application of gamma-aminobutyric acid (GABA) in approximately half of supraoptic MNCs. Since bicuculline also selectively blocks baroreceptor-induced inhibition in supraoptic MNCs, it is proposed that the depressant baroreflex input to vasopressin-secreting MNCs involves a population of DBB neurons and GABAergic interneurons located close to MNCs. An excitatory and selective input to vasopressin-secreting MNCs follows chemoreceptor activation, possibly mediated by the A1 noradrenergic cell group in the ventrolateral medulla. Another excitatory input to both vasopressin- and oxytocin-secreting MNCs is triggered by circulating angiotensin II and appears to be relayed centrally through an angiotensinergic projection from the subfornical organ.