Regulation of phosphorylation of proteins I, IIIa, and IIIb in rat neurohypophysis in vitro by electrical stimulation and by neuroactive agents

The state of phosphorylation of proteins I, IIIa, and IIIb--neuron-specific phosphoproteins--was studied in neurosecretory endings of the neurohypophysis in vitro. Brief periods (a few seconds) of electrical stimulation caused large increases in the state of phosphorylation of all three proteins. The three proteins were dephosphorylated within 1 min after termination of the stimulation. High potassium, 8-bromo-cAMP, and dopamine also stimulated the phosphorylation of the three proteins. The effect of dopamine was blocked by the dopamine antagonist fluphenazine. Peptide mapping of protein I revealed that electrical stimulation or high potassium increased the state of phosphorylation of two regions of the molecule, whereas 8-bromo-cAMP and dopamine increased the state of phosphorylation of only one of these regions.

Termination of drinking: satiation

Speeds of swallowing water differ among species, for example, in the dog and rat. Alimentary factors predominate in the termination of drinking. Parenteral water avoids alimentary factors, yet can also lead to delayed satiation. Central factors of termination are also recognized, especially in the neurohypophysis. Kinetics of various intakes (food, sodium, oxygen, heat) show analogous patterns of satiation or saturation. Such intakes have in common the dimensions of clearances of deficits.

The influence of selective adeno- and neurointermedio-hypophysectomy upon plasma and brain levels of beta-endorphin and their response to stress in rats

Selective ablation of the anterior lobe (AL) of the pituitary led to a fall in basal plasma levels of beta-endorphin immunoreactivity (beta-EI) at 3 and 20 weeks post-surgery (p.s.). Further, the stress-evoked rise in circulating levels of beta-EI was abolished. This operation did, however, severely deplete the beta-EI content of the neurointermediate lobe (NIL). Removal of the NIL did not, in contrast, decrease the beta-EI content of the AL but depressed basal plasma levels of beta-EI at 3 weeks p.s. and attenuated, but did not abolish, the increase in these elicited by stress at both 3 and 20 weeks p.s. In rats not possessing a NIL, a secretion of beta-EI into plasma can thus occur. The possibility that NIL pools of beta-EI contribute to circulating levels of beta-EI is discussed. Removal of the AL depressed the beta-EI content of the hypothalamus and periventricular tissue at 3 and 20 weeks p.s. The Met-enkephalin-immunoreactivity (ME-I) content of the hypothalamus was, in contrast, unaffected. These animals still responded to stress at 20 weeks p.s. with a significant fall in hypothalamic levels of beta-EI. Extirpation of the NIL did not, in contrast, change brain levels of either beta-EI or ME-I. The presence of the AL, but not the NIL, is thus essential for the maintenance of usual levels of beta-EI and ME-I in the brain.

Posterior pituitary lobectomy: differential elevation of plasma prolactin and luteinizing hormone in estrous and lactating rats

The effects of posterior pituitary lobectomy on PRL and LH secretion in estrous and lactating rats were examined. Blood was collected from a femoral artery immediately before and at various times after the removal of the posterior lobe from anesthetized rats. Rats in estrus were also subjected to chronic posterior lobectomy, and their water consumption and vaginal cytology were determined for 3 weeks. Within 5--10 min after posterior lobectomy in estrous rats, plasma PRL increased 3-fold, but declined to near control levels by 1--2 h. Plasma LH increased more gradually, reaching 4 times the control level after 2--3 h. No change was observed in plasma GH. Injection of dopamine to posterior lobectomized estrous rats caused an immediate fall in plasma PRL, but no change in LH. Plasma PRL in lactating rats increased 4-fold after posterior lobectomy, reaching a peak concentration by 30 min and remaining elevated for at least 3 h; plasma LH was unchanged. Eighty percent of chronic posterior lobectomized rats became pseudopregnant and then resumed normal cyclicity. Water consumption increased 3-fold after posterior lobectomy, but declined to 60--70% above the control level after 2--3 weeks. The data suggest that the posterior lobe participates in the regulation of PRL secretion via a dopaminergic mechanism; such regulation might be more pronounced during lactation than in estrus. In addition, the posterior pituitary appears to contribute to the regulation of LH secretion during estrus. The factor(s) of posterior pituitary origin responsible for inhibiting LH secretion is unknown at the present time.

Influence of histamine and pentobarbitone on plasma and CSF vasopressin levels of hypophysectomized rats

Histamine increased vasopressin levels, as measured by radioimmunoassay (RIA), in both cerebrospinal fluid (CSF) and plasma of hypophysectomized rats, while histamine enhanced plasma but not CSF levels of vasopressin in sham operated rats. Pentobarbitone increased CSF vasopressin levels in hypophysectomized rats and in sham operated animals. The present data demonstrate that the histamine induced elevation of vasopressin levels in the blood is only temporarily disturbed after hypophysectomy, while the effect of histamine on CSF vasopressin levels of hypophysectomized rats is of a more permanent nature.

The milk ejection reflex in the pig

1. The milk ejection reflex in response to suckling was studied in conscious sows by continuous recording of intramammary pressure, radioimmunoassay of plasma concentrations of neurohypophysial hormones, and observation of the behaviour of the sows and piglets.2. A regular pattern of nursing, suckling and milk ejection was observed. The mean duration of the suckling period was 6.3 min. Over 144 suckling periods, 113 milk ejections were recorded. Each milk ejection was characterized by a sudden rise in intramammary pressure reaching 20-49 mmHg, and lasting 8-41 sec. Milk ejections occurred only once per suckling period, at a mean interval of 44.3 min.3. Each milk ejection occurred with a mean latency of 2.4 min from the onset of a period of initial massage of the udders by the piglets, and was coincident with a period of quiet suckling when the piglets were consuming milk. The onset of nursing was signalled by the sows grunting in a rhythmic manner. In most cases, the frequency of grunts, at first low, increased suddenly 23 sec before milk ejection.4. During eighteen suckling periods leading to milk ejection, neurohypophysial hormone assays performed on serial blood samples showed an increase in plasma concentration of oxytocin up to 30 sec before milk ejection. The concentration of lysine-vasopressin did not rise above basal levels.5. In 21.4% of the suckling periods, no rise in intramammary pressure was observed. In these ;incomplete sucklings', the sow usually failed to grunt rapidly, and the piglets obtained no milk. For three of these periods, hormone assay showed no increase in oxytocin or vasopressin concentrations in blood.6. Oxytocin given intravenously produced variations in intramammary pressure which depended on the dose and the rate of injection. Rapid injections of 25-50 m-u. oxytocin, caused milk ejections similar to those induced by suckling. When oxytocin was administered at different rates, the faster the injection, the shorter the latency and the higher the amplitude of the response. Plasma concentrations of oxytocin after injection of 25 m-u. were similar to those observed during reflex milk ejection.7. Trains of electrical pulses were applied to the posterior pituitary of four anaesthetized sows. At frequencies of stimulation above 10 Hz, a rise in intramammary pressure and an increase in plasma oxytocin and vasopressin concentrations were observed. At frequencies of stimulation of 30-50 Hz, the response of the mammary gland and the time course of the variations in oxytocin plasma concentrations were similar to those observed during natural reflex milk ejection.8. It is concluded that reflex milk ejections during suckling in the pig are caused by the intermittent and spurt-like release of about 25 m-u. oxytocin, without concomitant vasopressin release. It is postulated that the release of oxytocin is probably precipitated by a brief and massive activation of oxytocin-secreting neurones in the hypothalamus. Central mechanisms controlling the intermittent release of oxytocin are discussed.

Internal pH of isolated newly formed and aged neurohypophysial granules

The pH gradient (delta pH) across the membrane of bovine neurohypophysial granules was estimated by using the [14C]methylamine partition technique. The granule membrane showed high permeability to sugars such as sucrose or sorbitol and to cations. Granules suspended in sucrose medium showed an acidic internal delta pH that decreased with external pH from 1.0 pH unit at pH 7.5 to 0 at pH 4.5. High ionic strength of the external medium destroyed the delta pH, indicating that it originated from a Donnan equilibrium. In a medium constituted to simulate cytoplasm, the delta pH was approximately 0.5 pH unit. Aged neurosecretory granules were more acidic inside than were newly formed granules. The results are discussed in relationship to the nature and the duration of maturation and degradation process of the granule matrix.

Calcium-sensitive cells of the pars intermedia and osmotic balance in the eel. I. Responses to changes in the environmental calcium and magnesium

The structure of the PAS-positive calcium-sensitive (Ca-s) cells of the pars intermedia was investigated in eels kept in deionized water (DW) or fresh water (FW) supplemented with Ca2+ of Mg2+ x Ca2+ (2mM) reduces considerably the response to DW; plasma osmolarity, Na+ and Ca2+ levels are not significantly affected. In eels adapted to DW for 21 or 28 days, showing highly stimulated Ca-s cells, an addition of CaCl2 for 2 days inhibits the release of granules, but does not immediately block their synthesis and the mitotic activity. The nuclear area is reduced, osmolarity and plasma sodium increase, but the rise in calcium is not always significant. Magnesium, at a 10-fold greater concentration than in FW (2mM), slightly inhibits the release of secretory granules without reducing other indicators of stimulation. In Ca-enriched FW, the Ca-s cells appear inactive. These data show that the PAS-positive cells in the pars intermedia of the eel are calcium-sensitive, similar to those of the goldfish; their role in calcium regulation is briefly discussed.

[Interrelationships between pars intermedia and posterior pituitary with regard to corticotrophic and thyrotrophic partial function in rats]

Functional interrelationships between the pars intermedia and posterior pituitary were proved under different experimental conditions. After stimulation of the thyrotropical axis of rats by an acute intraperitoneal application of 50 microgram TRH/rat the nuclear sizes of the thyroid follicular and the anterior pituitary thyrotropical cells increased according to a monophasic time curve with maximal amplitude at the time of 30 minutes. Interestingly, the nuclear sizes of the posterior pituitary cells were also enhanced. Under the same experimental conditions the nuclear areas of the cells of the external layer of the adrenal zona fasciculata decreased as did the nuclei of the pars intermedia cells (without regard to the cell type or localization of the cells in the intermediate lobe). Stimulation of the adrenocorticotropical axis by an acute injection of 0.2 ml isotonic saline solution/rat was followed by a time-dependent increase of nuclear sizes of the fasciculata cells and pars intermedia, whereas the nuclear volumes of the thyroid follicular cells, the anterior pituitary thyrotropical cells and the posterior pituitary cells decreased. Thus the functional state of the pars intermedia was in accordance with that of the adrenal cortex. Also the posterior pituitary cells responded to stimuli applied to the thyrotropical axis at the same degree as the thyrotropic organs themselves. Between the nuclear sizes of the pars intermedia and posterior pituitary we established the same inverse functional relationships as between the adrenal cortex and the thyroid gland.

A functional analysis of dopaminergic innervation of the neurohypophysis

Dopaminergic neurons arising from cell bodies in the rostral arcuate nucleus of the hypothalamus have been shown to make axoaxonic contact with neurohypophyseal neurosecretory axons. In this study, electrical stimulation of the rostral arcuate nucleus depresses multiunit electrical activity recorded from neurosecretory axons within the neurohypophysis. After a single 5-s stimulus train, neurohypophyseal electrical activity is reduced to 6% of control. The superfusion of dopamine (5 micrograms/microliters) onto the neurohypophysis also has an inhibitory effect. Superfusion directly onto the neurohypophysis of the dopamine-receptor antagonist, pimozide (1 micrograms/microliters), abolishes the inhibitory effect of arcuate nucleus stimulation. These findings suggest that the dopaminergic innervation of the neurohypophysis may have an inhibitory influence on the release of neurohypophyseal hormones.

The posterior pituitary: regulation of anterior pituitary prolactin secretion

Removal of the posterior pituitary from anesthetized male rats results in a prompt and significant increase in circulating prolactin that is reversed by the injection of dopamine. Posterior pituitary extracts, which contain high concentrations of endogenous dopamine, inhibit prolactin secretion from isolated anterior pituitary cells. This inhibition is prevented by incubation of the cells with the dopamine receptor antagonist (+)-butaclamol. The data show that posterior pituitary dopamine reaches the anterior pituitary via the short hypophysial portal vessels and participates in the regulation of prolactin secretion.

Vasopressin concentrations in hypophysial portal plasma: insignificant reduction following removal of the posterior pituitary gland

This study was designed to determine the relative contribution of vasopressin-secreting nerve terminals in the median eminence compared to those in posterior pituitary to the high concentrations of the hormone in hypophysial portal blood. Vasopressin was measured by radioimmunoassay in plasma obtained by microcannulation of individual long portal veins of 8 intact male Long-Evans rats (2.0 +/- 0.44 ng/ml SEM), and in 8 in which the posterior pituitary was removed just prior to collection (1.5 +/- 0.3 ng/ml SEM). Since there was no significant difference /p = 0.23, NS) in the concentration of vasopressin in portal plasma after removal of the posterior pituitary gland, these results suggest that the direct vasopressin pathway to the median eminence is the major source of vasopressin in portal blood of the rat.

Electrophysiological recordings from oxytocinergic neurones during suckling in the unanaesthetized lactating rat

A method is described for making extracellular recordings of the spontaneous activity of single hypothalamic neurones in unanaesthetized, freely moving, lactating rats using chronically implanted micro-wire electrodes. Extracellular recordings taken from individual neurones were maintained for periods of between 1 and 12 days. These records were not affected by any normal movement of the animal. As several micro-wires were implanted into each animal it was possible to make simultaneous recordings from several different hypothalamic sites in the same animal. Some recordings were identified as those from magnocellular neurones in the paraventricular nucleus on the basis of antidromic invasion after electrical stimulation of the neurohypophysis. Milk ejection in response to the prolonged sucking of ten or more pups was intermittent, and individual milk ejections recurred at intervals of 2-10 min throughout each period of nursing. The rise in intramammary pressure at milk ejection was associated with a vigorous extensor response from the pups. This was monitored by radar to provide an index of milk ejection in the unanaesthetized rat. Eleven antidromically identified neurones were recorded through 321 milk ejections. Eight of these neurones displayed a transient (2-6s) and very substantial acceleration in discharge at the time predicted for oxytocin release, i.e. 10-12s before milk ejection. The background discharge of these cells was 0.1-2.6 action potentials/s; this increased to 16-50 action potentials/s during the brief period of accelerated activity. Twenty-five neurones were studied during 365 milk ejections in rats which did not have a stimulating electrode implanted in the neurohypophysis. Thirteen of these neurones displayed a burst of high frequency discharge before each milk ejection, similar to that described for the antidromically identified neurones. Two of the non-responsive cells displayed a phasic pattern of discharge, characteristic of vasopressinergic neurone discharge recorded in anaesthetized rats. These observations of putative oxytocinergic neurones in unanaesthetized, freely moving rats are identical with those previously made on anaesthetized rats, and establish that the high frequency burst of electrical activity displayed by magnocellular neurones some 10-12s before milk ejection is responsible for oxytocin release under normal physiological circumstances.

Connections of the hypothalamic paraventricular nucleus with the neurohypophysis, median eminence, amygdala, lateral septum and midbrain periaqueductal gray: an electrophysiological study in the rat

Extracellular recordings were obtained from 555 paraventricular (PVN) nucleus neurons in pentobarbital-anesthetized male rats. Cells were examined for their spontaneous activity patterns and response to single 1-Hz electrical stimulation of the neurohypophysis, median eminence, amygdala, lateral septum (LS) and midbrain periaqueductal gray (PAG). Neurohypophyseal stimulation evoked antidromic activation from 109 neurons. Among spontaneously active neurohypophyseal neurons, evidence of a recurrent inhibitory pathway usually required pituitary stimulus intensities twice threshold for antidromic activation. Orthodromic excitatory or inhibitory responses followed amygdala and LS stimulation, but not PAG stimulation. The amygdala influence was predominantly inhibitory to 'phasic' (putative vasopressin-secreting) PVN neurohypophyseal neurons. Neurohypophyseal stimulation evoked orthodromic responses from 124 PVN cells; some of these neurons were also responsive to stimulation in other sites. Median eminence stimulation evoked antidromic responses from 37 PVN neurons; some of these cells also displayed phasic activity but no evidence for recurrent inhibition. Twelve cells in this group were also activated antidromically from both the median eminence and the neurohypophysis; collision tests suggest that the median eminence innervation may be an axon collateral of a neurohypophyseal pathway. Amygdala stimulation was inhibitory to some cells in this category. Amygdala, LS and PAG stimulation evoked antidromic activation from a small number of PVN cells, but none of these cells appeared to innervate more than one area, including the neurohypophysis, and none displayed phasic activity. Orthodromic responses were recorded among other PVN neurons after stimulation in these sites; however, PAG stimulation was the least effective stimulation area. These observations provide additional electrophysiological data that confirm efferent PVN connections to all areas tested, afferent connections from amygdala and LS but not PAG, and the possibility for coordinated activity among PVN neurons through local recurrent or common afferent connections.

Corticoliberin activity of rat neurohypophysis is distinct from vasopressin

Electrical stimulation of the neural lobe of the pituitary resulted in an increase of corticosterone secretion in both normal and Brattleboro rats. Bioassaying the corticoliberin (CRF) activity of stalk-median eminence and neural lobe extracts obtained from normal and Brattleboro rats revealed that the endogenous vasopressin was not a prerequisite of ACTH-releasing potency. Arginine-8-vasopressin failed to potentiate the CRF activity of the different extracts. These data suggest that a nonvasopressin substance(s) with CRF activity can be released from the neurohypophysis of the rat, and it may contribute to activating the pituitary-adrenal axis under certain experimental conditions.