Nociceptin/orphanin FQ and the regulation of neuronal excitability in the rat bed nucleus of the stria terminalis: interaction with glucocorticoids

Nociceptin (N/OFQ) peptide has regulatory roles in neuroendocrine responses to stress. We sought to clarify the roles of nociceptin and its receptors (NOP receptors) in the regulation of rat bed nucleus of the stria terminalis (BNST) neurones in vitro. The effect of nociceptin (75 nM) across subregions of the anterior BNST was determined using extracellular single-unit recordings in rat brain slices. Firing patterns of the neurones were recorded in the presence of N-methyl-D-aspartate (NMDA, 10 μm) for the classification of putative cell types. Based on the firing patterns, four cell types were identified. The distribution of cell types differed between the dorsal and ventral BNST. Nociceptin inhibited the activity of 53.2% of all the neurones tested (n = 47), regardless of the cell type or subregion. The duration of nociceptin-mediated inhibition of cell firing was significantly attenuated by pre-treatment with the NOP receptor antagonist, UFP-101 (750 nM), indicating that nociceptin-induced suppression of firing rate involves NOP receptor activation in the BNST. Pre-treatment of slices with 100-nM corticosterone (CORT) vs. dimethylsulphoxide (DMSO) for 20 min significantly abolished the nociceptin-induced inhibition of firing rate (P < 0.001) when tested 2 h later. We did not, however, observe a significant effect of CORT on baseline firing rate or pattern in BNST neurones. We suggest that the interaction between nociceptin and glucocorticoids in the BNST may be essential for normal adaptive stress responses.

A neuromodulatory role for oxytocin within the supramammillary nucleus

Oxytocin functions as both a neurohypophysial hormone and central neuromodulatory peptide, and has been implicated in reproductive behaviours, anxiety and reward, as well as facilitation of the neuroendocrine milk-ejection reflex. A potential substrate for oxytocin is the supramammillary nucleus (SuM), a structure that contains oxytocin binding sites and serves as an important relay within the limbic system. Hence, this study investigated the neuromodulatory role of oxytocin within the SuM. Firstly, the effect of oxytocin on neuronal firing within the SuM was studied, using in vitro brain slices from virgin female rats. Oxytocin (10(-6)M) excited approximately 50% of SuM neurones, and similar results were obtained with the selective oxytocin agonist, Thr(4) Gly(7) oxytocin (TGOT) (10(-6) and 10(-7)M). The remaining neurones were unaffected. The TGOT response was blocked by application of the oxytocin antagonist, [d(CH(2))51,Tyr(Me)(2),Thr(4),Orn(8),Tyr-NH29]-vasotocin. Repeat doses of TGOT caused diminution of the response, indicative of desensitisation. In the second series of experiments, immunocytochemical techniques were used to study the oxytocinergic innervation of the SuM. The supramammillary decussation was found to contain numerous oxytocinergic fibres, and some could be seen coursing ventrally to enter the SuM. Whereas, some were clearly "en passant" fibres innervating the neurohypophysis, others followed a more convoluted and branching course, and appeared to terminate within the nucleus. Finally, in vivo microinfusion studies investigated whether oxytocin injected into the SuM facilitated the milk-ejection reflex, a well known action of central oxytocin. Oxytocin microinfusion in the region of the SuM caused a pronounced facilitation of the reflex, contrasting with the much smaller effects of microinfusions made rostral or caudal to the nucleus. Collectively, these results strongly support a neuromodulatory role for oxytocin within the SuM. This could have important implications for understanding the diverse neuroendocrine and behavioural functions of central oxytocin, including its role in reward.

Excitatory effects of oxytocin and cholecystokinin on oxytocin neurones: differences between virgin, pregnant and lactating rats

Extracellular recordings were made from supraoptic oxytocin (OT) neurones in rat brain slices to investigate the effect of reproductive state on their excitation by OT and cholecystokinin (CCK). Stable background activity was induced by local glutamate application, and OT neurones were identified by their continuous firing and opioid inhibition. The excitatory effect of OT (indicated by percentage neurones excited, peak increment in firing, and response magnitude) was maximal in lactating rats, intermediate in virgin, and lowest in pregnant animals. Excitation by CCK was high in both lactating and virgin rats but, as with OT tests, was minimal in the pregnant group. These adaptations in the responses to OT and CCK may help to ensure that the firing of OT neurones is appropriately regulated to meet changing demands for OT release.

Hypothalamic targets for prolactin: assessment of c-Fos induction in tyrosine hydroxylase- and proopiomelanocortin-containing neurones in the rat arcuate nucleus following acute central prolactin administration

Prolactin (PRL) has been implicated in central actions including those that result in its own regulation and/or the suppression of gonadotropin secretion. It is not clear, however, which neuronal systems may mediate the central effects of PRL. Here, using dual immunohistochemistry for c-Fos and either tyrosine hydroxylase (TH) or proopiomelanocortin (POMC), we have assessed neuronal activation, following centrally administered PRL, within two neuronal networks that have been shown to participate in the inhibitory regulation of reproductive function. Male rats received one intracerebroventricular injection of either PRL (5 microg) or saline (vehicle control) 5 days after cannulae were inserted into the lateral ventricles. Ninety minutes after treatment, animals were perfused with 4% paraformaldehyde, the brains were removed and 30-microm frozen sections were cut throughout the entire hypothalamic region. Parallel sets of sections were processed for both c-Fos immunoreactivity (ir) and either TH-ir or POMC-ir. PRL increased the mean number of c-Fos-ir neurons within the rostral arcuate nucleus (9.3 +/- 2.0 vs. 5.0 +/- 1.2 cells/section, for PRL and control rats, respectively; p < 0.05). Within the TH-ir neurones, PRL induced a significant increase in c-Fos in the dorsomedial portion of the mid-arcuate nucleus (p < 0.05). In contrast, there was no significant increase in the expression of c-Fos within the POMC neurones of the arcuate nucleus. PRL also induced c-Fos expression in the supraoptic nucleus (SON) (11.7 +/- 3.2 vs. 3.0 +/- 1.4 cells/section for PRL and control rats, respectively; p < 0.05), but not in the medial preoptic nucleus, ventromedial nucleus or the dorsomedial nucleus, areas reported to either contain gonadotropin-releasing hormone neurones or express PRL receptors. The results from this study show immediate early gene activation within both the arcuate nucleus and the SON of the hypothalamus following acute PRL administration. While the role of PRL-responsive neurones in the SON remains to be elucidated, these findings support the notion that the central actions of PRL could be mediated via the TH neurones of the dorsomedial arcuate nucleus and/or by a population of neurones in the rostral arcuate nucleus that contain neither TH nor POMC.

Permissive effect of centrally administered oxytocin on the excitatory response of oxytocin neurones to ventral tegmental stimulation in the suckled lactating rat

The mesencephalic ventral tegmentum has been implicated in the milk-ejection reflex and modulation of inputs from this region could provide a mechanism whereby central oxytocin facilitates synchronous bursting of oxytocin neurones during suckling. Experiments were therefore undertaken to investigate the effect of intracerebroventricular (i.c.v.) oxytocin on the response of oxytocin neurones to ventral tegmental stimulation. Oxytocin neurones were recorded in the supraoptic nucleus of urethane-anaesthetized lactating rats during suckling, and their response to single shock stimulation of the ventral tegmentum was monitored using peri-stimulus time-interval histograms. Before i.c.v. oxytocin, oxytocin neurones were either unresponsive to ventral tegmental stimulation, or displayed a small inhibition. However, after administration of oxytocin (2.2 ng i.c.v.), seven out of eight neurones tested displayed a pronounced excitatory response (onset latency 78.4 +/- 4.8 ms, duration 73.4 +/- 8.3 ms). This permissive effect on the excitatory response was only observed in the presence of suckling, and followed the same time course as facilitation of the milk-ejection reflex, being maximal immediately before each facilitated bursting response in the oxytocin neurones. The response to ventral tegmental stimulation remained unaltered after intraperitoneal administration of hypertonic saline to cause a generalized increase in the excitability of the oxytocin neurones. Moreover, i.c.v. oxytocin had no effect on the response of oxytocin neurones to stimulation of a descending input from the medial septum. In conclusion, administration of i.c.v. oxytocin has a selective permissive effect on the excitation of oxytocin neurones from the ventral tegmentum, and this supports previous in vitro studies suggesting that centrally released oxytocin may act as a modulator of afferent transmission to the magnocellular nuclei. This effect on the afferent excitation of oxytocin neurones may provide a mechanism whereby i.c.v. oxytocin facilitates suckling-evoked bursting activity.

Effect of gonadal steroids on the oxytocin-induced excitation of neurons in the bed nuclei of the stria terminalis at parturition in the rat

Experiments were undertaken to examine the role of ovarian steroids in peripartum programming of oxytocin sensitivity of limbic neurons implicated in oxytocin-induced facilitation of the milk-ejection reflex. In vivo recordings of neurons in the bed nuclei of the stria terminalis and ventrolateral septum of pre-parturient rats which had undergone prior ovariectomy and hysterectomy showed that oestradiol significantly increased the excitatory responses of bed nuclei/ventrolateral septum neurons to intracerebroventricular oxytocin, compared to oil-treated controls. Oestradiol also increased the excitation of bed nuclei neurons to the selective oxytocin agonist, [Thr4,Gly7]oxytocin in brain slices from steroid pre-treated ovariectomized hysterectomized rats, so that both the proportion of responsive neurons, and the magnitude of their responses were significantly increased. Parallel autoradiographic studies showed that oxytocin binding in the medial bed nuclei and ventrolateral septum was selectively increased following oestradiol treatment. Progesterone pre-treatment had no effect on either oxytocin sensitivity of bed nuclei/ventrolateral septum neurons recorded in vivo, or on oxytocin binding in the medial bed nuclei and ventrolateral septum, compared to oil-treated controls. Mean responses to [Thr4,Gly7]oxytocin in bed nuclei neurons recorded in slices from progesterone-treated rats were larger than controls, but this effect was highly variable. These results demonstrate that oestradiol greatly enhances oxytocin receptor expression and sensitivity of bed nuclei/ventrolateral septum neurons to oxytocin over the peripartum period, consistent with involvement of this steroid in enhancing oxytocin regulation of neuroendocrine and behavioural adaptations required for lactation.

Electrophysiological effects of oxytocin within the bed nuclei of the stria terminalis: influence of reproductive stage and ovarian steroids

The bed nuclei of the stria terminalis (BNST) is a target site for the central actions of oxytocin (OT) in promoting behavioural and neuroendocrine responses involved in female reproduction, and binding studies suggest that OT sensitivity may be modulated over the peripartum period. Electrophysiological recordings from brain slices in vitro showed that OT sensitivity of BNST neurones is relatively low in late pregnancy, but is high during lactation. In vivo studies over the immediate peri-partum period revealed that although BNST neurones can be excited by i.c.v. OT at day 22 of pregnancy, there is a 5-10 min delay in their response which is not present in lactation. This delay can be reversed by naltrexone, or lesioning the stria terminalis, and may involve an inhibitory opioid input to the BNST from the amygdala. Examination of the role of steroids in regulating OT responses of BNST neurones showed that oestradiol pre-treatment in late pregnant ovariectomized rats increased OT excitation of BNST neurones in vitro, and a similar result was observed with in vivo recordings. Progesterone also augmented OT excitation of BNST neurones in vitro, but no such effect was observed in vivo. This difference could indicate that an additional effect of progesterone is to potentiate extraneous inhibitory inputs to the BNST, or may reflect the ability of this steroid to suppress OT sensitivity by a direct membrane action. Changes in the response of BNST neurones to OT may have functional implications for the action of central OT in facilitating the neuroendocrine milk-ejection reflex (i.e. increasing milk-ejection frequency), an effect which first appears at around day 3 of lactation. Studies involving steroid treatment of late pregnant ovariectomized rats showed that this facilitatory mechanism can be induced to appear early (i.e. on day 22 of pregnancy) by oestradiol, but not progesterone treatment. Collectively, these results support this view, that the action of OT in the BNST is regulated by the changing levels of steroids towards the end of pregnancy, thereby ensuring appropriate neuroendocrine responses necessary for motherhood.

Supraoptic oxytocin and vasopressin neurones show differential sensitivity to the neurosteroid pregnenolone sulphate

The neurosteroid pregnenolone sulphate (PS) interacts allosterically with ionotropic glutamate receptors and thereby could be an important modulator of activity within the hypothalamic magnocellular nuclei. The present in-vitro study therefore examined the effect of perifusion of PS (100 microM) on activity of supraoptic oxytocin (OT) and vasopressin (VP) neurones, in which firing was stimulated by local application of glutamate, NMDA or AMPA. In the presence of locally applied glutamate, PS significantly potentiated firing in putative VP neurones, but had little effect on putative OT neurones. In both cell types, PS increased firing in the presence of NMDA and depressed firing in the presence of AMPA. The action of PS on glutamate- and NMDA-stimulated firing was unaffected by addition of the GABA(A) receptor antagonist, picrotoxin (50 microM). The suppressive action of PS on AMPA-stimulated firing was, however, reversed by picrotoxin and therefore probably requires intact GABAergic transmission for its expression. When putative VP neurones were stimulated by local application of K+, in the presence of picrotoxin, PS evoked a small increase in the ongoing activity, although this did not reach significance. When the glutamate receptor antagonists, NBQX (20 microM) and AP5 (40 microM), were included in the medium, no change in K+ -stimulated firing was observed. Hence PS has no effect on activity of putative VP neurones in the absence of exogenous and endogenous glutamate excitation. In conclusion, PS selectively potentiates glutamate-stimulated activity in putative VP neurones, probably via NMDA receptors, thus providing a mechanism whereby this neurosteroid might exert rapid non-genomic effects on VP secretion. The lack of effect of PS in putative OT neurones probably relates to the relatively small involvement of NMDA receptors in mediating glutamate excitation in this cell type.

Electrophysiological responses of neurones in the rat nucleus tractus solitarius to oxytocin-releasing stimuli

Neurones in the nucleus tractus solitarius (NTS) of the rat are, at least partially, responsible for mediating the excitatory effects of systemic cholecystokinin (CCK) injection and parturition on oxytocin release. Utilising in vivo electrophysiological recordings in urethane-anaesthetised rats we examined the effects of systemic CCK injection and vaginal distension (VD) on NTS neuronal activity. Approximately 25% of neurones were excited by CCK injection and a population of neurones (24%) responded specifically to VD, but only one neurone responded to both oxytocin-releasing stimuli. NTS neurones that projected to the hypothalamus also responded in a specific manner to either CCK or VD. It is known that the excitatory effects of CCK and VD on oxytocin release are mediated by separate peripheral pathways and the results from this study suggest that separation of these two inputs persists at the level of the NTS.

Glutamate excitation of oxytocin neurones in vitro involves predominantly non-NMDA receptors

Experiments were undertaken to compare effects of the NMDA and non-NMDA receptor antagonists, AP5 (40 microM) and NBQX (10 microM), on glutamate-induced firing in supraoptic oxytocin (OT) and vasopressin (VP) neurones in vitro. In putative OT neurones NBQX caused a significantly greater reduction in firing than AP5, whilst in putative VP neurones both antagonists reduced activity powerfully and to a similar extent. The relatively small effect of AP5 in putative OT neurones was unaffected by the removal of extracellular magnesium. These results suggest that glutamate-induced firing in putative OT neurones is predominantly controlled by non-NMDA receptors.

The neurosteroid pregnenolone sulphate enhances NMDA-induced phasic firing of vasopressin neurones in the rat supraoptic nucleus

The effect of the neurosteroid pregnenolone sulphate (PS) on N-methyl-D-aspartate (NMDA)-induced phasic firing of supraoptic vasopressin (VP) neurones was studied in rat hypothalamic slices in vitro. In VP neurones which were induced to fire phasically by continuous perifusion with NMDA (9-30 microM), addition of 100 microM PS to the incubation medium significantly increased overall spike frequency, with a rise in both proportion of time active and intraburst firing rate. A similar effect was seen during picrotoxin block of GABAergic transmission. No significant change in NMDA-induced phasic firing was observed with 100 microM dehydroepiandrosterone sulphate. VP neurones became silent in the absence of NMDA, and under these conditions PS had no effect. In conclusion, PS increases NMDA-induced phasic firing in VP neurones, providing a mechanism whereby this neurosteroid may participate in the regulation of VP secretion.

The milk-ejection reflex in the peri-partum rat: effects of oestradiol and progesterone on basal milk-ejection frequency and the facilitatory response to central oxytocin

Experiments were undertaken to examine the effects of ovarian steroids on the functional characteristics of the milk-ejection reflex during late pregnancy. Basal milk-ejection frequency and response to i.c.v. oxytocin (OT) were compared in different experimental groups, using intramammary pressure recordings obtained in suckling tests under urethane anaesthesia. Ovariectomy (OVX) on day 20 of pregnancy significantly (P < 0.05) increased milk-ejection frequency on day 22, compared with sham-OVXed animals. I.c.v. injection of 2.2 ng OT during suckling had no consistent effect on milk ejection in either of these groups. Pretreatment with oestradiol (5 micrograms per day, s.c.) or progesterone (5 mg per day, s.c.) both resulted in a fall in milk-ejection frequency compared to oil-treated OVXed controls. However, whereas oestradiol-treated OVXed rats showed a facilitatory response to i.c.v. OT, with a significant (P < 0.05) increase in milk-ejection frequency in the 20 min period after injection, progesterone-treated OVXed rats showed only a delayed decrease in milk-ejection frequency (significant at P < 0.05 between 20-40 min after injection). Oil-treated OVXed rats showed no significant response to i.c.v. OT at any stage. Electrophysiological recordings from supraoptic OT neurones confirmed that bursting activity was increased by i.c.v. injection of OT in oestradiol-treated, but not progesterone-treated rats. Further experiments with hysterectomized ovariectomized rats indicated that the difference in response to i.c.v. OT in oestradiol- vs progesterone-treated rats was not related to changes in the timing of birth induced steroid treatments. These findings demonstrate the ability of ovarian steroids to alter the characteristics of the milk-ejection reflex in the peri-partum rat. In particular, the rise in oestradiol and fall in progestesterone near term, may contribute to programming of the facilitary response to central OT in preparation for lactation.

Analysis of bursting responses of oxytocin neurones in the rat in late pregnancy, lactation and after weaning

1. Electrophysiological recordings were undertaken to compare bursting characteristics of oxytocin (OT) neurones at four reproductive stages: day 20 pregnancy, day 22 of pregnancy (expected day of parturition), day 7-11 of lactation, and day 5-6 after weaning. 2. Each OT neurone was recorded for 1 h of suckling, combined with cervico-vaginal probing at 5 min intervals as an additional stimulus for bursting. Intracerebroventricular (I.C.V.) oxytocin (2.2 ng) was given after 30 min to facilitate bursting responses. Bursts observed during suckling were classified as 'spontaneous' or 'probe-evoked'. 3. The percentage of cells displaying spontaneous and/or probe-evoked bursts during the recording was low in day 20 pregnant animals, high in lactators and intermediate in day 20 pregnant and weaner groups. These differences may relate to variation in the proportion of animals with a responsive milk-ejection reflex, as well as the relative size of the population of bursting OT neurones. 4. In the period before I.C.V. OT, overall burst frequency (including both spontaneous and probe-evoked bursts) was similar across groups. After I.C.V. OT, overall burst frequency was much higher in lactators compared with other groups. Similar results were obtained when spontaneous bursts were analysed separately. 5. Burst amplitude (action potentials per burst, including both spontaneous and probe-evoked bursts) prior to I.C.V. OT was similar between the day 20 pregnant, day 22 pregnant and lactating groups, but was lower in weaners. All groups showed an increase in burst amplitude after I.C.V. OT, but values in weaners remained lower than in other groups. In a separate analysis of spontaneous bursts, burst amplitude after I.C.V. OT was higher in lactators, and lower in weaners, than in pregnant animals. 6. Background firing rates of OT cells were higher in the day 20 and day 22 pregnant groups compared with lactators, and lower in weaners. Only OT cells in lactators showed a significant increase in background firing rates following I.C.V. OT. 7. It is concluded that the bursting characteristics of OT cells change markedly between late pregnancy, mid-lactation and weaning. The factors underlying these changes, which are only loosely correlated with the sequence of morphological adaptations in OT cells surrounding lactation, remain to be established.

Mortyn Jones Memorial Lecture. Limbic regions mediating central actions of oxytocin on the milk-ejection reflex in the rat

Central oxytocin administration has a profound facilitatory effect on the patterning of the milk-ejection reflex in the lactating rat. Lesion and microinjection studies indicate that this action is, in part, mediated via a population of limbic neurones in the bed nuclei of the stria terminalis and ventrolateral septum, which have been shown to possess oxytocin receptors and to be activated by selective oxytocin-receptor agonists in vitro. In vivo electrophysiological recordings reveal that some of these neurones display cyclical activity which is highly correlated to each milk ejection, and are rapidly activated following i.c.v. administration of oxytocin, coincident with the facilitation of milk ejection activity. A hypothetical model is proposed in which this population of limbic neurones serves to gate the activity of a pacemaker which, in turn, coordinates the bursting of hypothalamic magnocellular neurones. The oxytocin innervation of these neurones and their expression of oxytocin receptors increases in the postpartum period, and the resultant enhanced sensitivity leads to a greater facilitatory response during lactation. Inhibitory opioid and noradrenergic inputs which converge on these oxytocin-sensitive neurones may function to switch off the facilitatory circuit during periods of stress. Thus, this population of limbic neurones participates in the regulation of neuroendocrine activity during lactation by providing an appropriate degree of feedback to alter the patterning of the milk-ejection reflex.

The effects of [Arg8]vasopressin and [Arg8]vasotocin on the firing rate of suprachiasmatic neurons in vitro

The excitatory effect of [Arg8]-vasopressin and its potential contribution to the circadian cycle of electrical activity in the suprachiasmatic nucleus of the rat was investigated using extracellular recordings from hypothalamic slices from virgin female rats. The majority of neurons tested for their responses to vasopressin and [Arg8]-vasotocin displayed coincident, dose-dependent excitation by both peptides, although the relative efficacy varied between neurons, with some showing a highly preferential excitation by vasotocin. Perifusion with the vasopressin receptor antagonist d(CH2)5[Tyr(OEt)2,Val4,Cit8]-vasopressin was able to block the majority of responses to vasopressin or vasotocin (20/25), and similar excitation could be induced by the selective agonist [Phe2,Orn8]-vasotocin, indicating a mainly V1 receptor-mediated effect. Few neurons (3/27; 11%) responded to the oxytocin-specific agonist, [Thr4,Gly7]-oxytocin, suggesting a low occurrence of oxytocin receptors. In addition to blocking the action of exogenous vasopressin, the V1 antagonist caused a reversible suppression of spontaneous basal activity in 7/25 cases, consistent with the presence of an endogenous excitatory vasopressin tone. In agreement with previous reports, the activity of suprachiasmatic nucleus neurons showed a significant correlation between spontaneous activity and the light-dark cycle, with activity decreasing during the subjective dark phase. When neurons were divided on the basis of their response to vasopressin and/or vasotocin, the peptide-sensitive neurons continued to show a strong correlation (r = 0.513, P < 0.01) while the insensitive neurons showed no correlation (r = 0.136, P > 0.05). These data confirm the presence of V1 type receptors in the suprachiasmatic nucleus and also indicate a small number of neurons possessing additional classes of receptor selective for either oxytocin or vasotocin. Contrary to previous reports, they also demonstrate that endogenous vasopressin tonically excites suprachiasmatic nucleus neurons. The fact that vasopressin-sensitive (but not vasopressin-insensitive) neurons show a level of basal activity correlated with time, suggests that this tone may contribute to the circadian cycle of electrical activity in the suprachiasmatic nucleus.

Inhibition of supraoptic vasopressin neurones following systemic clonidine

Experiments were undertaken in urethane-anaesthetized rats to investigate the effects of systemic clonidine on the firing of supraoptic vasopressin (VP) neurones, which were identified by their characteristic phasic activity pattern. Injection of clonidine (50 micrograms/kg i.v.) reduced the firing of all 16 VP neurones tested, and their overall mean activity decreased from 5.09 +/- 1.01 to 1.63 +/- 0.64 spikes/second (P < 0.02). In VP cells which were already firing phasically before clonidine, the inhibition resulted in complete quiescence. In VP cells which were originally continuously active, the inhibition resulted in a switch to phasic activity. This inhibitory effect, which was prevented by prior injection of the alpha-2 antagonist idazoxan (0.5 mg/kg), had a mean duration of 11.8 +/- 1.8 min. Subsequent experiments revealed that i.v. clonidine (50 micrograms/kg) caused a transient rise in blood pressure, but this had a shorter time-course and was unlikely to account for the prolonged neuronal inhibition. It was concluded that systemic clonidine acts centrally to suppress the activity of hypothalamic VP neurones, thereby explaining the fall in plasma VP levels found in previous studies.

Synchronisation of Bursting in Hypothalamic Oxytocin Neurones: Possible Coordinating Mechanisms

Hypothalamic oxytocin neurones exhibit periodic synchronous bursting during suckling. This involves simultaneous excitation from an afferent pacemaker, coordinating mechanisms acting both within and between the magnocellular nuclei, and intrinsic properties of the oxytocin cells. Centrally released oxytocin facilitates bursting, acting both within the magnocellular nuclei and at limbic sites.

Electrical activity of neurons in the ventrolateral septum and bed nuclei of the stria terminalis in suckled rats: statistical analysis gives evidence for sensitivity to oxytocin and for relation to the milk-ejection reflex

Our previous results obtained by lesioning or stimulating the ventrolateral part of the lateral septum and the bed nuclei of the stria terminalis suggested that this area is involved in the control of milk ejection pattern in rats. The present study was undertaken with the aim of testing ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons as a putative link of the neuronal network controlling the bursting activity of oxytocin neurons in suckled lactating rats (anaesthetized with urethane). Ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons were recorded simultaneously with hypothalamic oxytocin neurons in either the paraventricular or supraoptic nucleus in rats with (n = 26) or without (n = 29) periodic milk ejections. Analysis of their firing pattern enabled differentiation of two subgroups: type I, characterized by numerous high frequency spikes, often grouped in clusters; and type II with very few or no high frequency clusters of spikes. The probability density function of the interspike intervals of both patterns could be modelled using a mixture of two log-normal distributions, the parameters of which differed significantly. The presence of absence of milk ejections did not influence the overall mean level of activity (2.0 +/- 0.5 and 1.9 +/- 0.4 spikes/s, respectively). However, the characteristics of the type I firing pattern were affected by the presence of the milk-ejection reflex. The average level of activity was not always constant and 16/55 ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons displayed cyclical activity (from 0.6 +/- 0.2 to 4.0 +/- 0.5 spikes/s) both in the presence (n = 8) and absence (n = 8) of the milk-ejection reflex. In five of eight neurons recorded during milk-ejection reflex, the cycles in firing were clearly correlated with the bursting of oxytocin neurons. These five neurons exhibited the type I firing pattern. The three remaining neurons and the eight neurons recorded in the absence of milk-ejection reflex displayed the type II firing pattern. Oxytocin (1-2 ng = 0.45-0.9 mU) was injected into the third ventricle (i.c.v.) in order to examine the possible involvement of ventrolateral part of the lateral septum-bed nuclei of the stria terminalis neurons in the facilitatory effect of oxytocin on the reflex.(ABSTRACT TRUNCATED AT 400 WORDS)

Post-partum increase in oxytocin-induced excitation of neurones in the bed nuclei of the stria terminalis in vitro

Extracellular recordings were made from neurones in the bed nuclei of the stria terminalis (BST) in brain slices from female rats on days 13-15 of pregnancy, during lactation or 5-6 days following weaning. The proportion of neurones excited by the oxytocin-specific agonist, Thr4, Gly7-oxytocin, did not change over the peri-partum period, but the magnitude of their response increased significantly during lactation. These data concur with reported changes in receptor density. It is suggested that increased oxytocin responsivity of BST neurones may subserve a regulatory function to maternal behaviour or neuroendocrine reflexes during lactation.

Oxytocin in the bed nucleus of the stria terminalis and lateral septum facilitates bursting of hypothalamic oxytocin neurons in suckled rats

Abstract Several regions of the forebrain possess high densities of oxytocin (OT)-binding sites including the bed nucleus of the stria terminalis (BST) and lateral septum (LS). In order to examine whether these regions participate in the central facilitation of the milk ejection reflex by OT, microinjections of OT (1 ng in 100 nl containing Janus Green dye) were made into the BST (13 tests) or LS (9 tests) of anaesthetized, suckled rats, while recording the electrical activity of OT neurons in the contralateral supraoptic nucleus. Histological localization of injection sites using Janus Green demonstrated that all BST injections were close to the anterior commissure, and LS injections were all located in the ventral division of the LS. Film autoradiographic visualization of OT-binding sites (in 7 tests using [(125)I]OT antagonist) confirmed that the BST and LS injections were located within regions of high OT binding. Injections into both regions facilitated the milk ejection reflex by increasing either the frequency and/or amplitude of OT neuron bursts, or by triggering bursts in animals that previously had shown no milk ejection responses; the mean number of milk ejections in the 30 min before and after injection increasing from 1.6.0.5 to 3.6.0.5 for BST and from 1.5.0.6 to 3.9.0.4 for LS. The OT microinjections had a more variable effect on background activity of OT neurons, increasing firing in some cases and not in others. This facilitatory effect was similar to that induced by microinjections into the lateral ventricle, but was smaller and delayed compared to that induced by injection into the third ventricle (9 tests), possibly due to unilateral activation of target sites. The facilitatory effect was unlikely to have been due to diffusion of OT into the ventricle, since injections into control sites (striatum and thalamus) at similar distances from the ventricle (9 tests) had no facilitatory effect (number of bursts during 30 min before and after injection; 2.2.0.5 and 1.8.0.5, respectively). These data suggest that limbic structures (BST and LS) participate in the action of central OT on the pattern of milk ejections in the suckled rat.

Facilitatory effect of hypothalamo-neurohypophysial tract stimulation on milk ejection frequency in the lactating rat

The relative contribution of magnocellular and parvocellular neurones to the patterning of milk ejections was studied by activation of various parts of the hypothalamo-neurohypophysial tract. During suckling of anaesthetised lactating rats, electrical stimulation of the neurohypophysis/neural stalk (15 Hz, 1.5 s on/1.5 s off, 10 min) evoked an increased frequency of milk ejections as detected by intramammary pressure recording. Bilateral stimulation of the paraventricular nuclei produced a similar facilitation in the post-stimulus period, but stimulation of the supraoptic nuclei (with either low current or current sufficient to evoke peripheral oxytocin release) had no effect on the occurrence of milk ejections. These data are consistent with the hypothesis that parvocellular but not magnocellular neurones participate in the regulation of milk ejection frequency.

Oxytocin excites neurones in the bed nucleus of the stria terminalis of the lactating rat in vitro

Unit recordings were made in the bed nucleus of the stria terminalis in brain slices obtained from lactating rats. Addition of 10(-8) to 10(-6) M oxytocin to the perfusate caused a reversible and repeatable excitation in 28/53 (53%) of neurones. The excitatory effect of oxytocin was completely blocked in the presence of the antagonist [d(CH2)5,D-Tyr(OEt)2,Val4,Cit8]vasopressin (5 x 10(-7) M) and a smaller excitation was achieved with equimolar concentration of arginine vasopressin, implicating the involvement of an oxytocin receptor. This effect is discussed in relation to the actions of centrally administered oxytocin in the lactating rat.

Role of the paraventricular nucleus in controlling the frequency of milk ejection and the facilitatory effect of centrally administered oxytocin in the suckled rat

The milk-ejection reflex was studied in anaesthetized, lactating Wistar rats in order to evaluate the contribution of the paraventricular nucleus (PVN) to the patterning of milk ejection and the facilitatory action of centrally administered oxytocin. In the first series of experiments, radiofrequency lesions were performed and centred: (1) antero-dorsal to the PVN, damaging parts of the medial septum and anterior hypothalamus; (2) in the PVN, such that much of the parvocellular division was destroyed, but parts of the magnocellular division remained intact; or (3) in the PVN, destroying both parvocellular and magnocellular divisions. Suckling tests performed before and after lesioning showed that the milk-ejection interval was significantly increased (decreased frequency) after lesioning in groups 2 and 3, but that milk-ejection amplitude was significantly decreased only in group 3. These results suggest that damage to the parvocellular division of the PVN affects milk-ejection frequency, but that damage to the magnocellular PVN only affects amplitude. Subsequent tests on rats injected into the PVN with the neurotoxin N-methyl-D,L-aspartate revealed a fall in the amplitude and frequency of milk ejection, similar to that after complete radiofrequency lesions of the PVN. In the second series of experiments, the facilitatory action of centrally administered oxytocin (1 mU, 2.2 ng) was examined in animals bearing either sham or complete PVN lesions. In both groups, intracerebroventricular injection of oxytocin was able to increase the frequency of milk ejections, although the incidence of milk ejection was lower in the pre- and post-injection period in the PVN-lesioned animals.(ABSTRACT TRUNCATED AT 250 WORDS)

Effect of centrally administered oxytocin on the association between cortical electroencephalogram and milk ejection in the rat

Abstract The milk-ejection reflex of the rat is closely associated with synchronized activity of the cortical electroencephalogram (EEG), and the frequency of milk ejections has been shown to be greatly facilitated by central oxytocin. The following experiments were undertaken to examine the changes in the EEG during facilitation of the reflex by central oxytocin. Intracerebroventricular injection of 1 mU (2.2 ng) oxytocin during suckling caused a rapid increase in the frequency of milk ejections but no change in the predominantly synchronized pattern of the EEG. However, after a delay (11.3 +/- 0.8 min, mean +/- SE) there appeared to be an increasing proportion of desynchronization, which correlated with cessation of the facilitated milk-ejection responses. Hence, the observed EEG desynchronization may signal activation of mechanisms inhibitory to the milk-ejection reflex. In the absence of the suckling stimulus oxytocin also caused a change to desynchronization. However, this effect was more pronounced and commenced after a much shorter latency (1.7 +/- 0.4 min, mean +/- SE; P < 1.001), suggesting that the desynchronizing effect of oxytocin on the EEG can be attenuated by the suckling stimulus. These results demonstrate two phases in the action of central oxytocin in the suckled rat. During the initial phase, the milk-ejection reflex is facilitated and although there may be a concomitant desynchronizing influence on the EEG this is prevented by the influence of the suckling stimulus. In the later phase, this desynchronizing influence predominates and is accompanied by cessation of milk-ejection responses. Although milk ejections were generally restricted to periods of a synchronized EEG as previously reported, during the oxytocin-induced change to desynchronization a number of milk ejections were observed to occur in the absence of a synchronized EEG. These results provide further evidence that the association between milk ejection and the EEG state is not an absolute causal relationship.

Oxytocin release evoked by electrical stimulation of the medial forebrain in the rat: analysis of stimulus parameters and supraoptic neuronal activity

The role of the medial forebrain area (vertical limb of the diagonal band, medial septum and medial nucleus accumbens) in the control of oxytocin secretion in lactating rats was investigated. Electrical stimulation of the medial forebrain evoked a reproducible rise in intramammary pressure, equivalent to that caused by i.v. injection of 1 mU oxytocin. No pressor effect accompanied this response. Radioimmunoassay of plasma samples showed that stimulation caused a significant rise in the concentration of circulating oxytocin. The effects of changing the parameters of stimulation to the medial forebrain were compared with those evoked by stimulation of the neural stalk. The optimal frequency for stimulation of the forebrain was found to be four-fold lower (10-20 Hz) than that for stimulation of the neural stalk (50 Hz). During continuous prolonged stimulation of the forebrain (20 Hz; 2 min) only a single transient response was obtained, whereas a protracted response was obtained as a result of prolonged stimulation of the stalk. Recordings were made from antidromically identified neurosecretory cells in the supraoptic nucleus. Electrophysiological responses to electrical stimulation of the medial forebrain were characterized by two main features. (1) Single-pulse stimulation produced only a small excitation (one or two action potentials), while high-frequency trains produced a profound facilitation of this response, with each pulse evoking short-duration 'bursting' behaviour in the supraoptic neurons. (2) During long trains of stimulation this frequency-dependent facilitation declined and could only be renewed after a period of rest.(ABSTRACT TRUNCATED AT 250 WORDS)

Prolonged electrical stimulation of the nipples evokes intermittent milk ejection in the anaesthetised lactating rat

Intermittent and continuous electrical stimulation of the nipples elicited milk-ejection responses in the lactating rat. The responses occurred intermittently, with similar amplitudes and periodicity as those seen in suckled rats. The responses were always associated with synchronization of the electroencephalogram (EEG), but some rats with synchronized EEG activity did not milk eject during stimulation. Since continuous stimulation also resulted in intermittent milk ejection it seems unlikely that the periodicity of the reflex in suckled rats depends upon changes in the intensity of sensory stimulation. The techniques of nipple stimulation may be a useful method with which to study neural pathways and other phenomena such as gating involved in oxytocin release and milk ejection. The success of the technique depends on a variety of factors such as parameters of the stimulation and state of anaesthesia.

Afferent projections from the mammary glands to the spinal cord in the lactating rat--II. Electrophysiological responses of spinal neurons during stimulation of the nipples, including suckling

In lactating rats, the milk ejection reflex is evoked and maintained by stimulation of the nipples by the suckling young. In order to understand the processing of the suckling stimulus within the spinal cord, urethane-anaesthetized lactating rats were prepared for electrophysiological recording from the thoraco-lumbar spinal cord during stimulation of the nipples. Single shocks to inguinal or abdominal nipples evoked a cord dorsum potential, consisting of an early (2.6 ms) afferent volley followed by a negative wave (100-200 microV; latency 5-7 ms, duration 5-10 ms). Evoked potentials were also recorded at various depths within the spinal cord, with a maximum amplitude (200-400 microV) at a depth of 400-800 microns, 400-800 microns lateral to the mid-line. At a given recording site, the response was maximal for one particular nipple but submaximal potentials could be evoked from adjacent nipples. Simultaneous stimulation of adjacent nipples caused summation of the response. Unit recordings were made from 35 spinal neurons. Upon electrical stimulation of the nipples, the cells responded with an early train of spikes (latency 5-15 ms), and in 6 cells, a later response (140-180 ms), with a higher stimulation threshold, was also observed. All cells examined showed convergence and summation from different nipples. Twenty out of 27 cells were also activated by stretching of the nipples, which evoked a rapidly adapting response; rhythmical stretching produced a more sustained increase in activity. The cells also responded to other natural stimuli such as touch and pressure or stroking the hair around the nipple and had large receptive fields. Six cells were tested with the suckling stimulus. There was a brisk increase in firing as the pup grasped the nipple and then intermittent (every 18-30 s) episodes of enhanced activity, which directly correlated with the suckling movements. These episodes continued for the duration of the suckling test and were enhanced when a second pup was placed on an adjacent nipple. Finally, from a few experiments when a stimulating electrode was placed within the contralateral antero-lateral funiculus at the level of C2-C3 for antidromic identification, it was seen that some of the cells activated from the nipples projected to higher levels. The short latency responses to nipple stimulation, including suckling, suggest that the suckling stimulus reaches the spinal cord ungated.(ABSTRACT TRUNCATED AT 400 WORDS)

Changing characteristics of the milk-ejection reflex during pregnancy, lactation and after weaning in the rat

The pattern of reflex milk ejection during suckling was investigated in anaesthetized Wistar rats at various stages of pregnancy, lactation and after weaning. Milk-ejection responses were measured using intramammary pressure recordings, and the amount of oxytocin released was estimated from log dose-response lines compiled from the mammary responses to exogenous oxytocin. The number of rats showing intramammary pressure responses to oxytocin increased on Day 22 of pregnancy (the day of parturition) and decreased at 8 days after weaning. The dose-response lines from pregnant animals were shallow, but steepened and shifted to the left during lactation and after weaning. Reflex milk-ejection responses during suckling were detectable in primigravid animals, indicating that birth of the litter and previous suckling experience are unnecessary for the immediate functioning of the reflex. Reflex milk-ejection responses improved during early lactation (such that the frequency and the amount of oxytocin released at each response were maximal at Day 10 of lactation), and subsequently declined in late lactation. Although the frequency of responses in animals 2 and 4 days after weaning was similar to that in late lactating animals, the amount of oxytocin released at each response had risen again to mid-lactation values. In animals undergoing a second pregnancy and lactation the pattern of change in the milk-ejection responses was similar to that of primiparous animals.

Reappraisal of the influence of mammary distension on the frequency of milk ejection in the rat

Experiments were performed to reinvestigate the importance of mammary engorgement for activation of the milk-ejection reflex in the rat. Reflex milk ejection (measured by intramammary pressure recordings during a 2-h suckling test under anaesthesia) was compared in rats with engorged mammary glands (15-h separation from the pups, followed by sham-removal of milk) and in rats with drained mammary glands (15-h separation, followed by milk removal using a foster litter and exogenous oxytocin). In experiment 1, multiple small (2 mu.) doses of oxytocin were used for milk removal: these were effective in emptying the mammary glands and caused no subsequent impairment or change in sensitivity of the mammary response to oxytocin. Using this draining procedure, no significant differences were observed in either the number or relative amplitude of the milk ejections, or the occurrence of pup stretch reactions between engorged and drained rats. Similar results were seen in experiment 2, where an identical draining protocol was used, but the rats were pretreated with propranolol before the suckling test. In experiment 3, large (250 mu.) oxytocin doses were used for milk removal, as in previous studies. Again mammary draining had no effect on milk ejection in a subsequent suckling test (with propranolol pretreatment). However, the number of stretch reactions shown by the pups was significantly (P less than 0.001) reduced from 8.6 +/- 1.4/2 h to 1.9 +/- 0.6/2 h. This effect probably related to long-term impairment of the oxytocin response of the mammary glands following the draining procedure, and could not be attributed to the draining per se.(ABSTRACT TRUNCATED AT 250 WORDS)

Extrinsic control of phasic supraoptic neurones in vitro: burst initiation and termination following brief changes in excitatory drive

Experiments were performed to investigate the responses of phasic supraoptic cells in hypothalamic slices to brief (2-3 sec) changes in excitatory drive, induced by varying the level of local glutamate stimulation. A brief increase in excitation during a silent period immediately triggered a prolonged burst of firing, similar in duration to the ongoing phasic bursts. A transient decrease in excitation during a phasic burst evoked a protracted quiescence, reminiscent of a typical silent period. These results support the idea that in phasic cells the effects of brief synaptic inputs may be amplified in time to produce a prolonged change in electrical activity and associated hormone release.

Effects of morphine and D-Ala, D-Leu enkephalin on the electrical activity of supraoptic neurosecretory cells in vitro

Experiments were performed to investigate the effects of morphine and [D-Ala2, D-Leu5]enkephalin on supraoptic cells in hypothalamic slices in vitro. To ensure the presence of a steady background activity, the cells were recorded with glutamate-filled glass microelectrodes and the level of activity was controlled by selecting a suitable retaining current (0.1-9.8 nA). Under these conditions, supraoptic cells showed either the non-phasic (65%) or phasic (35%) firing pattern previously associated with oxytocin or vasopressin cells, respectively. During perifusion of the slice with morphine (10 microM), 10 out of 17 non-phasic supraoptic cells were profoundly inhibited, five cells showed no response and the remaining 2 cells were excited. Similarly with [D-Ala2, D-Leu5]enkephalin (10 microM), 11 out of 15 non-phasic cells were inhibited, 3 cells showed no response and 1 cell was excited. The inhibition produced by morphine or [D-Ala2, D-Leu5]enkephalin could be reversed by concomitant application of naloxone (10 microM). In contrast to the profound effects seen in the non-phasic cells, only 1 out of 13 phasic cells tested with either morphine or [D-Ala2, D-Leu5]enkephalin was inhibited. The remaining 12 phasic cells showed no change in either their overall firing rate or pattern of activity during opiate perifusion. These results provide further evidence that, in addition to their inhibitory effects within the posterior pituitary, opiates can directly suppress the electrical activity of magnocellular neurosecretory cells at the level of the hypothalamus. However, the absence of an opiate effect on the phasic cells might suggest that the action of opioid peptides within the hypothalamus would be exerted predominantly on the oxytocin, rather than the vasopressin cells.

Mesencephalic areas controlling pulsatile oxytocin release in the suckled rat

Experiments were performed on anaesthetized lactating rats to investigate the effects of radiofrequency lesions of the mesencephalon on the milk-ejection reflex. In lesioned and control rats, intramammary pressure recordings were used to estimate oxytocin release (number and relative amplitude of the intermittent milk-ejection responses) during a 3-h suckling test with ten pups. Bilateral lesions (diameter 0·5–1·5 mm) of the lateral tegmentum (near the brachium of the inferior colliculus and medial geniculate body) seriously disrupted the milk-ejection reflex, reducing the number of rats ejecting milk (two out of ten v. all 12 controls, P<0·001) and the amount of oxytocin they released (1·35±0·35 (s.e.m.) v. 15·52±2·19 mu. for controls, P<0·05). Unilateral lesions of the lateral tegmentum also impaired milk ejection and, if the suckling stimulus was restricted only to the contralateral nipples, oxytocin release was virtually abolished. Bilateral lesions placed more medially in the intermediate tegmentum were far less disruptive (eight out of nine rats ejected milk), though the amount of oxytocin released in this group (8·64±1·88 mu.) was still significantly (P<0·05) lower than controls. All rats with lesions of the central grey (nine) or ventral tegmentum (eight) displayed reflex milk ejection, as did those with multiple lesions of the tectum, central grey and ventral tegmentum (seven); in these three groups the amounts of oxytocin released (13·88±2·68, 13·10±1·90 and 11·04±1·95 mu. respectively) did not differ significantly from controls. Damage to the ventral tegmentum produced an irregular pattern of milk ejection characterized by occasional abnormally short (<2 min) milk-ejection intervals, though the overall number of responses in 3 h was less than that of controls (20·83±1·82 v. 14·50±1·30 mu., P<0·05). In conclusion, these results delineate two mesencephalic areas of particular importance in the milk-ejection reflex: (a) the lateral tegmentum, which appears to be concerned with transmission of the suckling stimulus from the contralateral nipples and is indispensable for oxytocin release, and (b) the ventral tegmentum which, although not an essential component of the reflex, may contribute to the timing of the intermittent milk-ejection responses.

Electrophysiological studies of paraventricular and supraoptic neurones recorded in vitro from slices of rat hypothalamus

1. In slices (300 micrometer) of rat hypothalamus maintained in vitro in isotonic (298 +/- 4 m-osmol/kg) medium, the median firing rate of twenty-four supraoptic (s.o.) neurones was 0 . 05 spikes/s, compared to 0 . 66 spikes/s for twenty-eight paraventricular (p.v.) units (P < 0 . 01) and 0 . 79 spikes/s for forty-three anterior hypothalamic area a.h.a. units (P < 0 . 001). 2. One hundred and two p.v. and s.o. units incubated in hypertonic medium (311--343 m-osmol/kg, achieved by adding NaCl) showed no correlation with osmotic pressure and displayed a similar level of spontaneous activity to units recorded in isotonic medium. Recordings from nineteen p.v. and s.o. units during rapid changes from iso- to hypertonic (338 +/- 4 m-osmol/kg) medium confirmed this lack of osmo-sensitivity. 3. Excitation of s.o. units in vitro with glutamate resulted in firing patterns similar to those found in previous in vivo studies on activated s.o. cells. Thus out of thirty-two glutamate-excited units, twelve (37%) fired in repetitive bursts, giving a phasic pattern and thirteen (41%) showed fast continuous activity. The remaining seven (22%) units showed ambiguous patterns that were neither continuous nor clearly phasic. 4. Mean durations of bursts and silent periods in phasic cells excited by perifused glutamate were 16 . 6 s and 13 . 2 s (calculated from normalized distributions of thirty values), compared to means of 41 . 7 s and 33 . 9 s (thirty-six values, P < 0 . 001 for each parameter) for cells excited by glutamate ionophoresis. The periodicity of phasic firing in vitro was unaffected by a change to hypertonic (340 m-osmol/kg) medium. 5. From these in vitro results it is proposed that the excitation associated with osmotic stimuli in vivo does not originate within the p.v. and s.o. neurosecretory cells, but that it involves a separate osmoreceptor. However, the control of phasic firing, which is commonly found during osmotic excitation, would seem to involve a mechanism which lies within or in close proximity to, the neurosecretory neurones.

Comparison of firing patterns in oxytocin- and vasopressin-releasing neurones during progressive dehydration

The electrical activity of neurosecretory cells in the supraoptic nucleus of the urethane-anaesthetized lactating rat was examined after periods of water deprivation ranging from 0-24 h. Supraoptic units were identified by antidromic activation following stimulation of the neurohypophysis, and classified as oxytocin or vasopressin cells according to their response during reflex milk ejection. In 65 vasopressin cells, dehydration increased the mean firing rate from 2.1 spikes/sec at 0 h to 6.8 spikes/sec at 24 h and caused a change from a slow irregular to a phasic firing pattern. Thus, after 6 h or more of dehydration, 84-100% of the vasopressin cells fired phasically, compared to 12% under normal conditions. In phasic vasopressin cells , the intraburst firing rates were closely related to the stages of dehydration, rising from a mean of 6.3 spikes/sec at 6 h to 12.0 spikes/sec at 24 h. However, no systematic relationship was observed between the stages of dehydration and the mean burst or silence durations. In 77 identified oxytocin units, dehydration increased the firing rate from 0.9 spikes/sec to 2.8 spikes/sec after 24 h, but only 3 (4%) of the cells showed phasic firing. Instead, the oxytocin units changed from a slow irregular to a fast continuous discharge. In conclusion, both vasopressin and oxytocin neurones are activated during chronic dehydration, but there is a marked difference in the pattern of their response. The phasic firing of the vasopressin cells may be important in increasing the occurrence of short interspike intervals and thus facilitating hormone release.

Relationship between the suckling-induced release of oxytocin and prolactin in the urethane-anaesthetized lactating rat

The effects of changes in the intensity of the suckling stimulus on the reflex release of oxytocin and prolactin were compared in urethane-anaesthetized lactating rats. Mothers which had previously suckled 12 pups (Group 1) showed a graded increase in the amount of oxytocin released during a 3 h suckling test when the number of pups applied to the nipples was increased from six to eight or ten. Mothers which had suckled six pups during their lactation (Group 2) appeared to show a maximum frequency of milk ejection whether six, eight or ten pups were applied to the nipples. The release of prolactin was not elicited from either Group 1 or Group 2 mothers when six pups were applied to their nipples. With eight pups suckling, the Group 1 mothers again showed no evidence of prolactin release. In contrast, the Group 2 mothers showed a significant increase in the level of prolactin in the plasma during the 3 h suckling test. With ten pups suckling the release of prolactin was evident in both groups of mothers, although the response was earlier and more pronounced in Group 2 than Group 1. These results suggest that in the urethane-anaesthetized rat, the threshold for the suckling-induced reflex release of oxytocin is distinct from the threshold for the release of prolactin and that these thresholds are, at least in part, set by the preceding suckling experience of the mothers. In those animals which showed both reflex milk ejection and prolactin release there was a linear relationship between the magnitude of the two endocrine responses.

Plasma concentrations of prolactin and thyrotrophin during suckling: effects of stimulation of the median eminence

A.R.C. Institute of Animal Physiology, Babraham, Cambridge, CB2 4AT

(Received 1 November 1977)

Thyrotrophin releasing hormone (TRH) can have a stimulatory effect on the release of both prolactin and thyrotrophin (TSH; Deis & Alonso, 1973), although in the rat, supraphysiological doses of TRH are required to affect the secretion of prolactin (Burnet & Wakerley, 1976). A more important factor in the control of the release of prolactin is considered to be prolactin release inhibiting factor (PIF), which is thought to act through the catecholamine, dopamine (MacLeod, 1976). Stimuli which cause the concomitant release of TSH and prolactin are thought to have a direct effect at the hypothalamic level such that neurones releasing TRH are excited, whereas those releasing PIF are inhibited. In the present work, we have tested this hypothesis using the suckling stimulus to elicit the simultaneous release of prolactin and TSH (Blake, 1974; Burnet & Wakerley, 1976). If

Electrophysiological differentiation of oxytocin- and vasopressin-secreting neurones

Antidromically identified neurosecretory cells of the paraventricular (p. v.) and supraoptic (s. o.) nuclei of the hypothalamus were recorded in lactating rats under urethane anaesthesia during reflex milk ejection (m. e.) and haemorrhage. Eighty one p. v. and s. o. neurones were studied. Their background firing rates ranged from < 0.1 to 6.3 spikes/s and three distinct patterns of activity were encountered: slow irregular (73%), fast continuous (10%) and phasic (17%). Forty units (49%) displayed a brief (2-4 s) high-frequency discharge (30-60 spikes/s) correlated with suckling-induced m. e., and these were classified as m. e. (oxytocin-secreting) neurones. The remainder of the cells showed no activation at this time and were classified as non-m. e. neurones. Ten m. e. neurones tested through haemorrhage (5 ml of blood) showed a gradual acceleration of firing rates, reaching a maximum of 3.7 ± 0.7 spikes/s (mean + s. e.) about 20 min after blood withdrawal. The firing pattern of the m. e. neurones therefore changed from a slow irregular to a fast continuous type. By contrast, 11 non-m. e. neurones tested with the same procedure showed a rapid activation reaching a maximum of 6.4 ±0.6 spikes/s by the fourth minute. Non-m. e. neurones which were initially of the slow irregular type, first became fast continuous and later evolved into a highly characteristic phasic pattern of activity which was never induced in the m. e. neurones. After the blood was replaced, all the cells returned to their original firing pattern. In a parallel series of experiments, plasma samples taken 5 and 25 min after haemorrhage showed a ten-fold elevation in antidiuretic activity. A slight but non-significant increase in m. e. activity was also observed. Thus p. v. and s. o. neurosecretory cells may be electrophysically differentiated into two functionally distinct populations: (1) oxytocin releasing neurones which show a high-frequency discharge before m. e. induced by suckling, and (2) vasopressin-releasing neurones which adopt a phasic pattern of firing during vasopressin release induced by haemorrhage. We suggest that the rate of vasopressin secretion into the circulation largely depends on the proportion of vasopressin neurones firing phasically, their firing rates within the phases and the duration and degree of synchronization of the phases.

Plasma concentrations of prolactin and thyrotrophin during suckling in urethane-anaesthetized rats

Plasma levels of prolactin and TSH were determined by radioimmunoassay in urethaneanaesthetized lactating rats during suckling. Oxytocin release was monitored by recording intramammary pressure. Application of ten pups, 3 h after administration of urethane (1-1 g/kg, i.p.), evoked a parallel rise in prolactin and TSH concentrations which reached a maximum during the 3rd hour of suckling and then declined. Peak hormone concentrations represented a 25-fold increase in prolactin and a ten-fold increase in TSH. Suckling also elicited a pulsatile (every 5-10 min) release of 0-5--1-0 mu. oxytocin. The gradual rise in prolactin and TSH occurred between the 1st and 20th oxytocin pulses. Intravenous injection of thyrotrophin-releasing hormone (TRH) into unsuckled, anaesthetized lactating rats resulted in a 7- to 30-fold increase in TSH concentration, whereas prolactin levels showed no substantial change. These results indicate that suckling releases TSH as well as prolactin in the urethaneanaesthetized rat. However, the absence of prolactin release after injections of TRH makes it unlikely that both endocrine responses are regulated solely by the actions of this one releasing hormone.

Pattern of sucking in the infant rat during spontaneous milk ejection

Two methods are described for measuring the sucking of rat pups on the nipples of the mother. The first uses pressure recording of the cannulated teatduct; the second uses direct observation of sucking behavior. Using these methods, the sucking behavior of the pups during sequences of milk ejections was investigated. Pressure recordings of the sucking of individual pups on the nipple showed that between milk ejections the pups sucked intermittently in bursts. During milk ejection itself there was a longer period of vigorous and continuous sucking. Behavioral observations on the level of sucking in whole litters of pups showed that the background bursts of sucking from the litter as a whole were randomly distributed in relation to the inferred time of oxytocin release. These results indicate that once the pups are sucking on the nipples, variations in the sucking behavior of the litter have no role in the timing of milk ejections in the mother.