The role of the septum in the control of the milk ejection reflex in the rat: effects of lesions and electrical stimulation

Recording and manipulation of the maternal oxytocin neural activities in mice

Pulsatile release of the hormone oxytocin (OT) mediates uterine contraction during parturition and milk ejection during lactation.^1-3 These pulses are generated by the unique activity patterns of the central neuroendocrine OT neurons located in the paraventricular and supraoptic hypothalamus. Classical studies have characterized putative OT neurons by in vivo extracellular recording techniques in rats and rabbits.^1,4-10 Due to technical limitations, however, the identity of OT neurons in these previous studies was speculative based on their electrophysiological characteristics and axonal projection to the posterior pituitary, not on OT gene expression. To pinpoint OT neural activities among other hypothalamic neurons that project to the pituitary^11,12 and make better use of cell-type-specific neuroscience toolkits,¹³ a mouse model needs to be developed for the studies of parturition and lactation. We herein introduce viral genetic approaches in mice to characterize the maternal activities of OT neurons by fiber photometry. A sharp photometric peak of OT neurons appeared at approximately 520 s following simultaneous suckling stimuli from three pups. The amplitude of the peaks increased as the mother mice experienced lactation, irrespective of the age of the pups, suggesting the intrinsic plasticity of maternal OT neurons. Based on a mono-synaptic input map to OT neurons, we pharmacogenetically activated the inhibitory neurons in the bed nucleus of the stria terminalis and found the suppression of the activities of OT neurons. Collectively, our study illuminates temporal dynamics in the maternal neural activities of OT neurons and identifies one of its modulatory inputs.

Neuromodulation of maternal circuits by oxytocin

Motherhood in mammals involves tremendous changes throughout the body and central nervous system, which support attention and nurturing of infants. Maternal care consists of complex behaviors, such as nursing and protection of the offspring, requiring new mothers to become highly sensitive to infant needs. Long-lasting neural plasticity in various regions of the cerebral cortex may enable the perception and recognition of infant cues, important for appropriate caregiving responses. Recent findings have demonstrated that the neuropeptide oxytocin is involved in a number of physiological processes, including parturition and lactation and dynamically shaping neuronal responses to infant stimuli as well. Here, we review experience-dependent changes within the cortex occurring throughout motherhood, focusing on plasticity of the somatosensory and auditory cortex. We outline the role of oxytocin in gating cortical plasticity and discuss potential mechanisms regulating oxytocin release in response to different sensory stimuli.

Virus tropism, distribution, persistence and pathology in the corpus callosum of the Semliki Forest virus-infected mouse brain: a novel system to study virus-oligodendrocyte interactions

The temporal course of cellular pathology in virus-infected oligodendrocytes in vivo is not well defined. Here we study these events in the mouse brain using a novel system in which large numbers of oligodendrocytes can be reproducibly infected. In the mouse, following extraneural inoculation, the A7(74) strain of the alphavirus Semliki Forest virus (SFV) is efficiently neuroinvasive and central nervous system (CNS) infection leads to predominantly perivascular lesions of immune-mediated demyelination. This study demonstrates that direct intracerebral inoculation with SFV A7(74) or the SFV1 vector results in dramatic, selective and widespread infection of the major white matter tract of the brain, the corpus callosum. Mature oligodendrocytes are the predominant cell type infected. Subsequent events are complex; early virus-induced necrotic death of infected cells is followed by apoptotic death of adjacent apparently uninfected cells. A strong inflammatory response and considerable myelin loss are evident from 10 days and virus-positive cells are not observed after this time. In contrast, in athymic nu/nu mice, in the absence of T-cell responses, no inflammatory infiltrates are observed and virus-infected cells persist for over 30 days with extensive vacuolation but less demyelination. The change from an early destructive to a potentially persistent infection of oligodendrocytes is likely to reflect activation of innate immune responses. Activation of peripheral innate defences by inoculation of poly I : C prior to CNS virus infection abrogates the widespread corpus callosum infection. This widespread infection of the corpus callosum provides a novel in vivo system in which to study virus-oligodendrocyte interactions.

Semliki forest virus infection of laboratory mice: a model to study the pathogenesis of viral encephalitis

Semliki Forest virus (SFV) infection of the laboratory mouse provides an experimental system to study the pathogenesis of viral encephalitis. Following extraneural inoculation the virus is efficiently neuroinvasive and crosses the blood-brain barrier to initiate perivascular foci of infection in neurons and oligodendrocytes. The outcome of infection ranges from clinically unapparent mild encephalitis to fatal panencephalitis. SFV infections of the developing nervous system are always highly destructive and are generally fatal. In contrast, SFV infections of the mature nervous system can result in persistent infection with no apparent cell loss. This dramatic difference is attributable to developmental changes in the interactions between virus and CNS cells. Antibody responses clear the systemic infection and control the CNS infection. CD8+ T-cells are required to generate the lesions of inflammatory demyelination which can be a feature of the neuropathology. This article reviews the pathogenesis of SFV encephalitis, describing the neuropathology and the mechanisms which underlie it and which may be fundamental to many viral encephalitides.

Neural populations in the rat forebrain and brainstem activated by the suckling stimulus as demonstrated by cFos expression

During lactation in the rat, the suckling stimulus plays an important role in mediating alterations in hypothalamic neuroendocrine function associated with lactation. To provide the basis for understanding the neural circuitry that may transmit suckling-induced signals into the hypothalamus, the present study used the expression of the immediate-early gene product, cFos protein, as a marker for neuronal activation to identify neural populations in the brain of lactating female rats activated by the suckling stimulus. In addition, cFos expression induced by the exteroceptive sensory stimuli (olfactory, auditory, visual) associated with pup exposure alone was also determined. Thus, cFos patterns in response to the physical suckling stimulus, which would include exteroceptive sensory stimuli associated with pup exposure, were compared with the patterns induced in response to pup exposure alone, so that neuronal populations specifically activated by the suckling stimulus could be identified. After 90 min of suckling, several forebrain areas, including the lateral septum, medial preoptic area, periventricular preoptic area and supraoptic nucleus of hypothalamus, showed a significant increase in cFos expression, compared with non-suckled controls and pup exposure animals. In addition, in the bed nucleus of stria terminalis, the medial amygdala and several cortical areas, cFos-positive cells were found in both suckling and pup exposure animals. In the brainstem, the suckling stimulus induced a significant increase in cFos expression in the ventrolateral medulla, locus coeruleus, lateral parabrachial nucleus, lateral and ventrolateral portions of the caudal part of the periaqueductal gray, and caudal portion of the paralemniscal nucleus, compared with non-suckled controls and pup exposure animals. As expected, in several areas related with sensory input, such as reticular formation and pontine nucleus, cFos expression was found in both suckling and pup exposure animals. Moreover, when double-label immunocytochemistry was used to identify cFos- and catecholamine-positive neurons in the brainstem, it was found that catecholamine-positive neurons in the ventrolateral medulla and locus coeruleus showed a significant increase in cFos expression in response to suckling compared with non-resuckled and pup-exposure groups. Using cFos expression as a marker for neuronal activation, the present studies identified the neural populations in the brain that are activated by the suckling stimulus. By comparing the pattern of cFos expression observed in response to pup exposure alone or the suckling stimulus, the present studies differentiated the neural populations activated by the physical suckling stimulus from the populations activated by the exteroceptive sensory stimuli associated with pup exposure. These suckling-activated areas are likely candidates for playing an important role in transmitting the effects of the suckling stimulus into the hypothalamus to regulate neuroendocrine alterations associated with lactation.

Evidence for a hypothalamic oxytocin-sensitive pattern-generating network governing oxytocin neurons in vitro

During lactation and parturition, magnocellular oxytocin (OT) neurons display a characteristic bursting electrical activity responsible for pulsatile OT release. We investigated this activity using hypothalamic organotypic slice cultures enriched in magnocellular OT neurons. As shown here, the neurons are functional and actively secrete amidated OT into the cultures. Intracellular recordings were made from 23 spontaneously bursting and 28 slow irregular neurons, all identified as oxytocinergic with biocytin and immunocytochemistry. The bursting electrical activity was similar to that described in vivo and was characterized by bursts of action potentials (20.1 +/- 4.3 Hz) lasting approximately 6 sec, over an irregular background activity. OT (0.1-1 microM), added to the medium, increased burst frequency, reducing interburst intervals by 70%. The peptide also triggered bursting in 27% of nonbursting neurons. These effects were mimicked by the oxytocin receptor (OTR) agonist [Thr4, Gly7]-OT and inhibited by the OTR antagonist desGly-NH2d(CH2)5[D-Tyr2,Thr4]OVT. Burst rhythmicity was independent of membrane potential. Hyperpolarization of the cells unmasked volleys of afferent EPSPs underlying the bursts, which were blocked by CNQX, an AMPA/kainate receptor antagonist. Our results reveal that OT neurons are part of a hypothalamic rhythmic network in which a glutamatergic input governs burst generation. OT neurons, in turn, exert a positive feedback on their afferent drive through the release of OT.

Evidence for a hypothalamic oxytocin-sensitive pattern-generating network governing oxytocin neurons in vitro

During lactation and parturition, magnocellular oxytocin (OT) neurons display a characteristic bursting electrical activity responsible for pulsatile OT release. We investigated this activity using hypothalamic organotypic slice cultures enriched in magnocellular OT neurons. As shown here, the neurons are functional and actively secrete amidated OT into the cultures. Intracellular recordings were made from 23 spontaneously bursting and 28 slow irregular neurons, all identified as oxytocinergic with biocytin and immunocytochemistry. The bursting electrical activity was similar to that described in vivo and was characterized by bursts of action potentials (20.1 +/- 4.3 Hz) lasting approximately 6 sec, over an irregular background activity. OT (0.1-1 microM), added to the medium, increased burst frequency, reducing interburst intervals by 70%. The peptide also triggered bursting in 27% of nonbursting neurons. These effects were mimicked by the oxytocin receptor (OTR) agonist [Thr4, Gly7]-OT and inhibited by the OTR antagonist desGly-NH2d(CH2)5[D-Tyr2,Thr4]OVT. Burst rhythmicity was independent of membrane potential. Hyperpolarization of the cells unmasked volleys of afferent EPSPs underlying the bursts, which were blocked by CNQX, an AMPA/kainate receptor antagonist. Our results reveal that OT neurons are part of a hypothalamic rhythmic network in which a glutamatergic input governs burst generation. OT neurons, in turn, exert a positive feedback on their afferent drive through the release of OT.

Electrophysiological analysis of the morphofunctional organization of the limbic control of magnocellular neurosecretory nuclei in the rat hypothalamus

The effects of electrical stimulation of the ventral hippocampus, ventral subiculum, and corticomedial amygdala were used to obtain a general and comparative assessment of the organization of efferent outputs of limbic system structures to the magnocellular neurosecretory nuclei of the hypothalamus, i.e., antidromally identified neurosecretory cells and other groups of identified neurons in these nuclei and in the perinuclear zones. These studies showed that different efferent outputs of the hippocampal formation provide differential control of spike activity of neurosecretory cells in the supraoptic nucleus, with excitatory pathways from the ventral hippocampus and inhibitory pathways from the subiculum. The effects of the amygdala on neurosecretory cells of the paraventricular nucleus were shown to be excitatory, though they were less significant than the excitatory and inhibitory effects of the hippocampus. It was demonstrated that in general, the effect of limbic structures are addressed predominantly to cells which do not project to the posterior lobe of the hypophysis. Projections were mostly to interneurons, which, as convergence sites for excitatory influences both from limbic structures and neurosecretory cells, may thus be responsible for the involvement of the latter in integrative brain functions.

Forebrain expression of c-fos due to active maternal behaviour in lactating rats

To reveal brain sites simultaneously active during the expression of maternal behaviour in lactating rats, we used immunocytochemical visualization of the nuclear protein product Fos of the immediate-early gene c-fos as a marker of neuronal activity. After a 48 h separation from their litter, day 7 postpartum dams received a 1 h period of physical interaction with pups either capable or incapable of suckling, inaccessible pups in a wire-mesh box, an empty box, or no stimulation. Physical interaction with pups elicited high levels of pronurturant maternal behaviour (retrieval, licking, mouthing), and suckling elicited nursing behaviour as well. Exposure to the box, with or without pups, elicited high levels of investigatory sniffing, self-grooming, and general activity. Distal stimulation from pups did not differentially activate Fos in any of 20 sites, including olfactory-processing structures such as the piriform cortex and medial amygdala. Physical interaction with pups, with or without suckling, elicited higher levels of Fos-immunoreactive nuclei than that of other conditions in numerous sites, including many previously implicated in maternal behaviour (medial preoptic nucleus, nucleus accumbens, lateral septum, lateral habenula, and the bed nucleus of the stria terminalis). Similar group patterns of Fos expression also occurred in sites not previously implicated in maternal behaviour (somatosensory cortex and paraventricular thalamic nucleus). Interaction with nonsuckling pups elicited the highest levels of Fos in the cortical amygdala, whereas suckling did not activate higher Fos than nonsuckling interaction in any site included in this report, including hypothalamic nuclei involved in lactation (paraventricular, supraoptic, and arcuate). There was little or no Fos in cingulate cortex, olfactory tubercle, medial septum, medial habenula, or ventromedial hypothalamus. These data suggest that trigeminal stimuli received by lactating rats during the performance of pronurturant maternal behaviour promote cellular activity resulting in neuronal expression of c-fos in many forebrain sites including the medial preoptic nucleus, several sites connected with it that are part of the mesotelencephalic dopamine system, and in the somatosensory cortex. In contrast, in these forebrain sites suckling does not elicit greater levels of Fos than that seen in nonsuckled rats and distal stimuli from pups are ineffective in increasing Fos levels compared with non-stimulated controls.

Connections from the subfornical organ to the oxytocin and vasopressin systems in the lactating rat. A study using electrical stimulations, lesions and electrophysiological recordings

The medial septal area has been implicated in the control of the magnocellular neurosecretory cells of the hypothalamus, and in particular, in the regulation of neurons secreting oxytocin. The present study investigated the hypothesis that this medial septal pathway originates in the subfornical organ. Brief electrical stimulation of the subfornical organ or of the medial septum both evoked a transient rise in intramammary pressure equivalent to that caused by an i.v. injection of 1 mU oxytocin. The optimal frequency was 5-20 Hz for 5-10 s. Prolonged stimulation also elicited at its onset a single transient response, similar to that evoked by brief stimulation. Extracellular recordings were made from neurosecretory cells of the supraoptic nucleus identified by antidromic stimulation of the neural stalk and further classified as vasopressinergic and oxytocinergic by their reaction at the time of reflex milk ejection induced by suckling. Single-pulse stimulation of the subfornical organ rarely produced excitation, but short trains of stimuli evoked a large excitation in most oxytocinergic and vasopressinergic neurons. To delineate further the pathway from the subfornical organ to the magnocellular neurons, stimulations were combined with various lesions of the medial forebrain. The effects of stimulation of the subfornical organ were abolished after a section immediately rostral to the organ, and in most cases after lesion of the medial septum. Stimulation of the medial septum no longer had an effect after the subfornical organ had been lesioned a week prior to experiments, a period sufficient to allow degeneration of subfornical efferents. This study shows that the excitatory afferent input to the oxytocin and vasopressin-secreting neurons of the hypothalamus from the medial septal area originates in the subfornical organ. This input is not involved in the main afferent control of the milk ejection reflex since lesions of the subfornical organ and of the medial septum had no effect on the reflex. It is suggested, therefore, that the subfornical input to both oxytocin and vasopressin cells intervenes to facilitate synergistic action of both hormones in non-reproductive functions.

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.

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)

Further Evidence that the Septum is not part of the Main Pathway of the Milk Ejection Reflex in the Rat

Abstract The possible role of the medial septum in the control of oxytocin release and of the milk ejection reflex induced by suckling was investigated in lactating rats by using electrical stimulations and lesions. In anaesthetized animals, brief electrical stimulation of the medial septum at 5 to 50 Hz elicited a single brief milk ejection similar to natural reflex milk ejections, whereas prolonged low frequency stimulations (5 to 10 Hz) induced a prolonged inhibition of the reflex. In acute experiments under anaesthesia, lesions of the medial septum did not impair the amplitude and pattern of reflex milk ejections. In chronic experiments, lesions of the medial septum resulted first in a loss of body weight of the mothers and a parallel reduction in growth of the litters. After a few days, the litters gained weight normally, and the pattern of milk ejections was normal. Thus, the pathways which pass through or originate from the medial septum and which are excitatory for oxytocin release appear not to be involved in the regulation of the milk ejection reflex. In view of these results and those from our previous study on the lateral septum, we conclude that the whole septum is not essential to the milk ejection reflex. However, the effects of septal stimulation suggest that the medial and lateral septum may be involved in a secondary neural circuitry that can inhibit the reflex.

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.

Electrophysiological properties of neurones in the region of the paraventricular nucleus in slices of rat hypothalamus

1. Neurones in the region of the hypothalamic paraventricular nucleus (PVN) of the rat were studied with intracellular recording in the coronal slice preparation. Three types of hypothalamic neurones were distinguished according to their membrane properties and anatomical positions. Lucifer Yellow or ethidium bromide was injected intracellularly to determine the morphology of some recorded cells. 2. The most distinctive electrophysiological characteristic was the low-threshold depolarizing potentials which were totally absent in type I neurones, present but variable in type II neurones and very conspicuous in type III neurones. Type II neurones generally showed relatively small low-threshold depolarizations (26.5 +/- 2.2 mV) which generated at most one to two action potentials. Type III neurones, on the other hand, generated large low-threshold potentials (40.3 +/- 2.8 mV) which gave rise to bursts of three to six fast action potentials. Deinactivation of the low-threshold conductance in both type II and type III neurones was voltage- and time-dependent. Low-threshold potentials persisted in TTX (1-3 microM) but were blocked by solutions containing low Ca2+ (0.2 mM) and Cd2+ (0.5 mM), suggesting they were Ca(2+)-dependent. 3. Type I neurones had a significantly shorter membrane time constant (14.5 +/- 1.7 ms) than those of type II (21.6 +/- 1.7 ms) and type III neurones (33.8 +/- 4.4 ms). Input resistance and resting membrane potential did not differ significantly among the cell groups. 4. Current-voltage (I-V) relations were significantly different among the three cell types. Type I neurones had linear I-V relations to -120 mV, while type III neurones all showed marked anomalous rectification. I-V relations among type II neurones were more heterogeneous, although most (75%) had linear I-V curves to about -90 to -100 mV, inward rectification appearing at more negative potentials. 5. Type I neurones generated fast action potentials of relatively large amplitude (64.2 +/- 1.1 mV, threshold to peak) and long duration (1.1 +/- 0.1 ms, measured at half-amplitude); the longer duration was due to a shoulder on the falling phase of the spike. Type II neurones had large spikes (66.5 +/- 1.6 mV) of shorter duration (0.9 +/- 0.1 ms) with no shoulder. Type III neurones had relatively small spikes (56.1 +/- 2.2 mV) of short duration (0.8 +/- 0.1 ms) with no shoulder. 6. The three cell populations showed different patterns of repetitive firing in response to depolarizing current pulses. Type I neurones often generated spike trains with a delayed onset and little spike-frequency adaptation.(ABSTRACT TRUNCATED AT 400 WORDS)

Septal and Hippocampal Release of Oxytocin, but not Vasopressin, in the Conscious Lactating Rat During Suckling

Abstract The central release of both oxytocin and vasopressin within the septum and dorsal hippocampus in response to suckling was studied in conscious, freely-behaving lactating rats. Three consecutive 30-min push-pull perfusions were carried out before, during and after suckling (suckled group) or without suckling (control group). As compared to control levels, suckling resulted in a significantly increased oxytocin release within both limbic brain areas (septum: to 140%, dorsal hippocampus: to 1,600%). After removal of the suckling pups, the oxytocin concentration in the final perfusates remained at the stimulation level (septum) or tended to return to control values (dorsal hippocampus). In contrast to oxytocin, the vasopressin perfusate levels did not differ significantly between unsuckled and suckled rats.

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)

The role of the AV3V region in the control of magnocellular oxytocin neurons

The AV3V region is important in the control of body fluid and Na+ regulation and projects to the supraoptic and paraventricular nuclei. Oxytocin from the neurohypophysis mediates milk ejection and is involved in parturition, but has also been recently implicated as a candidate natriuretic hormone. We have studied the role of the AV3V region in the control of magnocellular oxytocin neurons in rats. Electrical stimulation of the AV3V region increased the firing rate of supraoptic oxytocin neurons and evoked a concomitant release of oxytocin. Acute electrolytic AV3V lesions silenced supraoptic neurons and abolished their excitation by hyperosmotic stimulation. The lesions also abolished osmotically-induced release of oxytocin. Re-activation of supraoptic neurons by local glutamate restored their osmoresponsiveness to about 50% normal. Thus, while supraoptic neurons are directly osmosensitive, the AV3V region is essential for their normal osmoresponsiveness. Electrolytic AV3V lesions did not affect suckling-induced oxytocin secretion or, in conscious rats, the release of oxytocin secretion during parturition. Thus the AV3V region is not involved in the activation of oxytocin neurons during suckling or parturition.

Ionic basis of the differential neuronal activity of guinea-pig septal nucleus studied in vitro

1. The electrical properties and ionic conductances of septal neurones were studied by intracellular recording in an in vitro slice preparation. Within the total number of cells recorded (n = 150) we identified three electrophysiological cell types, each one of them located in a separate septal region. Dorsolateral septal neurones comprised 60% of the cells, intermediate septal neurons 10%, and medical septal neurones 30%. 2. Passive electrical constants of dorsolateral, intermediate and medial septal neurones were, respectively:resting potential (-60.2 +/- 4.8, -59.8 +/- 3.3 and -56 +/- 4.3 mV); input resistance (82.5 +/- 17, 63 +/- 16 and 83 +/- 18 M omega) and membrane time constant (18.5 +/- 7.3, 14.2 +/- 6.8 and 10.7 +/- 3.4 ms). 3. Direct activation of dorsolateral septal neurones by current injection below 0.2 nA triggered repetitive firing of fast action potentials. Larger current pulses elicited a characteristic response consisting of an initial fast action potential followed by a train of slow spikes. An after-hyperpolarization followed termination of the pulse and the characteristic response. 4. In dorsolateral septal neurons tetrodotoxin (TTX) abolished the fast action potentials. The slow spikes and the after-hyperpolarization disappeared in presence of Co2+ or after brief removal of external Ca2+. This suggests that the characteristic response is mediated by Ca2+ and the after-hyperpolarization by a Ca2+-dependent K+ conductance. 5. The firing pattern of intermediate septal neurones activated from the resting potential spontaneously measured in the cells was similar to that of dorsolateral septal neurones; but direct activation from a hyperpolarized membrane potential evoked in intermediate septal cells a bursting response due to the generation of a low-threshold spike. The low-threshold spike was TTX-resistant but abolished by Co2+ and reached a maximal amplitude after hyperpolarization to -75 mV lasting for 100-150 ms. These results suggest the existence in intermediate septal neurons of a low-threshold Ca2+ conductance inactivated at the resting potential and deinactivated by hyperpolarization. 6. Depolarization of medial septal neurons by current pulses of amplitude greater than 0.2-0.3 nA elicited a typical burst of two to six action potentials. The bursts lasted for 20-50 ms and were followed by a marked after-hyperpolarization.(ABSTRACT TRUNCATED AT 400 WORDS)

Extra-hypothalamic afferent inputs to the supraoptic nucleus area of the rat as determined by retrograde and anterograde tracing techniques

To detect neuronal cell bodies whose axon projects to the hypothalamic supraoptic nucleus, small volumes (10-50 nl) of 30% horseradish peroxidase or 2% fast blue solutions were pressure-injected into the area of one supraoptic nucleus of rats. Both dorsal and ventral approaches to the nucleus were used. In animals where the injection site extended beyond the limits of the supraoptic nucleus, retrogradely labelled cell bodies were found in many areas of the brain, mainly in the septum, the nucleus of the diagonal band of Broca and ventral subiculum in the limbic system; the dorsal raphe nucleus, the locus coeruleus, the nucleus of the dorsal tegmentum, the dorsal parabrachial nucleus, the nucleus of the solitary tract and the catecholaminergic A1 region in the brain stem; in the subfornical organ and the organum vasculosum of the lamina terminalis, as well as in the median preoptic nucleus. In contrast, when the site of injection was apparently restricted to the supraoptic nucleus, labelling was only clearcut in the two circumventricular organs, the median preoptic nucleus, the nucleus of the solitary tract and the A1 region. Injections of wheat germ agglutinin coupled with horseradish peroxidase (60-80 nl of a 2.5% solution) made in the septum and in the ventral subiculum anterogradely labelled fibers coursing in an area immediately adjacent to the supraoptic nucleus but not within it. In contrast, labelling within the nucleus was found following anterograde transport of tracer deposited in the A1 region and in an area that includes the nucleus of the solitary tract. Neurones located in the perinuclear area were densely labelled by small injections into the supraoptic nucleus; they may represent a relay station for some afferent inputs to the supraoptic nucleus. These results suggest that the supraoptic nucleus is influenced by the same brain areas which project to its companion within the magnocellular system, the paraventricular nucleus.

Influence of lateral septum and amygdala stimulation on the excitability of hypothalamic supraoptic neurons. An electrophysiological study in the rat

Extracellular recordings were obtained from 116 phasically-active (putative vasopressinergic) and 113 continuously-active (putative oxytocinergic) neurosecretory neurons in the hypothalamic supraoptic nucleus of urethane or pentobarbital anesthetized male Sprague-Dawley rats. Single 1 Hz pulse stimulation in most regions of the amygdala and the ipsilateral lateral septum was followed by a transient (20-140 ms) reduction in the excitability of more than 90% of responsive cells; one third displayed a reduction in excitability to both amygdala and lateral septum stimulation. Amygdala or lateral septum stimuli delivered in brief trains of 20-100 pulses at 5-20 Hz during ongoing phasic discharges could induce silent periods lasting up to 30 or more seconds beyond the time of application. The same stimuli also reduced ongoing activity among continuously-firing SON cells but their response lasted only as long as the duration of the applied stimulus. These data suggest that neurons in both the ipsilateral septum and the various amygdaloid nuclei exert a predominantly inhibitory influence on the excitability of both vasopressinergic and oxytocinergic SON neurons in the rat.