Neurohypophysial hormones: neuronal effects in autonomic and limbic areas of the rat brain

Neuromodulatory functions exerted by oxytocin on different populations of hippocampal neurons in rodents

Oxytocin (OT) is a neuropeptide widely known for its peripheral hormonal effects (i.e., parturition and lactation) and central neuromodulatory functions, related especially to social behavior and social, spatial, and episodic memory. The hippocampus is a key structure for these functions, it is innervated by oxytocinergic fibers, and contains OT receptors (OTRs). The hippocampal OTR distribution is not homogeneous among its subregions and types of neuronal cells, reflecting the specificity of oxytocin's modulatory action. In this review, we describe the most recent discoveries in OT/OTR signaling in the hippocampus, focusing primarily on the electrophysiological oxytocinergic modulation of the OTR-expressing hippocampal neurons. We then look at the effect this modulation has on the balance of excitation/inhibition and synaptic plasticity in each hippocampal subregion. Additionally, we review OTR downstream signaling, which underlies the OT effects observed in different types of hippocampal neuron. Overall, this review comprehensively summarizes the advancements in unraveling the neuromodulatory functions exerted by OT on specific hippocampal networks.

Activation of Oxytocin Receptors Excites Subicular Neurons by Multiple Signaling and Ionic Mechanisms

Oxytocin (OXT) is a nonapeptide that serves as a neuromodulator in the brain and a hormone participating in parturition and lactation in the periphery. The subiculum is the major output region of the hippocampus and an integral component in the networks that process sensory and motor cues to form a cognitive map encoding spatial, contextual, and emotional information. Whilst the subiculum expresses the highest OXT-binding sites and is the first brain region to be activated by peripheral application of OXT, the precise actions of OXT in the subiculum have not been determined. Our results demonstrate that application of the selective OXT receptor (OXTR) agonist, [Thr4,Gly7]-oxytocin (TGOT), excited subicular neurons via activation of TRPV1 channels, and depression of K+ channels. The OXTR-mediated excitation of subicular neurons required the functions of phospholipase Cβ, protein kinase C, and degradation of phosphatidylinositol 4,5-bisphosphate (PIP2). OXTR-elicited excitation of subicular neurons enhanced long-term potentiation via activation of TRPV1 channels. Our results provide a cellular and molecular mechanism to explain the physiological functions of OXT in the brain.

Neurohypophysial peptides: gatekeepers in the amygdala

A recent paper by Huber, Veinante and Stoop reports electrophysiological studies in slices of the amygdala in which the authors are able to demonstrate a cellular and spatial dissociation between the sites of action of oxytocin and vasopressin. These studies are important for determining how these brain peptides might gate autonomic responses to fear and other emotional stimuli.

Vasopressin-induced intracellular Ca2+ increase in isolated rat supraoptic cells

1. The intracellular Ca2+ concentration ([Ca2+]1) was monitored in single magnocellular neurones freshly isolated from rat supraoptic nucleus. Application of 100 nM vasopressin increased [Ca2+]1. Two types of [Ca2+]1 responses were observed: (i) a transient response, displayed by 86% of the vasopressin-sensitive neurones, and (ii) a sustained response displayed by 14% of the vasopressin-sensitive neurones. 2. Among responding neurones, 52% were vasopressin sensitive, 44% were oxytocin sensitive and 4% were sensitive to both peptides. 3. Responses to vasopressin were dose dependent, showed a progressive desensitization after successive applications, were specifically blocked by the V1a vasopressin receptor antagonist, SR 49059, and were unaffected by the oxytocin receptor antagonist, d(CH2)5OVT. 4. Vasopressin responses were completely suppressed by the removal of external Ca2+. 5. The intracellular Ca2+ mobilizers, caffeine and tBuBHQ, did not affect resting or vasopressin-induced [Ca2+]1 changes. Thapsigargin (200 nM) on its own evoked an increase in [Ca2+]1, and reduced the [Ca2+]1 increase evoked by vasopressin by 52%, suggesting that thapsigargin-sensitive Ca2+ stores are partially involved in the vasopressin response. 6. Immunocytochemical identification revealed that vasopressin-responding neurones synthesize vasopressin whereas oxytocin-responding neurones synthesize oxytocin. 7. In conclusion, vasopressin- (partially external Ca2+ dependent) and oxytocin (totally external Ca2+ independent)-induced [Ca2+]1 changes are mediated by specific receptors. In addition, vasopressin and oxytocin neurones are specifically autoregulated by their own peptides.

Ontogeny of oxytocin-like immunoreactivity in the Brazilian opossum brain

The neuropeptide oxytocin (OT) has been shown to function as a neurotransmitter and/or neuromodulator in addition to its hormonal function in the periphery in the adult central nervous system (CNS). Previously, we have studied the postnatal neurogenesis of the paraventricular and supraoptic nuclei and ontogeny of arginine vasopressin-like immunoreactivity in the Brazilian opossum brain, Monodelphis domestica. In this study, we have described the ontogeny of oxytocin-like immunoreactivity (OT-IR) in the opossum brain. As a marsupial, opossum pups are in an extremely immature state, with neurogenesis and morphogenesis continuing into the second week of postnatal life. Thus, opossum pups are a good model for developmental studies. In the adult opossum brain, OT-IR was localized in regions as reported for the adult rat and other species, except for a few differences. These findings suggest similar functional roles for OT in the adult opossum brain as in other mammals. Unlike the prenatal expression of arginine vasopressin, OT-IR was first detected in the forming median eminence on day 1 of postnatal life (1 PN). Between 3 and 5 PN, OT-IR was present in the hypothalamic supraoptic and paraventricular nuclei and posterior pituitary. At this time, neurogenesis of these nuclei is not completed. By 10 to 15 PN, OT-IR was seen in several brain areas, and begins to resemble that of the adult between 45 and 60 PN. These results indicate that the time course of appearance of the OTnergic system does not directly parallel the early expression of the vasopressinergic system. However, the expression of OT-IR in the opossum brain before neurogenesis and morphogenesis is completed suggests a potential role for OT in developmental events. Similar to arginine vasopressin, oxytocin may also be involved in the regulation of autonomic functions that are essential for the opossum's adaptation to an ex utero environment. Future studies utilizing experimental manipulations of the OTnergic system will help determine the significance of this peptide in the neonatal opossum.

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.

Electrophysiological actions of oxytocin in the dorsal vagal complex of the female rat in vitro: changing responsiveness during the oestrous cycle and after steroid treatment

The effect of the oxytocin-specific agonist Thr4,Gly7-oxytocin (TGOT) was tested on neurones in tissue slices of the dorsal vagal complex, obtained from virgin female rats at different stages of the oestrous cycle. The proportion of neurones excited by TGOT (0.1 microM) was independent of the day of the cycle, but both the basal activity and magnitude of response induced by TGOT were significantly reduced on the day of oestrus by comparison with dioestrus. This was due to a small but significant shift in the dose-response relationship. The magnitude of the excitation of neurones obtained from animals at proestrus did not differ significantly from either oestrus or dioestrus, but lay between the two. Ovariectomy 6 days prior to recording reduced the proportion of responsive neurones (35% vs. 69% at dioestrus), but had only a small effect on the amplitude of the averaged responses. Daily injection of 10 micrograms oestradiol benzoate had no additional effect on the proportion of responsive neurones (40%), but caused a marked suppression of the amplitude of the response at all doses (change in firing rate caused by 0.1 microM: 1.68 +/- 0.27 Hz vs. 2.69 +/- 0.39 Hz). In contrast, injections of 5 mg progesterone caused a small increase in the amplitude of the response. The data show that ovarian steroids have a marked effect on oxytocin-sensitive neurones of the dorsal vagal complex, causing dynamic changes in responsiveness over the oestrous cycle. This is discussed with respect to the effects of ovarian steroids on central oxytocin receptors and the possible involvement in regulating autonomic functions.