Action of the lateral hypothalamic area on subfornical organ neurons projecting to the supraoptic nucleus in the rat

The activity of all subfornical organ neurons (N = 20) that were antidromically identified by electrical stimulation of the rat hypothalamic supraoptic nucleus region was excited by microiontophoretically applied angiotensin II. Electrical stimulation of the lateral hypothalamic area produced either an excitatory response (N = 12) or no effect (N = 8) in the activity of identified subfornical organ neurons. The excitatory responses to iontophoretically applied angiotensin II or stimulation of the lateral hypothalamic area were blocked by iontophoretically applied saralasin, an antagonist of angiotensin II.     

Subfornical organ efferents influence the activity of median preoptic neurons projecting to the hypothalamic paraventricular nucleus in the rat

Twelve neurons in the median preoptic nucleus were antidromically activated by electrical stimulation of the hypothalamic paraventricular nucleus in the rat. Electrical stimulation of the subfornical organ produced excitation (N = 7) or inhibition (N = 4) of the activity of these identified units. The activity of all identified units that were excited by stimulation of the subfornical organ was also excited by microiontophoretically applied angiotensin II whereas the remaining units were not affected. The excitatory responses of the identified units to subfornical organ stimulation or applied angiotension II were blocked by saralasin, an angiotensin II antagonist.     

Angiotensin II-sensitive neurons in the rat lateral hypothalamic area with efferent projections to the subfornical organ

Thirteen neurons in the lateral hypothalamic area were antidromically activated by electrical stimulation of the subfornical organ in the rat. The activity of almost all identified neurons (N = 11) was excited by microiontophoretically applied angiotensin II. On the other hand, of the antidromically unidentified lateral hypothalamic area neurons (N = 10) tested, 4 were excited by microiontophoretically applied angiotension II and 6 were not affected. The excitatory responses of identified and unidentified lateral hypothalamic area neurons to angiotensin II were blocked by microiontophoretically applied saralasin, an angiotensin II antagonist.     

Angiotensin II may mediate excitatory neurotransmission from the subfornical organ to the hypothalamic supraoptic nucleus: an anatomical and electrophysiological study in the rat

In the rat, it has been proposed that angiotensin II (AII) neurons in the subfornical organ, a midline circumventricular structure, participate in the activation of hypothalamic neurosecretory neurons and promote a rise in plasma vasopressin and oxytocin. In this study, we observed AII-immunoreactive fibers coursing throughout the supraoptic nucleus as well as in other magnocellular cell groups of the hypothalamus. Moreover, following retrograde transport of Fast blue deposited within the supraoptic nucleus, cell counts in our best case revealed that 40% of AII-immunoreactive neurons in subfornical organ contained Fast blue, and 46% of the retrogradely labeled subfornical organ cells contained AII. In separate electrophysiological studies, post-stimulus histograms from 18 of 28 supraoptic neurons displayed a 30-55% reversible reduction in the excitation evoked by an electrical stimulus in the subfornical organ during local pressure applications of 100 microM to 1 mM saralasin. In 2 of 14 other cells, tubocurare (100 microM) produced only a 10% reduction in subfornical organ excitation. These observations indicate that AII may mediate an excitatory input to supraoptic neurons from the subfornical organ.     

Cardiovascular input to hypothalamic neurosecretory neurons

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

Projections from the subfornical organ to the supraoptic nucleus in the rat: ultrastructural identification of an interposed synapse in the median preoptic nucleus using a combination of neuronal tracers.

The subfornical organ, along with other regions of the lamina terminalis, may contain osmoreceptors and is likely to be a site of action of blood-borne angiotensin II. The neural pathways by which these stimuli lead to vasopressin secretion, have been suggested to extend from the subfornical organ to hypothalamic sites of vasopressin production either directly or via synapses in an intervening nucleus such as the median preoptic nucleus. In the present study, cholera toxin conjugated to horseradish peroxidase (CT/HRP) or colloidal gold (CT/Au) has been injected, respectively, into the subfornical organ and supraoptic nucleus of the same animal. The anterograde and retrograde transport of the toxin from these two sites has made possible the identification, at the ultrastructural level, of a synapse in the median preoptic nucleus interposed in the pathway between the subfornical organ and the supraoptic nucleus. Moreover, the presence of retrogradely transported CT/HRP and CT/Au in the same neurone in the median preoptic nucleus indicates that some neurones in this nucleus have axons with collateral branches to both the subfornical organ and supraoptic nucleus. Either or both of these pathways may transmit information related to the tonicity of the blood or circulating levels of angiotensin II to sites in the hypothalamus.     

Lateral hypothalamic area stimulation excites neurons in the region of the subfornical organ with efferent projections to the hypothalamic paraventricular nucleus in the rat

Fifteen neurons in the region of the subfornical organ (SFO) were antidromically activated by electrical stimulation of the paraventricular nucleus (PVN) in the rat. Electrical stimulation of the lateral hypothalamic area (LHA) excited the activity of 9 of the identified units, but did not affect the remaining units. The excitatory response of the identified units was blocked by microiontophoretically (MIPh) applied saralasin (Sar), an angiotensin II (ANGII) antagonist, but not by atropine (Atr), a muscarinic antagonist. These results suggest that the LHA has an excitatory influence on the activity of neurons in the region of the SFO with efferent projections to the PVN and that the influence may be mediated by ANGII receptors.     

Angiotensin II sensitive neurons in the supraoptic nucleus, subfornical organ and anteroventral third ventricle of rats in vitro

The angiotensin II (AII) sensitivity of neurons in the supraoptic nucleus (SON), subfornical organ (SFO) and the region near the anteroventral part of the third ventricle (AV3V) was investigated using extracellular recording in the rat brain slice preparation by adding AII (10(-10)-10(-6) M) to the perfusion medium. Forty seven (44%) of 106 SON neurons, 62 (66%) of 94 SFO neurons and 28 (33%) of 86 AV3V neurons were excited by AII. One cell was inhibited by AII in the SON and one in the SFO. The threshold concentration to evoke responses in the SON neurons was approximately 10(-9) M, but neurons in the SFO and AV3V showed clear excitatory responses to AII at 10(-10) M. In the SON, 18 (40%) of 45 phasic firing neurons (putative vasopressin neurons) and 29 (48%) of 61 nonphasic firing neurons (including putative oxytocin neurons) were excited by AII. The excitatory effect of AII was reversibly antagonized by a specific antagonist saralasin and persisted after synaptic blockade in medium with low [Ca2+] and high [Mg2+]. We conclude that AII can stimulate both vasopressin and oxytocin release, acting directly upon SON neurons and also that both the SFO and AV3V are important receptive sites for AII (although the SFO is relatively more sensitive) which contributes SON input and modulates release of these hormones.     

Role of Anterior Peri-Third Ventricular Structures in the Regulation of Supraoptic Neuronal Activity and Neurohypophysical Hormone Secretion in the Rat

Neurohypophysical hormone release, and the electrical activity of single neurons of the supraoptic nucleus, were monitored in urethane-anaesthetized rats. Immediately after electrolytic lesions of the region anterior and ventral to the third ventricle (AV3V region), supraoptic neurons showed little spontaneous activity and their responses to ip injection of hypertonic saline were severely impaired; corresponding deficits were found in the secretion of both oxytocin and vasopressin. Similar deficits in oxytocin secretion were also found in rats following electrolytic lesions which destroyed all or part of the subfornical organ; however the effects of the lesions were not additive: rats with lesions of both the AV3V region and the subfornical organ region showed a similar degree of impairment of osmotically stimulated oxytocin secretion to rats with lesions of either site alone. Such deficits might occur either as a result of destruction of osmoresponsive projections to the magnocellular nuclei, or as a result of destruction of an afferent input which is essential for the full expression of the innate osmosensitivity of supraoptic neurons. To test the latter possibility, supraoptic neurons in AV3V-lesioned rats were activated by continuous application of glutamate, and then tested with ip injection of hypertonic saline. Five of seven cells tested responded significantly to the hyperosmotic stimulus, though the responses were significantly weaker than observed in sham-lesioned rats. We suggest that the innate osmosensitivity of supraoptic neurons does contribute to their responses to systemic osmotic stimulation, but that expression of this innate osmosensitivity requires inputs from the AV3V region and/or the subfornical organ, some of which may also be osmoresponsive. Electrical stimulus pulses applied to the AV3V region influenced the electrical activity of most supraoptic neurons strongly: the predominant response was a short-latency, short-duration inhibition followed by long-latency, long-duration excitation. Whereas intracerebroventricular administration of the angiotensin II antagonist saralasin reduced spontaneous or osmotically induced activity of supraoptic neurons, the neuronal responses to AV3V stimulation were impaired only with relatively high doses of saralasin. We conclude that angiotensin ll-sensitive neurons are an important component of the afferent pathways that sustain the excitability of supraoptic neurons, but that angiotensin is probably not the major transmitter of the projection from the AV3V region to the supraoptic nucleus.     

Terminal degeneration in supraoptic nucleus following subfornical organ lesions: ultrastructural observations in the rat

A projection from the subfornical organ (SFO) to the supraoptic nucleus, recently identified in light microscopic studies, was examined at the ultrastructural level following lesions in SFO. After 18–36 h, axon terminal degeneration was identified in axosomatic contacts with supraoptic neurosecretory neurons, and in axodendritic contacts within and around the supraoptic nucleus. These observations confirm a monosynaptic pathway from SFO to supraoptic neurosecretory neurons that may participate in the release of vasopressin following activation of angiotensin II receptors in SFO.     

Neuronal effects of neurokinin B on the rat subfornical organ

The subfornical organ is an essential central nucleus for angiotensin II-induced body fluid regulation. Similar to angiotensin II, centrally injected neurokinin B (NKB) may induce cardiovascular responses by the subfornical organ; however, it does not induce water intake. To clarify this inconsistency, we investigated the neuronal effects of NKB on subfornical organ neurons in slice preparations along with its behavioral effects in vivo. In electrophysiological extracellular recordings, NKB excited angiotensin II-insensitive and inhibited angiotensin II-sensitive neurons. Centrally injected NKB inhibited peripherally injected angiotensin II-induced water intake. These results suggest that NKB-mediated neuronal effects on the subfornical organ are likely to be involved in antidipsogenic responses in addition to the previously reported cardiovascular responses.     

Subfornical organ neurons with efferent projections to the hypothalamic paraventricular nucleus: an electrophysiological study in the rat

Seventeen neurons in the subfornical organ (SFO) were antidromically activated by electrical stimulation of the paraventricular nucleus (PVN) in the rat. The activity of all identified SFO neurons was excited by microiontophoretically (MIPh) applied angiotensin II (AII) and the effect of AII was blocked by MIPh-applied saralasin (Sar), an AII antagonist, but not by atropine (Atr), a muscarinic antagonist. In these identified SFO neurons, 9 were also excited and 8 were not affected by MIPh-applied acetylcholine (ACh) and the effect of ACh was attenuated by not only MIPh-applied Atr but also by Sar. These results suggest that there are specific AII- and both AII- and ACh-sensitive types of SFO neurons with efferent projections to the PVN.     

Electrophysiology of the subfornical organ and its hypothalamic connections—an in-vivo study in the rat

The connections of the subfornical organ to a defined population of hypothalamic neurons have been explored with extracellular recording methods in the rat. Electrical stimulation in the subfornical organ has a predominantly excitatory action on a majority of oxytocin and vasopressin-secreting neurosecretory neurons in the supraoptic and paraventricular nuclei. Subfornical organ stimulation also enhances the excitability of paraventricular nucleus neurons that project to the median eminence, and to the dorsomedial medulla. These observations provide initial evidence of functional connectivity of subfornical organ neurons with other hypothalamic cells that are engaged in central regulation of pituitary secretions and autonomic activities.     

Responses of subfornical organ neurons projecting to the hyphotalamic paraventricular nucleus to hemorrhage

The activity of subfornical organ (SFO) neurons that were antidromically identified by electrical stimulation of the rat hypothalamic paraventricular nucleus (PVN) was tested for a response to microiontophoretic application of angiotensin II (ANG II) or hemorrhage (10 ml/kg b.v.t.). Microiontophoretically (MIPh) applied ANG II caused an increased excitability in 24 out of 28 neurons tested and the excitation was blocked by MIPh-applied saralasin (Sar), a specific ANG II antagonist. Of these neurons that responded to ANG II, 14 displayed an increase in neuronal firing in response to hemorrhage, while 10 were unresponsive. The excitatory response to hemorrhage in 5 out of 14 neurons tested was prevented by MIPh-applied Sar, whereas the response of the remaining neurons was not affected. These results show that part of SFO neurons projecting to the PVN may receive neural inputs from the peripheral baroreceptors, and suggest that the inputs may be partially attributable to the involvement of central angiotensinergic circuits.     

The median preoptic nucleus participates in the control of paraventricular vasopressin neurons by the subfornical organ in the rat

Extracellular single-unit activity was recorded from phasically firing neurohypophyseal neurons (n = 41) in the hypothalamic paraventricular nucleus (PVN) of urethane-anesthetized male rats. Electrical stimulation of the subfornical organ (SFO) produced orthodromic long-duration (n = 18) or short-duration (n = 10) excitation or inhibition (n = 8) of the activity of PVN neurons. The long-duration excitatory response of about half (n = 7) the neurons (n = 15) tested was reversibly abolished by microinjection of the local anesthetic lidocaine into the median preoptic nucleus (MnPO), whereas neither the short-duration excitatory (n = 7) nor inhibitory (n = 6) responses were affected. These results suggest that the SFO efferents through the MnPO to the PVN may transmit the neuromodulatory signals which evoke long-duration increases in the excitability of putative vasopressin (VP)-secreting neurons in the PVN.     

Endothelin acts at the subfornical organ to influence the activity of putative vasopressin and oxytocin-secreting neurons

Systemic endothelin-1 (ET-1) enhances the activity of subfornical organ (SFO) neurons with identified projections to the paraventricular nucleus of the hypothalamus (PVN). The present electrophysiological experiments were undertaken to examine the mechanisms through which systemic ET influences vasopressin secretion. Systemic ET-1 (50-100 pmol) was found to influence the excitability of antidromically identified vasopressin and oxytocin-secreting neurons in the PVN or supraoptic nucleus (SON) of urethane-anaesthetized rats. Long-term stable recordings from 95 antidromically identified neurons showed 56% of putative vasopressin- (n = 41), and 37% of putative oxytocin- (n = 54) secreting neurons were activated by ET-1. Such effects normally demonstrated a short latency (less than 10 s), with a duration ranging between 10 and 300 s. In contrast, unidentified neurons in the vicinity of PVN and SON (n = 27) were unaffected by ET-1. The inability of peptides to cross the normal blood-brain barrier suggested that such effects of ET-1 result from actions of this peptide at the SFO which lacks this barrier and sends efferent neural projections to both SON and PVN. This hypothesis was tested by obtaining similar recordings from animals in which this structure was destroyed prior to experimentation. In these studies recordings from 15 putative vasopressin- and 29 putative oxytocin-secreting neurons showed that only 7% and 14%, respectively, were excited by systemic ET-1 in lesioned animals. These data show that increases in circulating levels of ET have predominantly excitatory effects on vasopressin- and oxytocin-secreting neurons in SON and PVN. The modified responsiveness of these neurons to ET-1 in SFO-lesioned animals suggests this as a likely CNS site at which this peptide acts within the central nervous system to elicit such effects.     

Circulating angiotensin II activates neurones in circumventricular organs of the lamina terminalis that project to the bed nucleus of the stria terminalis

The aim of this study was to determine, in conscious rats, whether elevated concentrations of circulating angiotensin II activate neurones in both the subfornical organ and organum vasculosum of the lamina terminalis (OVLT) that project to the bed nucleus of the stria terminalis (BNST). The strategy employed was to colocalize retrogradely transported cholera toxin B subunit (CTB) from the BNST, with elevated levels of Fos protein in response to angiotensin II. Circulating angiotensin II concentrations were increased by either intravenous infusion of angiotensin II or subcutaneous injection of isoproterenol. Neurones exhibiting Fos in response to angiotensin II were present in the subfornical organ, predominantly in its central core but with some also seen in its peripheral aspect, the dorsal and lateral margins of the OVLT, the supraoptic nucleus and the parvo- and magnocellular divisions of the paraventricular nucleus. Fos-labelling was not apparent in control rats infused with isotonic saline intravenously or injected with either CTB or CTB conjugated to gold particles (CTB-gold) only. Of the neurones in the subfornical organ that were shown by retrograde labelling to project to BNST, approximately 50% expressed Fos in response to isoproterenol. This stimulus also increased Fos in 33% of neurones in the OVLT that project to BNST. Double-labelled neurones were concentrated in the central core of the subfornical organ and lateral margins of the OVLT in response to increased circulating angiotensin II resulting from isoproterenol treatment. These data support a role for circulating angiotensin II acting either directly or indirectly on neurones in subfornical organ and OVLT that project to the BNST and provide further evidence of functional regionalization within the subfornical organ and the OVLT. The function of these pathways is yet to be determined; however, a role in body fluid homeostasis is possible.     

Autoradiographic localization of angiotensin receptors in the sheep brain

Binding of [125I]-(Sar1,Ile8)angiotensin II (AII) to frozen sections of sheep brain was determined by in vitro autoradiography. Greatest AII-binding occurred in the organum vasculosum of the lamina terminalis, subfornical organ, median preoptic and periventricular nuclei situated in the anterior third ventricle wall. Other binding sites included the hypothalamic supraoptic and paraventricular nuclei and the medullary nucleus tractus solitarius. These regions may be central receptor sites for AII involvement in fluid and electrolyte balance and blood pressure regulation.     

Localization of angiotensin II receptor binding in rabbit brain by in vitro autoradiography

Binding of 125I-[Sar1,Ile8] angiotensin II (AII) to sections of brains from both wild and laboratory rabbits was determined by in vitro autoradiography. In the forebrain, specific high density binding was observed in the olfactory bulb, organum vasculosum of the lamina terminalis (OVLT), subfornical organ, median eminence, lateral septum, median preoptic nucleus and hypothalamic paraventricular, supraoptic and arcuate nuclei. In the midbrain, binding of the radioligand was observed in the interpeduncular and parabrachial nuclei, in the locus coeruleus, and ventrolateral pons. In the hind brain, there was dense binding of 125I-[Sar1,Ile8] AII to the nucleus of the solitary tract (NTS) and to both rostral and caudal parts of the reticular formation of the ventrolateral medulla oblongata. Weaker specific binding of the radioligand to the molecular layer of the cerebellum, to the nucleus of the spinal trigeminal tract, dorsal motor nucleus of the vagus, area postema, and to a band of tissue connecting the NTS to the ventrolateral medulla was also observed. Binding of the ligand to circumventricular organs such as the OVLT, subfornical organ, and median eminence suggests that these are sites in the brain of the rabbit at which blood-borne AII may exert influences on the central regulation of fluid balance and pituitary hormone secretion, although AII of neuronal origin could also act at these sites. Binding of the radioligand in several other brain regions suggests that angiotensin II of cerebral origin may be involved in a number of different aspects of brain function in the rabbit. The finding of dense binding in the NTS and ventrolateral medulla, which are involved in autonomic activity and are also sites of catecholamine-containing neurons, raises the possibility of angiotensin interaction with these neurons and involvement in autonomic function.     

Neurons in the median preoptic nucleus of the rat with collateral branches to the subfornical organ and supraoptic nucleus.

A novel pathway between the subfornical organ and the supraoptic nucleus involving the collateral branches of cell bodies situated in the lamina terminalis has been studied. Fluorogold was injected into the supraoptic nucleus and rhodamine-labelled microspheres into the subfornical organ of rats. Nineteen % of neurons in the median preoptic nucleus and 30% of neurons in the OVLT projecting to the subfornical organ also had axons extending to the supraoptic nucleus. These pathways may represent a novel trajectory for the rely of information from the lamina terminalis to the supraoptic nucleus.