Effects of angiotensin II on central neurons

Angiotensin receptor subtype mediated physiologies and behaviors: new discoveries and clinical targets

The renin-angiotensin system (RAS) mediates several classic physiologies including body water and electrolyte homeostasis, blood pressure, cyclicity of reproductive hormones and sexual behaviors, and the regulation of pituitary gland hormones. These functions appear to be mediated by the angiotensin II (AngII)/AT(1) receptor subtype system. More recently, the angiotensin IV (AngIV)/AT(4) receptor subtype system has been implicated in cognitive processing, cerebroprotection, local blood flow, stress, anxiety and depression. There is accumulating evidence to suggest an inhibitory influence by AngII acting at the AT(1) subtype, and a facilitory role by AngIV acting at the AT(4) subtype, on neuronal firing rate, long-term potentiation, associative and spatial learning, and memory. This review initially describes the biochemical pathways that permit synthesis and degradation of active angiotensin peptides and three receptor subtypes (AT(1), AT(2) and AT(4)) thus far characterized. There is vigorous debate concerning the identity of the most recently discovered receptor subtype, AT(4). Descriptions of classic and novel physiologies and behaviors controlled by the RAS are presented. This review concludes with a consideration of the emerging therapeutic applications suggested by these newly discovered functions of the RAS.

Neural plasticity and the brain renin-angiotensin system

The brain renin-angiotensin system mediates several classic physiologies including body water balance, maintenance of blood pressure, cyclicity of reproductive hormones and sexual behaviors, and regulation of pituitary gland hormones. In addition, angiotensin peptides have been implicated in neural plasticity and memory. The present review initially describes the extracellular matrix (ECM) and the roles of cell adhesion molecules (CAMs), matrix metalloproteinases, and tissue inhibitors of metalloproteinases in the maintenance and degradation of the ECM. It is the ECM that appears to permit synaptic remodeling and thus is critical to the plasticity that is presumed to underlie mechanisms of memory consolidation and retrieval. The interrelationship among long-term potentiation (LTP), CAMs, and synaptic strengthening is described, followed by the influence of angiotensins on LTP. There is strong support for an inhibitory influence by angiotensin II (AngII) and a facilitory role by angiotensin IV (AngIV), on LTP. Next, the influences of AngII and IV on associative and spatial memories are summarized. Finally, the impact of sleep deprivation on matrix metalloproteinases and memory function is described. Recent findings indicate that sleep deprivation-induced memory impairment is accompanied by a lack of appropriate changes in matrix metalloproteinases within the hippocampus and neocortex as compared with non-sleep deprived animals. These findings generally support an important contribution by angiotensin peptides to neural plasticity and memory consolidation.

Extracellular matrix molecules, long-term potentiation, memory consolidation and the brain angiotensin system

Considerable evidence now suggests an interrelationship among long-term potentiation (LTP), extracellular matrix (ECM) reconfiguration, synaptogenesis, and memory consolidation within the mammalian central nervous system. Extracellular matrix molecules provide the scaffolding necessary to permit synaptic remodeling and contribute to the regulation of ionic and nutritional homeostasis of surrounding cells. These molecules also facilitate cellular proliferation, movement, differentiation, and apoptosis. The present review initially focuses on characterizing the ECM and the roles of cell adhesion molecules (CAMs), matrix metalloproteinases (MMPs) and tissue inhibitors of metalloproteinases (TIMPs), in the maintenance and degradation of the ECM. The induction and maintenance of LTP is described. Debate continues over whether LTP results in some form of synaptic strengthening and in turn promotes memory consolidation. Next, the contribution of CAMs and TIMPs to the facilitation of LTP and memory consolidation is discussed. Finally, possible roles for angiotensins, MMPs, and tissue plasminogen activators in the facilitation of LTP and memory consolidation are described. These enzymatic pathways appear to be very important to an understanding of dysfunctional memory diseases such as Alzheimer's disease, multiple sclerosis, brain tumors, and infections.

Ethanol affects hypothalamic neurons projecting to the hippocampus and inhibits dentate granule cell LTP

In previous studies we demonstrated that ethanol inhibition of hippocampal granule cell long-term potentiation (LTP) is mediated by angiotensin II (AII), and the inhibition can be blocked by losartan, a specific AII receptor antagonist. The purpose of the present study was to demonstrate that this low-dose ethanol inhibition of dentate granule cell LTP induction is mediated by lateral hypothalamic (LH) afferents that project to the granule cells. In urethane anesthetized rats, we compared the effects of ethanol infusion, 6.0 microliter/30 min, by means of an open-ended push-pull type cannula, in both the LH and the dentate gyrus, on dentate granule cell LTP. Results demonstrate a dose-dependent inhibition of LTP induction when the LH is perfused that can be blocked by losartan, 10 mg/kg i.p.. Four doses of ethanol were used: 5, 10, 20, and 30 mM. There was no effect when the dentate gyrus was infused with 30 mM ethanol and normal granule cell LTP was observed. Also, these results demonstrate for the first time a low-dose ethanol effect on a physiological function, LTP in a specific neural pathway, directly related to the anterograde amnesia produced by ethanol on short-term memory. Therefore, these data support our hypothesis that ethanol inhibition of LTP induction at the medial perforant path-granule cell synapse can be attributed to a presynaptic release of AII and cannot be explained in terms of a direct postsynaptic effect on the granule cells.

Lateral hypothalamic stimulation inhibits dentate granule cell LTP: direct connections

We discovered that angiotensin II (Ang II) applied directly to the dentate gyrus inhibited LTP induction in medial perforant path-dentate granule cell synapses and that the inhibition can be blocked by losartan, an Ang II AT1 receptor specific antagonist. In the first part of this study we found that electrical stimulation of the lateral hypothalamus (LH) inhibits LTP in these synapses and the inhibition can be blocked by pretreating the animals with losartan, indicating that LH angiotensin-containing neurons project to the dentate gyrus. Results of the second part of the study demonstrate clearly that some angiotensin-containing LH neurons project directly to dentate granule cells. LH neurons were identified by retrograde tracers applied to the granule cell layer. Double-labeled neurons containing angiotensin and HRP were sparsely distributed and both fusiform and multipolar LH neurons appeared in a small cluster lateral and ventral to the fornix at the level of the paraventricular nucleus. Large numbers of angiotensin staining neurons were observed in the hypothalamus. Results support our hypothesis that some angiotensin containing LH neurons project directly to the dentate gyrus.

The neuronal role of angiotensin II in thirst, sodium appetite, cognition and memory

Within the past two decades, a great deal has been learnt about the renin-angiotensin system in the brain. The renin-angiotensin system is one of the best-studied enzyme-neuropeptide systems in the brain. The diversity of localization of this peptide throughout the brain has implied a variety of potential functions. Besides its classical role in the regulation of blood pressure and body-fluid homeostasis, it has more subtle functions involving complex mechanisms such as learning and memory. The profound effects on behaviour produced by angiotensin are of broad interest to neuroscientists. The mechanisms of action differ depending on whether angiotensin is locally synthesized and whether regulation is governed by neural or metabolic inputs impinging on the neurones. Its central action is mediated through peptidergic receptors present on neurones. The description of the receptor subtypes AT1 and AT2 for angiotensin II and the development of non-peptidic specific angiotensin receptor subtype antagonists have opened a new area in this field of research. The AT1 site, which preferentially binds to angiotensin II and angiotensin III, appears to mediate the classical angiotensin functions concerned with maintenance of blood pressure and body-fluid control. In addition, most of the behavioural effects described so far are linked with AT1, although so-called psychotropic effects are presumed to be mediated by receptor systems other than the known specific angiotensin receptors. In fact, evidence for the existence of such receptors with high-affinity binding has been reported. The central action of angiotensin II mediated by AT2 is as yet unclear. Most reports concerning this receptor subtype suggest a role in differentiation and development, since the number of binding sites is higher in fetal and young rats than in adults. Furthermore, the neuronal effect of angiotensin II in the inferior olivary nucleus which is blocked specifically by AT2 antagonists suggests an involvement in motor control. Over the next few years we should find answers to many of the questions currently unanswered about angiotensin function and, given the rapid progress in research on this neuropeptide, it may serve as a model for the action of peptides on neuronal function in general.

Impaired retention by angiotensin II mediated by the AT1 receptor

We demonstrated previously that hippocampal dentate gyrus neurons were sensitive to angiotensin II (AII) and recently discovered that AII applied directly to the dentate gyrus inhibited granule cell long-term potentiation induction and that the inhibition is mediated by the AT1 receptor and can be blocked by losartan, a specific AT1 antagonist. The purpose of the present study was to examine the effects of AII administered directly to the dentate gyrus, 1, 5, 50, 150, and 300 ng, on the retention of an inhibitory shock avoidance response and to determine if the resultant impairment of retention can be blocked by losartan. A total of 12 groups of rats in three experiments were studied. Three independent repetitions of 5 ng AII administered bilaterally to the dentate gyrus demonstrate a clear impairment of retention under these experimental conditions and that the impairment can be effectively prevented by pretreatment with 20 mg/kg of losartan IP.

Ascorbic acid concentration in the lateral hypothalamus is related to plasma osmolality

Microdialysis was used to measure extracellular ascorbic and uric acid concentrations in the lateral hypothalamus of water-restricted rats as they drank distilled water or 1.5% NaCl. Other water-restricted rats, not implanted with microdialysis probes, were decapitated 2 h after beginning to drink these fluids. Rats were inverted and their blood was collected for measurements of plasma osmolality and percent hematocrit. Results showed that drinking distilled water produced a significant increase in the ascorbic acid concentration but not in the uric acid concentration. Drinking 1.5% NaCl produced a significant decrease in the uric acid concentration but not in the ascorbic acid concentration. Drinking distilled water decreased mean osmolality from 306.0 to 291.5 mOsm/kg, whereas drinking 1.5% NaCl maintained mean osmolality at water-restricted levels. These results indicate that the extracellular fluid concentration of ascorbic acid in the lateral hypothalamus rises in response to a fall in plasma osmolality.

Dose and time dependency of angiotensin II inhibition of hippocampal long-term potentiation

We previously reported that injection of 1.0 microliter of 4.78 microM angiotensin II (AII) above the hippocampus in rats inhibits long-term potentiation (LTP) induction in medial perforant path-stimulated dentate granule cells. The present experiments were conducted in urethane-anesthetized Sprague-Dawley rats. LTP was measured in terms of the relative change in slope of the population EPSP compared to baseline. Effects of 0.48, 0.956, 1.195, 2.39, and 4.78 microM AII and time delays of 30, 60, 90, and 150 min with the 4.78 microM dose were determined. Results were significant and demonstrate that AII inhibition of LTP in dentate granule cells is both dose and time dependent. The threshold is approximately 1.0 pmol of peptide. Inhibition due to the 4.78 microM AII begins slowly after 1 h and is complete over the next 30 min, continues for another 30 min, and then fully recovers by the end of the next 30 min. This time dependency could be due to the internalization of the AII, interaction with a cytosolic receptor, and eventual degradation.

Angiotensin II depresses glutamate depolarizations and excitatory postsynaptic potentials in locus coeruleus through angiotensin II subtype 2 receptors

A previously reported depression of glutamate responses by angiotensin II was investigated to define the nature of this neuromodulatory effect. Studies were carried out in an vitro brain slice preparation containing the locus coeruleus, using intracellular recordings, and iontophoretic, micropressure and bath perfusion methods for application of drugs. The angiotensin action was found to be blocked by a non-peptide antagonist specific for the angiotensin type 2 receptor, and not by an antagonist selective for the type 1 receptor. Excitatory postsynaptic potentials mediated primarily by excitatory amino acids were also depressed by angiotensin II. The angiotensin II depressions of glutamate were shown to be strong and highly specific. The low effectiveness of bath-applied compared with iontophoretically or micropressure-applied angiotensin II was found to be at least partly explained by a rapid degradation by peptidases. Ammonium ions and hydrogen ions were also able to depress glutamate responses, but these effects were not specific for locus coeruleus neurons and were mediated independently of the angiotensin actions. Strong depression by angiotensin II of excitatory postsynaptic potentials as well as exogenously applied glutamate strengthens the strong possibility of a physiological role for this neuromodulatory mechanism. The identification of the type 2 angiotensin receptor subtype as the mediator of this effect indicates a novel functional role for this receptor, since previously recognized functions of angiotensin II in the brain, such as vascular and body fluid regulation, have been associated with the type 1 receptor.

Role of angiotensin II and AT1 receptors in hippocampal LTP

Results of a previous study showed that angiotensin II (AII) inhibited the induction of long-term potentiation (LTP) in hippocampal granule cells in response to dorsomedial perforant path stimulation in urethane-anesthetized rats. The results of present experiments demonstrate a dose-dependent inhibition of LTP induction under the same conditions due to ethanol (EtOH) administered by stomach tube and diazepam (DZ) injected IP. The inhibition of LTP induction by EtOH and DZ can be blocked by saralasin (SAR) applied directly to the dorsal hippocampus and by lorsartan (DuP 753) administered IP. Lorsartan or a metabolite crosses the blood-brain barrier because it also blocks the inhibition of LTP induction due to AII administration directly into the dorsal hippocampus. Lorsartan is a competitive antagonist of the AT1 subtype AII receptor. Therefore, the AII and the EtOH and DZ inhibition of LTP induction are mediated by the AII subtype receptor AT1. AIII and the AT2 antagonist PD123319 did not produce any significant effects. These in vivo effects can be reproduced in brain slices and therefore cannot be attributed to other factors, such as the urethane. In addition, electrical stimulation of the lateral hypothalamus (LH) inhibits LTP induction, and the inhibition can be blocked by SAR. These data on LH stimulation indicate that LH AII-containing neurons send axons into the hippocampus that inhibit the induction of LTP. These results not only provide new information on a neurotransmitter involved in the amnesic effects of benzodiazepines and ethanol-induced memory blackouts, but also testable hypotheses concerning recent observations that angiotensin converting enzyme (ACE) inhibitors elevate mood and improve certain cognitive processes in the elderly.

Regulatory role of brain angiotensins in the control of physiological and behavioral responses

Considerable evidence now indicates that a separate and distinct renin-angiotensin system (RAS) is present within the brain. The necessary precursors and enzymes required for the formation and degradation of the biologically active forms of angiotensins have been identified in brain tissues as have angiotensin binding sites. Although this brain RAS appears to be regulated independently from the peripheral RAS, circulating angiotensins do exert a portion of their actions via stimulation of brain angiotensin receptors located in circumventricular organs. These circumventricular organs are located in the proximity of brain ventricles, are richly vascularized and possess a reduced blood-brain barrier thus permitting accessibility by peptides. In this way the brain RAS interacts with other neurotransmitter and neuromodulator systems and contributes to the regulation of blood pressure, body fluid homeostasis, cyclicity of reproductive hormones and sexual behavior, and perhaps plays a role in other functions such as memory acquisition and recall, sensory acuity including pain perception and exploratory behavior. An overactive brain RAS has been identified as one of the factors contributing to the pathogenesis and maintenance of hypertension in the spontaneously hypertensive rat (SHR) model of human essential hypertension. Oral treatment with angiotensin-converting enzyme inhibitors, which interfere with the formation of angiotensin II, prevents the development of hypertension in young SHR by acting, at least in part, upon the brain RAS. Delivery of converting enzyme inhibitors or specific angiotensin receptor antagonists into the brain significantly reduces blood pressure in adult SHR. Thus, if the SHR is an appropriate model of human essential hypertension (there is controversy concerning its usefulness), the potential contribution of the brain RAS to this dysfunction must be considered during the development of future antihypertensive compounds.

Angiotensin and sodium interaction in the organum cavum pre-lamina terminalis: electrophysiological and drinking responses

Recording from single neurons in the rostral juxta-cerebroventricular areas, previous investigations in this laboratory failed to find neurons responding to iontophoretic application of both angiotensin II and Na+ in an additive or in a synergistic way. We are now describing such neurons found along the walls of the organum cavum pre-lamina terminalis (O.C.P.L.T.), a recently described structure. In another experiment, angiotensin II microinjections into this hollow O.C.P.L.T. in freely moving rats elicited drinking responses that were blocked whenever the vehicle contained no Na+. Although a critical concentration of Na+ seems to play a permissive role in the dispogenic action of angiotensin within the O.C.P.L.T., various concentrations of NaCl with angiotensin II did not alter the drinking response to angiotensin II itself, and hypertonic NaCl was not dipsogenic by itself in this area.

Angiotensin II receptors in the lumbar spinal cord of the rat

Locations of cells responsive to microiontophoretically applied angiotensin II (AII) were compared to distributions of AII receptor binding sites identified by autoradiography in the lumbar enlargement region of the rat spinal cord. Angiotensin II receptor binding sites were densely concentrated in the superficial layers of the dorsal horn. Considerably lower densities of binding sites were present in the remaining gray matter. Effects of microiontophoretically applied AII on lumbar spinal cord cells did not vary with location within the gray matter. AII facilitated firing of most cells in the lumbar cord whether the cells were in superficial or deeper laminae of the dorsal horn or in the ventral horn. The distribution of AII binding sites and the distribution of cells that were responsive to AII suggest that AII may play a role in modulating both sensory and motor functions of the spinal cord.

Improved immunohistochemical staining of angiotensin II in rat brain using affinity purified antibodies

Recent immunohistochemical studies that have sought to detect angiotensin II/III (AII/AIII) immunoreactive material in the brain have been forced to rely on a small number of antisera because most AII/AIII antibodies have unexplainably proved unsuitable for immunohistochemistry. Although extremely useful tools, these antisera have suffered from high background staining. The purpose of this study was to re-examine and characterize the staining using the most popular AII/AIII antiserum (Denise) before and after purification on an AII CH-sepharose affinity column. The use of crude AII/AIII antiserum resulted in the staining of large varicosities and cell bodies. Fibres were all but invisible owing to extensive background staining. In contrast, the purified antibodies yielded little background staining and produced a discrete staining of AII/AIII fibres with small varicosities in the paraventricular-hypophysial pathway and of cell bodies of large hypothalamic neurones. In addition punctate staining demarcated the perikarya of some neurones and resembled boutons containing immunoreactive AII/AIII. Biochemical and histochemical analysis of the crude antiserum, the affinity purified antibodies and other fractions off the sepharose column demonstrated that a large portion of the total staining (various types of background) seen with crude antiserum and column fractions was not to AII/AIII or several angiotensin-derived fragments. Furthermore, successful preabsorption blanks for the purified antibodies could only be achieved with AII coupled through its N-terminal, suggesting that these purified antibodies reacted best with conjugated angiotensin in the fixed tissue. In total the results of this study indicate that the background staining seen with crude antiserum is not to AII/AIII. The use of affinity purified antibodies greatly enhances resolution, enabling one to visualise even small fibres in rats not treated with colchicine, and should improve our ability to develop accurate maps of central angiotensinergic pathways.

Intrathecally administered angiotensin II increases sympathetic activity in the rat

The possibility that angiotensin II (AII) functions as an excitatory transmitter on sympathetic preganglionic neurones was tested in anaesthetized rats. Drugs were administered intrathecally whilst recording blood pressure, heart rate and sympathetic activity in splanchnic or renal nerves. Intrathecal AII (20 microliters, 10(-5) M) caused a significant increase in blood pressure of 13% +/- 3 and in sympathetic activity of 15% +/- 5. Intrathecal AII (20 microliters, 10(-3) M) caused larger increases in blood pressure of 22% +/- 3 and in sympathetic activity of 25% +/- 3. The magnitude of the response was dependent on the location of the catheter tip within the subarachnoid space T9-T11 being best for the above changes. Preceding intrathecal AII with the AII antagonist Saralasin (20 microliters, 10(-3) M) also given intrathecally prevented the changes. An increase in sympathetic nerve activity brought about reflexly by a drop in blood pressure of 45-47 mm Hg was almost halved by intrathecal Saralasin. Peak plasma counts (less than 5% of total) of [3H]AII in the blood after intrathecal injection occurred 2 min after the peak changes in sympathetic activity and blood pressure. Counts of [3H]AII in the spinal cord showed that 81% of recovered label was within one segment on either side of the catheter tip. It is concluded that AII has an excitatory action on sympathetic neurones in the spinal cord.

Angiotensin II as a factor inhibiting the fear response

Angiotensin II, if injected into the lateral ventricles of rabbits in doses of 0.015-0.15 microgram, has an inhibitory action on the fear response evoked by electrical stimulation of the ventromedial hypothalamic nucleus, but in doses of 1-10 ng it blocks the inborn behavioral fear responses in rats. On microionophoretic application of angiotensin II to single neurons in the cerebral cortex and parafascicular complex of the thalamus, predominantly activation responses were observed. Predominance of inhibitory neuronal responses were noted in structures of the hypothalamus and mesencephalic reticular formation to angiotensin II. Responses of cortical and subcortical neurons to angiotensin II are potentiated after stimulation of the "fear center" in the ventromedial hypothalamus. The hypothesis was put forward that depression of the fear response after administration of angiotensin II is connected with changes in cortico-subcortical relations, during which ascending activating influences of the mesencephalic reticular formation on the cerebral cortex are abolished due to descending influences of cortical and thalamic neurons.

Distribution of [125I]angiotensin II binding sites in the rat brain: a quantitative autoradiographic study

Angiotensin II receptors have been localized by quantitative autoradiography in the rat central nervous system after labeling with [125I]angiotensin II. A highly discrete distribution of these receptors was found throughout the rat brain. The highest density was seen in regions of the medulla, hypothalamus and circumventricular organs where angiotensin II could potentially produce cardiovascular, dipsogenic and neuroendocrine responses. The distribution of angiotensin II receptors correlates relatively well with the previously reported distribution of angiotensin immunoreactive nerve terminals as well as areas determined by various physiological techniques to be sensitive to angiotensin II. Finally, the anatomical localization of angiotensin II receptor populations has revealed several areas of the brain where the effects of this peptide have not been investigated. Many of these nuclei are involved in the transmission and processing of somatic and visceral sensory information. These results suggest a broader role for the central renin-angiotensin system in modulating several types of sensory input.

Immunological study of the rat hypothalamic ventromedial nucleus

Specific anti-sera were prepared by injecting the homogenates of rat ventromedial nucleus (VMH) and caudate nucleus (Cd) into the rabbit. Anti-VMH serum, after absorption of common components in rat normal serum and anti-Cd serum, reacted specifically to the rat VMH with only one precipitation line. Anti-VMH serum was successfully applied to 80 VMH neurons by electrophoresis through 5 barreled micropipettes. Fresh anti-VMH serum caused an irreversible response (increase and subsequent sudden cessation of firing) in 8 of the 25 VMH neurons tested. Anti-VMH serum reversibly inhibited 32 of 80 VMH neurons and 13 of these were also tested with glucose. Discharge rates of 12 of the 13 neurons increased by glucose. Most of these neurons were not affected by anti-Cd serum or normal rabbit serum. Results of these immunological and electrophysiological studies suggest the existence of specific membrane receptor binding sites on the glucoreceptor neurons in the VMH. These sites afford one route for producing the excitatory effect that glucose has on VMH neurons.

Electrophysiological effects of angiotensin II on cultured mouse spinal cord neurons

The effects of angiotensin II (AII) on the membrane properties of cultured spinal neurons were investigated using electrophysiological methods. In 26% of neurons tested AII induced changes in membrane potential and input resistance which varied according to the concentration of applied peptide. At low concentrations (10(-6) M), AII increased input resistance by an ionic mechanism which appears to involve a reduction in Cl- conductance. At higher concentration (10(-4) M), AII evoked depolarization associated with a decrease in input resistance. This response appears to depend on an increase in Na+ conductance. Our observations indicate that AII can have multiple effects on neuronal membrane properties dependent on the concentration of applied peptide.

Electrophysiological evidence for multiple sites of actions of angiotensin II for stimulating paraventricular neurosecretory cells in the rat

Microelectrophoretically (MEPh) applied angiotensin II (AII) excited about half of the PV neurosecretory cells recorded. The excitation was blocked by MEPh applied Sar1-Ala8-AII. Intraventricular (IVT) injection of AII excited both the sensitive cells and insensitive cells to the MEPh applied AII. MEPh-applied Sar1-Ala8-AII, however, blocked the IVT AII induced excitation only in the former type of the cells.

Evidence of a direct action of angiotensin II on neurones in the septum and in the medial preoptic area

Angiotensin II (AII) was microiontophoretically applied on neurones located in the septum and the medial preoptic area (MPOA). All the septal neurones sensitive to AII (15/37) responded by an inhibition to the peptide application. Of 44 units tested in the MPOA 21 cells (48%) were sensitive to AII and responded either by an increase (11/21) or decrease (10/21) in their firing. The specificity of these responses were ascertained by simultaneous application of the antagonist Sar-Ile-Angiotensin II. These data suggest that Angiotensin II acts directly on neurones of the septum and medial preoptic area, structures implicated in the control of drinking behaviour.

Angiotensin receptive neurones in the subfornical organ. Structure-activity relations

A microiontophoretic study was performed of the actions of angiotensin II and angiotensin fragments on neurones of the subfornical organ (SFO). Adult cats were anaesthetized and the SFO exposed for penetration by a multibarrelled micropipette. We found that angiotensin II-[2--8]-heptapeptide shows a significantly higher stimulation of firing rate compared to angiotensin II. Angiotensin II-[5--8]-tetrapeptide still produced an excitatory action on a single units. Both the action of the heptapeptide and the tetrapeptide were blocked by [sar1, Ala8]-angiotensin II (P 113). In contrast, angiotensin II-[6--8]-tripeptide failed to enhance the firing rate of the same neurones. Our data indicate that angiotensin II and some shorter chain peptide fragments can directly affect neurones of the SFO. The study may give new insight in structure-activity relations for angiotensin II. The results support the hypothesis that the subfornical organ is a receptor site which is available to this peptide.

Dissociation of responses to extracellular thirst stimuli following zona incerta lesions

In male albino rats, bilateral lesions in the anterior zona incerta which decrease ad lib and food-deprivation water intake and osmotic thirst but leave hypovolemic thirst intact, severely impaired or abolished drinking in response to systemic injections of isoproterenol or central administration of angiotensin II. Water intake following water deprivation was reduced by one-fourth. Reasons for the dissociation of responses to hypovolemia, water deprivation, isoproterenol and angiotensin were suggested.

Effects of angiotensin II on schedule dependent and induced behavior at recovered body weight

The effects of 4 doses of angiotensin II, 0.4, 0.8, 1.2 and 1.6 mg/kg, injected subcutaneously on schedule dependent lever pressing and schedule induced drinking and licking were studied in rats who had recovered body weight under ad lib eating conditions. Prior to this experiment rats had been maintained at 80% body weight and were tested under the usual conditions producing schedule induced drinking. Animals were then returned to the home cage and allowed to recover body weight. Results were analyzed for both the first 15 min of the 1 hr session and for the total 1 hr session. Data indicate that all four doses decreased lever pressing during the first 15 min and for the total 1 hr session. The three highest doses produced increased licking during the first 15 min. Only the highest dose augmented licking throughout the total 1 hr session. Water intakes were significantly increased by the three highest doses only during the first 15 min of the session. Peripheral effects of angiotensin II were discussed and a central pharmacological action on drinking was suggested.

Infant rats: hypothalamic unit activity

Single-unit recordings were made from lateral hypothalamic area (LHA) neurons of infant (8 through 21 days of age) male and female albino rats. Basal (or spontaneous) firing rates of LHA neurons were recorded for 20 min from rats 8 through 21 days of age, and mean basal firing rates did not differ across ages. Basal firing rates of LHA neurons in infant rats ranged from less than 1 spike/sec up to 27 spikes/sec, with 56% of the basal rates less than 1 spike/sec. Infant rats also received hypertonic saline injections (and control injections) to determine osmosensitivity characteristics of LHA neurons. Across ages, 56%--88% of LHA neurons were osmosensitive, with the highest percentages of osmosensitive units found in rats 14--21 days of age. Infant rats showed LHA unit electrophysiological characteristics that were quite similar to those obtained from LHA neurons in adult rats with respect to basal firing rates and osmosensitivity, however, LHA neuron activity in infants was not modulated by sensory stimuli as is frequently reported for adults. The results are discussed in terms of functional development of the LHA.

Evidence for independent osmosensitivity of lateral preoptic and lateral hypothalamic neurons

The purpose of the present study was to determine if a functional or modulatory relationship exists between osmosensitive neurons of the lateral preoptic (LPO) and lateral hypothalamic (LHA) areas. Unit activity was recorded from one neural area (LPO or LHA) following bilateral destruction of the opposite area, i.e., LPO recording site with LHA lesion site, and vice-versa. Bilateral destruction of the LPO or LHA did not eliminate the osmosensitivity characteristics of LPO or LHA units, demonstrating that units of either area do not require input from the opposite area for osmosensitivity.

Effects of angiotensin on drinking

A series of four experiments was carried out to assess the effects of angiotensin II on drinking elicited by various types of stimulation. Experimental I examined the effects of the interaction of 2 cc/kg of 5% NaCl plus 0.2 mg/kg angiotensin II on ad lib eating and drinking. Results indicate that NaCl plus angiotensin produced an additive enhancement in water consumption. Experiment 2 was conducted to investigate the effects of 0.2, 0.4, 0.8, 1.2, and 1.6 mg/kg of angiotensin II on drinking and eating in 23 hr water deprived animals. Dose related increases in drinking alone were observed. In Experiment 3 the effects of 0.4, 0.8, 1.2, and 1.6 mg/kg of angiotensin II on schedule dependent lever pressing and schedule induced drinking and licking were determined. Results demonstrate that angiotensin II decreased lever pressing and increased schedule induced water consumption without a concomitant increase in licking. Experimental 4 examined the effects of the same doses of angiotensin II on prandal drinking in food deprived animals. Under these conditions angiotensin II increased water consumption. Results were discussed in terms of the differential effects of angiotensin II on drinking, eating, and schedule dependent lever pressing.

Effects of ethyl alcohol on central neurons.-

A method was developed for the electrophoretic application of ethyl alcohol through one capillary in a multibarrel microelectrode array in the vicinity of the recording electode. Effects of ethyl alcohol and angiotensin II applied by means of electrophoretic ejection and ethanol administered intravenously on the frequency of extracellularly recorded action potentials of brain cells were determined. A total of 87 neurons in four different parts of the brain in female hooded rats anesthetized with a mixture of urethan and chloralose were tested. Results reveal that a most sensitive neurons appear to be those of the lateral hypothalamus within the medial forebrain bundle. Cells of the zona incerta and thalamus were also sensitive to ethanol. Cells of the cerebral cortex appear to be relatively less sensitive. Many of the ethanol sensitive cells also responded to angiotensin II and when tested the effects were potentiated by Na.