Alan N. Epstein

Sodium appetite elicited by intracerebroventricular infusion of angiotensin II in the rat: II. Synergistic interaction with systemic mineralocorticoids.

Angiotensin and mineralocorticoids, the hormones of sodium conservation, acted together to arouse a sodium appetite with shorter latency and greater magnitude than is produced by larger amounts of each acting alone. This potentiation was selective for sodium ingestion and occurred in the absence of significant changes in sodium balance. Therefore, because endogenous angiotensin and mineralocorticoids are concurrently elevated during sodium deficiency, sodium appetite may be aroused by a synergy of the peptide and the steroid.

Salt appetite is enhanced by one prior episode of sodium depletion in the rat.

A single sodium depletion enhances the salt appetite that is expressed after a second and subsequent sodium depletions. The enhanced salt intake, as measured by a decrease in latency to drink and an increase in volume of 3% NaCl ingested, is not accounted for by an increased sodium loss. The enhanced salt intake occurs even when the interval between first and second depletion is as long as 4 months. The enhanced salt appetite does not depend on the drinking of salt after the animals first sodium depletion and is specific for NaCl but not for KCl. Moreover, it can be produced without sodium depletion by the actions of the hormones aldosterone and angiotensin on the brain. These results suggest that angiotensin and aldosterone, which are released in response to sodium depletion, (a) increase renal sodium conservation, (b) evoke a salt appetite to restore the lost sodium, and (c) produce enduring changes in the brain that prepare it for more rapid and more vigorous expression of salt appetite in response to future sodium depletions. Thus the neural mechanisms that govern salt appetite are not only activated by the hormones of sodium conservation but appear also to be organized by them for a lifelong increase in avidity for salty substances.

Deficits in NaCl ingestion after damage to the central nucleus of the amygdala in the rat

These studies examined the NaCl intake behaviors of rats with bilateral electrolytic lesions of the central nucleus of the amygdala (CeAX). Daily need-free intake of 3% NaCl was abolished by CeAX even in rats in which it had been enhanced preoperatively by a history of repeated sodium depletions but was slightly restored by three successive postoperative sodium depletions. CeAX rats drank water but not 3% NaCl to high doses of DOCA and to the activation of cerebral angiotensin II, and expressed small but reliable salt intake (need-induced salt intake or salt appetite) after postoperative sodium depletions. Other ingestive behaviors (water drinking, intake of food and 5% sucrose) were normal. When given decreasing concentrations of NaCl solution the CeAX rats rejected them until the concentration reached 0.2%. These findings suggest that lesions to the central nucleus of the amygdala produce a global impairment in salt intake behaviors that is possibly due to an alteration in the central processing of the salt taste signal.

Prior episodes of sodium depletion increase the need-free sodium intake of the rat

Prior episodes of sodium depletion increase the daily 3% NaCl intake of rats. They ingest large volumes and continue to do so for as long as 3 months after recovery from sodium deficit while eating sodium-rich food and while plasma sodium concentration and renal function are normal. The increased daily intake of sodium is, therefore, need-free. There is a marked sex difference in the need-free intake of 3% NaCl. Female rats drink more salt than do male rats when they are sodium replete and depletion naive. Repeated depletions raise the need-free intakes of both sexes but the effect is greater in females. Plasma concentrations of angiotensin II and aldosterone, which are markedly elevated by each episode of sodium depletion, return to basal levels between and after depletions, and are not the cause of the chronically increased need-free salt intake of the multi-depleted rat. These results suggest that the persistent increase in daily 3% NaCl intake that occurs in the rat with a history of repeated sodium depletions is a permanent, nonpathological increase in avidity for the taste of salty substances that results in life-long overconsumption of salt.

Lesions of the central nucleus of the amygdala. I: Effects on taste reactivity, taste aversion learning and sodium appetite.

Bilateral damage to the central nucleus of the amygdala (CeAX) in the rat blunts need-induced NaCl intake and abolishes daily need-free NaCl intake when measured with a two-bottle test. Such a deficit could be the result of impaired taste function. To assess the taste function of the CeAX rat various taste stimuli were introduced directly into the oral cavity and taste-elicited oral motor responses were measured. Oral motor responses elicited by 0.62 M and 0.13 M sodium chloride, 0.3 M sucrose and 0.01 M citric acid, were similar in control and CeAX rats. Additionally CeAX and control rats acquired a taste aversion for fructose or maltose when either was paired with LiCl. Finally, in CeAX rats, like in control rats, the pattern of oral motor responses to 0.5 M NaCl was dependent on internal state; sodium depletion dramatically altered taste-elicited oral motor behavior. These results suggest that, in the rat, the deficits in NaCl intake behavior that follow CeAX do not appear to be a result of dramatic changes in gustatory function.

The complete dependence of beta-adrenergic drinking on the renal dipsogen ☆

Abstract The drinking that follows hypotensive doses of beta-adrenergic agonists is abolished by nephrectomy but survives ureteric ligation. It is restored to the nephrectomized, hypotensive rat by both systemic renin and intracranial angiotensin II. The thirst of beta-adrenergic activation, therefore, depends on renin-angiotensin for its expression. But unlike other extracellular challenges, beta-adrenergic activation is completely dependent on the renin-angiotensin system for the production of thirst. These results extend the significance of the renin-angiotensin system as a hormonal basis for thirst, operating by peripheral release of renin (the renal dipsogen) and direct action of angiotensin on the brain.

Mineralocorticoids and cerebral angiotensin may act together to produce sodium appetite

Abstract The sodium appetite that follows sodium deficiency may be aroused by a synergy of the hormones of sodium deficiency (angiotensin and mineralocorticoid) rather than by the deficiency itself. Recent evidence supporting this idea is discussed with emphasis on the possibility that angiotensin of cerebral origin may be more effective in this synergy than that of renal origin.

A role for the medial region of the amygdala in mineralocorticoid-induced salt hunger.

Damage to the medial region of the amygdala abolished aldosterone-induced salt hunger in the rat. In contrast, the salt hungers that are induced by adrenalectomy or by acute sodium depletion are left intact by the same brain damage. We suggest (a) that we have identified part of the neural circuit by which aldosterone participates in the genesis of salt hunger in the intact, sodium-depleted rat and (b) that these results provide further evidence for the hypothesis that there are separate receptive systems in the brain for the participation of aldosterone and angiotensin in the arousal of salt hunger.

Dependence of adrenalectomy-induced sodium appetite on the action of angiotensin II in the brain of the rat.

Adrenalectomized rats express a robust sodium appetite that is accompanied by high levels of blood-borne angiotensin II and is caused by angiotensin II of cerebral origin. Blood-borne angiotensin II is elevated in rats consuming NaCl after adrenalectomy, and plasma angiotensin II concentrations are increased further when the animals cannot drink a NaCl solution. These phenomena are the result of the pathological removal of aldosterone, because replacement therapy returned both sodium intake and plasma angiotensin II concentrations to preadrenalectomy levels. The adrenalectomized rats appetite for sodium is completely suppressed by interference with the central, but not the peripheral, action of angiotensin II. These data demonstrate that the mechanism of the sodium appetite of the adrenalectomized rat is a pathological instance of the angiotensin/aldosterone synergy that governs the sodium appetite of the adrenal-intact, sodium-depleted rat. Because aldosterone has been removed, angiotensin acts alone to produce the appetite. Furthermore, the data show that it is angiotensin II of central origin that is important for sodium appetite expression.

Water Intake without the Act of Drinking

A method is described that allows a rat to ingest fluid through a chronic gastric tube that bypasses the oropharyngeal cavity. In this situation longterm regulation of water intake occurs in normal rats and in the rat with diabetes insipidus. Under special circumstances, a remarkable degree of excess intake can be produced.