Central H1 and H2 receptor participation in the control of water and salt intake in rats

The aim of the present study was to evaluate the participation of brain H1 and H2 histaminergic receptors on water and salt intake induced by water deprivation (24 h), furosemide-induced sodium depletion and central angiotensinergic pharmacological stimulation in rats. Third ventricle injections of the H1 and H2 receptor antagonists, mepyramine (50, 100, 200 and 400 nmol) and cimetidine (100, 200 and 400 nmol), were unable to modify water intake induced by water deprivation and sodium depletion. Salt intake elicited by water deprivation and sodium depletion was reduced by the central administration of mepyramine, while intracerebroventricular administration of cimetidine had no effect. Water and salt intake evoked by central angiotensinergic stimulation (10 ng) was diminished by third ventricle injections of both mepyramine and cimetidine. Inhibition of the ingestive behaviors observed here is not a result of any illness-like effect produced by the intracerebroventricular injections of the histaminergic antagonists used, as demonstrated by an avoidance test. It was also shown that third ventricle injections of these compounds were unable to modify the hedonic behavior that leads rats to drink a tasty saccharin solution. We conclude that central histaminergic receptors participate in the control of salt intake induced by distinct physiological and pharmacological stimuli.     

Central kappa opioid receptors modulate salt appetite in rats

The role of the central opioid system in the control of water and salt intake is complex, with both stimulatory and inhibitory effects having been observed. The aim of the present study was to investigate the participation of the central κ-opioid receptors in the control of salt appetite. Male Wistar rats were submitted to two different experimental protocols: sodium deficit produced by the diuretic, furosemide, and brain angiotensinergic stimulation in rats under normal sodium balance. Lateral ventricle (LV) injections of Nor-binaltorphimine (Nor-BNI) at different doses (5, 10 and 20 nmol) inhibited hypertonic saline solution (1.5%) intake in sodium-depleted rats. The salt appetite induced by an LV injection of angiotensin II (Ang II) (10 ng) was also blocked by Nor-BNI injections into the LV, while no significant change was observed in water intake. Furthermore, the decrease in salt intake seems not to have been due to a general inhibition of locomotor activity or to any change in palatability, since central administration of Nor-BNI failed to modify the intake of a 0.1% saccharin solution when the animals were submitted to a "dessert test" or to induce any significant locomotor deficit in the open-field test. Also the central administration of Nor-BNI was unable to modify blood pressure in sodium-depleted animals. The present results suggest that activation of endogenous κ-opioid receptors modulates salt appetite induced by sodium depletion and by central angiotensinergic stimulation in rats.     

Central 5-HT(3) receptors and water intake in rats

In the present paper, we studied in rats the effect of third ventricle administration of m-chlorophenylbiguanide hydrochloride (1-(3-chlorophenyl)biguanide (m-CPBG), a selective 5-HT(3) agonist, on water intake induced by three different physiological stimuli: water deprivation, acute salt load and hypovolemia. Central acute m-CPBG injections in the doses of 80 and 160 nmol significantly reduced water intake elicited by an acute salt load. Third ventricle injections of m-CPBG in the dose of 160 nmol significantly inhibited water intake in hypovolemic animals, whereas third ventricle injections of m-CPBG in a higher dose (320 nmol) were necessary to decrease water intake in water-deprived rats. Pretreatment with 1-methyl-N-[8-methyl-8-azabicyclo(3.2.1)-oct-3-yl]-1H-indazole-3-carboxamide (LY-278,584), a selective 5-HT(3) antagonist, abolished the inhibitory effect on water intake seen after central administration of m-CPBG in all groups studied. The central administration of m-CPBG was also able to inhibit water intake induced by pharmacological activation of central cholinergic and angiotensinergic pathways. Third ventricle injections of m-CPBG in the highest dose employed in this study (320 nmol) were unable to modify food intake in food-deprived rats. An aversion test has shown that acute third ventricle injections of m-CPBG do not induce illness-like effects that could explain the water intake inhibition here observed. Also, central administration of m-CPBG did not modify the intake of a "dessert" meal consisting of diluted condensed milk. It is concluded that central 5-HT(3) receptor activation exerts a specific inhibitory effect on water intake.     

Effect of losartan on sodium appetite of hypothyroid rats subjected to water and sodium depletion and water, sodium and food deprivation

The involvement of angiotensin AT1 receptors in sodium appetite was studied in hypothyroid rats treated with the angiotensin II antagonist losartan. Losartan was administered chronically by the oral route or acutely by the subcutaneous route after water and sodium depletion or water, sodium and food deprivation. Three days after addition of losartan to the food at the dose of 1.0 mg x g(-1), the rats significantly reduced (P < 0.02) their spontaneous intake of 1.8% NaCl. Increasing the dose of losartan to 2.0 and 4.0 mg x g(-1) did not reduce NaCl intake; in contrast, the intensity of the sodium appetite gradually returned to previous levels. The simultaneous administration of captopril, an angiotensin converting enzyme inhibitor, and losartan significantly increased (P < 0.05) NaCl intake and after captopril removal NaCl intake returned to the levels observed with losartan treatment alone. The administration of losartan 4 days after the beginning of captopril treatment significantly reduced (P < 0.0001) NaCl intake. Following acute administration of losartan, water- and sodium-depleted rats significantly reduced their NaCl and water intake (P < 0.001). The administration of losartan also induced a significant reduction in NaCl and water intake in water, NaCl and food-deprived rats (P < 0.0001 and P < 0.001, respectively). The present results show that chronic treatment with oral losartan inhibited spontaneous sodium appetite in hypothyroid rats. Continuation of treatment rendered rats resistant to the blockade of AT1 receptors. Water and sodium depletion and water, NaCl and food deprivation induced sodium appetite, which in the short term depends on cerebral angiotensinergic activity mediated by the activation of AT1 receptors.     

The excess salt appetite of humans is not due to sodium loss in adulthood

In seeking the determinants of high salt intake, studies in rat have shown that sodium depletion in utero, neonatally, or in maturity, permanently enhances salt appetite. In humans too, salt appetite is permanently enhanced after perinatal sodium loss, but it is not known if sodium loss in adults also enhances salt intake. If it does, it might contribute to high sodium intake and its associated pathologies. Therefore, using methods that revealed the perinatal determinants of sodium appetite, here we evaluated whether salt appetite is enhanced in adults with a varied history of sodium loss. We find that putative sodium loss due to hyperhidrosis, hemorrhage, dehydration, or breastfeeding, does not increase salt appetite significantly. The findings contrast with the many studies showing enduring enhancement of salt appetite by perinatal sodium loss in humans, and suggest that lifelong salt appetite is established very early in development. In turn this counsels very early intervention to prevent lifelong excess sodium intake.     

Oestrogenic influence on brain AT1 receptor signalling on the thirst and sodium appetite in osmotically stimulated and sodium-depleted female rats

The present work was carried out to investigate the role of angiotensin II type 1 (AT(1)) receptors in nocturnal thirst and sodium appetite induced by classical models of osmotic and sodium depletion challenges in ovariectomized rats chronically treated with oil or oestradiol benzoate (EB, 20 microg per animal, s.c. daily). In both conditions, the animals were given saline or losartan (108 nmol per animal, i.c.v.), a selective AT(1) receptor blocker. Oestrogen therapy significantly reduced the water intake induced by water deprivation, sodium depletion produced by frusemide injected 24 h before, and s.c. acute frusemide plus captopril injection (FUROCAP protocol), with no alteration following s.c. hypertonic saline injection. In contrast, EB therapy decreased the salt intake induced by sodium depletion and FUROCAP protocols, with no alteration following water deprivation and s.c. hypertonic saline injection. Central AT(1) blockade inhibited the dipsogenic response induced by water deprivation, osmotic stimulation, chronic sodium depletion and FUROCAP protocols and inhibited the natriorexigenic response induced by sodium depletion in ovariectomized rats. Oestrogen therapy significantly attenuated the losartan-induced antidipsogenic and antinatriorexigenic actions following sodium depletion and FUROCAP protocols. These results indicate that ovariectomized rats express increased AT(1) receptor signalling related to thirst and sodium appetite responses. Oestrogen therapy and brain AT(1) receptor blockade weakened or markedly decreased the behavioural responses during the nocturnal period, a time at which brain angiotensinergic activity is expected to be more prominent. Finally, we demonstrated through different experimental protocols a clear-cut influence of oestrogenic status on the behavioural AT(1)-induced signalling response.     

Effects of SFO lesions on salt appetite during multiple sodium depletions.

A depletion of sodium may increase sodium intake by increasing the synthesis of angiotensin (ANG) II in the blood and by stimulating ANG II receptors in the subfornical organ (SFO) of the rat. Lesions of SFO reportedly reduce these intakes. The present experiments tested the effects of SFO lesions on salt appetite after three successive depletions. After a furosemide-induced natriuresis, Long-Evans rats had free access to water- and sodium-deficient diet for 22 h. Water and 0.3 M NaCl were given for 2 h, and then the rats received regular chow, water, and 0.3 M NaCl until the next injection 5 or 7 days later. SFO lesions reduced water intake 1-2 h after each furosemide injection but not during the overnight periods. The lesions did not affect salt appetite the next day, 24-26 h after furosemide, but they did prevent the expected increase in the chronic daily 0.3 M NaCl intake after repeated depletions. The second experiment was similar to the first except that three subcutaneous injections of 100 mg/kg captopril were given at 1, 18, and 20 h after furosemide for the second depletion only. After the first depletion, the results were similar to those of the same condition of the first experiment. After the second depletion, captopril greatly reduced water intake and salt appetite in all rats including those with SFO lesions. Thus, we found that the lesion reduced chronic intake, but we did not replicate results showing large effects of SFO lesions on acute salt appetite. This residual acute appetite after SFO lesion remains dependent on the synthesis of ANG II.     

Sodium appetite decreased by central angiotensin blockade

Disturbances in body water and electrolytes that trigger sodium appetite, such as sodium depletion or hypovolemia, are potent activators of the renin-angiotensin system. In the absence of an actual deficit in body fluids, angiotensin injections are adequate to stimulate increased sodium ingestion. To assess whether angiotensin is a significant mediator of sodium appetite induced by acute alterations in body fluids, sodium intake was examined in rats during central or peripheral angiotensin blockade. Central blockade of angiotensin receptors by intracerebroventricular (ICVT) injection of the analogue antagonist saralasin decreased (but did not eliminate) sodium intake after polethylene glycol-induced hypovolemia or sodium depletion resulting from dialysis against glucose. Conversely, peripheral blockade of angiotensin converting enzyme with orally active captopril potentiated rather than decreased sodium appetite and stimulated water intake after sodium depletion. This increased water and salt intake after peripheral inhibition of converting enzyme was reversed, however, by concurrent central blockade of angiotensin receptors. These data support the hypothesis that angiotensin participates in sodium appetite associated with acute alteration in body fluids. Furthermore, the brain is the site at which angiotensin exerts its influence on sodium appetite. While the involvement of angiotensin of brain origin is not ruled out, the change in sodium appetite after peripheral blockade of converting enzyme suggests that circulating angiotensin derived from renal renin may interact with central angiotensin receptors regulating sodium appetite.     

Involvement of central H1 and H2 receptors in water intake induced by hyperosmolarity, hypovolemia and central cholinergic stimulation

In the present study we investigated the participation of central H1 and H2 histaminergic receptors in water intake induced by hyperosmolarity (evoked by intragastric salt load), by hypovolemia (promoted by the subcutaneous administration of polyethyleneglycol) and by the pharmacological stimulation of central cholinergic pathways by the muscarinic agonist carbachol in male Wistar rats. The data presented here show that the pharmacological blockade of central H1 histaminergic receptors by third ventricle injections of mepyramine significantly decreased water intake induced by hyperosmolarity, hypovolemia and by the intracerebroventricular injections of carbachol. On the other hand, the pharmacological blockade of central H2 histaminergic receptors by third ventricle injections of cimetidine significantly reduced water intake in hypovolemic and hyperosmotic animals, but failed to alter water intake induced by central cholinergic stimulation by carbachol. We conclude that H1 and H2 brain histaminergic receptors are involved in inducing thirst during hyperosmolarity and hypovolemia and that H1 histaminergic receptors located post-synaptically in relation to cholinergic pathways seem to be important in triggering drinking following central pharmacological cholinergic stimulation.     

Salt craving: the psychobiology of pathogenic sodium intake

Ionic sodium, obtained from dietary sources usually in the form of sodium chloride (NaCl, common table salt) is essential to physiological function, and in humans salt is generally regarded as highly palatable. This marriage of pleasant taste and physiological utility might appear fortunate--an appealing taste helps to ensure that such a vital substance is ingested. However, the powerful mechanisms governing sodium retention and sodium balance are unfortunately best adapted for an environment in which few humans still exist. Our physiological and behavioral means for maintaining body sodium and fluid homeostasis evolved in hot climates where sources of dietary sodium were scarce. For many reasons, contemporary diets are high in salt and daily sodium intakes are excessive. High sodium consumption can have pathological consequences. Although there are a number of obstacles to limiting salt ingestion, high sodium intake, like smoking, is a modifiable behavioral risk factor for many cardiovascular diseases. This review discusses the psychobiological mechanisms that promote and maintain excessive dietary sodium intake. Of particular importance are experience-dependent processes including the sensitization of the neural systems underlying sodium appetite and the effects of sodium balance on hedonic state and mood. Accumulating evidence suggests that plasticity within the central nervous system as a result of experience with high salt intake, sodium depletion, or a chronic unresolved sodium appetite fosters enduring changes in sodium related appetitive and consummatory behaviors.     

Water deprivation-induced sodium appetite

A water deprived animal that ingests only water efficiently corrects its intracellular dehydration, but remains hypovolemic, in negative sodium balance, and with high plasma renin activity and angiotensin II. Therefore, it is not surprising that it also ingests sodium. However, separation between thirst and sodium appetite is necessary to use water deprivation as a method to understand the mechanisms subserving sodium appetite. For this purpose, we may use the water deprivation-partial repletion protocol, or WD-PR. This protocol allows performing a sodium appetite test after the rat has quenched its thirst; thus, the sodium intake during this test cannot be confounded with a response to thirst. This is confirmed by hedonic shift and selective ingestion of sodium solutions in the sodium appetite test that follows a WD-PR. The separation between thirst and sodium appetite induced by water deprivation permits the identification of brain states associated with sodium intake in the appetite test. One of these states relates to the activation of angiotensin II AT1 receptors. Other states relate to cell activity in key areas, e.g. subfornical organ and central amygdala, as revealed by immediate early gene c-Fos immunoreactivity or focal lesions. Angiotensin II apparently sensitizes the brain of the water deprived rat to produce an enhanced sodium intake, as that expressed by spontaneously hypertensive and by young normotensive rat. The enhancement in sodium intake produced by history of water deprivation is perhaps a clue to understand the putative salt addiction in humans.The paper represents an invited review by a symposium, award winner or keynote speaker at the Society for the Study of Ingestive Behavior [SSIB] Annual Meeting in Portland, July 2009.     

Ontogenetic role of angiontensin-converting enzyme in rats: Thirst and sodium appetite evaluation

We investigated the influence of captopril (an angiotensin converting enzyme inhibitor) treatment during pregnancy and lactation period on hydromineral balance of the male adult offspring, particularly, concerning thirst and sodium appetite. We did not observe significant alterations in basal hydromineral (water intake, 0.3 M NaCl intake, volume and sodium urinary concentration) or cardiovascular parameters in adult male rats perinatally treated with captopril compared to controls. However, male offspring rats that perinatally exposed to captopril showed a significant attenuation in water intake induced by osmotic stimulation, extracellular dehydration and beta-adrenergic stimulation. Moreover, captopril treatment during perinatal period decreased the salt appetite induced by sodium depletion. This treatment also attenuated thirst and sodium appetite aroused during inhibition of peripheral angiotensin II generation raised by low concentration of captopril in the adult offspring. Interestingly, perinatal exposure to captopril did not alter water or salt intake induced by i.c.v. administration of angiotensin I or angiotensin II. These results showed that chronic inhibition of angiotensin converting enzyme during pregnancy and lactation modifies the regulation of induced thirst and sodium appetite in adulthood.     

Salt appetite and lesions of the ventral part of the ventral median preoptic nucleus

Angiotensin receptors in the most ventral part of the ventral median preoptic nucleus (VVMnPO) or organum vasculosum laminae terminalis appear to be important for salt appetite to angiotensin in rats. If so, then small lesions of this region should reduce salt appetite that is dependent on angiotensin. In separate experiments, the lesion greatly reduced salt appetite after treatments with chronic oral captopril or sodium depletion. On the other hand, the VVMnPO lesion actually enhanced salt appetite to deoxycorticosterone acetate. The lesion did not affect water intake to water deprivation, combined food-water deprivation, isoproterenol, or hypertonic saline, and basal plasma osmolality and sodium values were normal. These experiments suggest that VVMnPO lesions selectively affect angiotensin-induced salt appetite without producing the gross hydrational deficits that occur with larger lesions of the ventral forebrain.     

Some central mechanisms of thirst in the dog.

Measurements of water intake were made on a population of trained conscious dogs of both sexes prepared with chronic third ventricle cannulae. 2. Injection of 100 ng angiotensin II into the third ventricle lead to a prompt stimulation of drinking, the mean water intake over a 5 min period being 503 +/- 89 ml. (n=6) compared with controls. This dipsogenic effect of angiotensin II was abolished by prior central administration of 10 mug saralasin acetate or 100 ng atropine. 3. Injection of 1 mug carbachol into the third ventricle produced a small, variable increase in drinking. 4. Injection of 0-2 ml. 5% NaCl into the third ventricle stimulated drinking, a response that was not affected by prior administration of 10 mug saralasin acetate or 100 ng atropine. 5. Following a 24 hr period of water deprivation there was an increase in plasma osmolality and plasma-renin activity. The drinking following this period of water deprivation was not affected by prior control administration of either 10 mug saralasin acetate or 100 ng atropine. 6. In two acute dogs, intracarotid infusion of 125I angiotensin II was not followed by significant appearance of radioactivity in the third ventricle or cisterna magna c.s.f. 7. The relevance of these results to the control of water intake is discussed.     

The olfactory detection of sodium and lithium salts by sodium deficient cattle

With development of Na+ depletion in cattle enhancement in the specific ability to smell very low concentrations of salt occurs. At the same time a behaviour pattern develops, in which increased locomotory activity is seen, directed towards searching for sodium salts. Following the initial successful location of a sodium source the pattern once learned, is consolidated by repetition and by consummation of the salt reward. Our data shows that olfactory and gustatory receptors are able to detect minute amounts of sodium salts as biochemical disruption develops with Na+ depletion but the central input from smell and taste receptors remain distinct. Salt appetite does not appear to be pleasurable (hedonic) in cattle, for salt appetite which is a feature of Na+ depletion does not persist when the ionic deficit is restored. The innate behaviour which develops with increased salt appetite in cattle may account for the evolutionary success and worldwide distribution of ruminants.     

Effects of central and peripheral injections of apelin on fluid intake and cardiovascular parameters in rats

Previous studies have indicated that apelin, a novel peptide suggested to have some actions related to angiotensin peptides, has either a dipsogenic or an antidipsogenic effect and either increases or decreases blood pressure. The present study attempts to provide replication or understanding of these disparate effects. Neither central (lateral or third cerebral ventricle) nor peripheral (intravenous) administration of apelin induced water intake in sated rats, nor did it decrease water intake in deprived rats. It also had no effect on sodium appetite. Peripherally injected apelin had a hypotensive action in anesthetized rats, but had no consistent effect in awake, unrestrained rats. We conclude that apelin does not have reliable or robust effects on fluid intake or blood pressure in Sprague-Dawley rats under normal conditions, but discuss the possibility for a role of apelin in fluid homeostasis in selected physiological states.     

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 animal's 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.     

Gender and obesity influence sodium intake and fluid regulation in Zucker rats following repeated sodium depletions

The Zucker obese rat is an important model for the metabolic syndrome, which includes renal disease and salt-sensitive hypertension, suggesting abnormalities of body fluid regulation. Here, in Zucker rats, lean and obese, and of both sexes, we compared 48 h of sodium intake and fluid regulation responses with repeated depletions with furosemide to repeated control saline injections. Increased urine volume excretion was observed after each furosemide administration for the 4 groups and obese rats excreted more than the leans on the control days. Male obese rats did not excrete sodium nor increase intake of 2% NaCl following the first furosemide administration, whereas the other 3 groups did. Subsequent depletions increased 2% NaCl consumption and urinary sodium excretion in all groups. Males excreted more sodium in their urine than the females on the control days. Females showed an increase in 2% NaCl intake on control days. Water intake increased in the female leans after each depletion, increased in the males after the 2nd and 3rd depletion and increased in the obese females only after the 2nd depletion. These findings show clearly that there are gender- and weight-related differences in the response of Zucker rats to furosemide-induced depletion. However, the main differences occurred with the first depletion. With repeated depletions the rats adjusted sodium and fluid intake and excretion so that differences due to gender and body weight tended to disappear. Our findings caution against drawing conclusions about differences due to gender and body weight based on single treatments.     

Effects of exercise and anion on intake of sodium solutions in Syrian hamsters.

Previous studies have shown that hamsters have low spontaneous intakes of NaCl solutions and are refractory to induction of salt appetite. In order to examine the generality of these results, the intakes of NaCl and NaHCO3 solutions are reported for hamsters housed either in normal laboratory conditions (sedentary) or with free access to exercise wheels. Spontaneous salt intakes, as well as those induced by acute sodium depletion and treatment with either the angiotensin converting enzyme inhibitor, enalapril, or deoxycorticosterone acetate (DOCA), were measured. The intakes of NaCl and NaHCO3 were similar. Salt intakes tended to be lower in exercising than in sedentary groups. Neither acute sodium depletion nor administration of enalapril increased salt intake systematically, but treatment with DOCA increased intakes of both salt and water. These results are contrasted with the efficacy of all three treatments to induce salt appetite in rats.     

Dietary sodium deprivation reduces gustatory neural responses of the parabrachial nucleus in rats

Acute sodium depletion induced by furosemide reduces gustatory responses of parabrachial nucleus (PBN) neurons to 0.3-0.5M NaCl in rats. However, in the rat nucleus of the solitary tract (NST), where taste-responsive cells project to the PBN, acute sodium depletion and dietary sodium deprivation elicit different response profiles to lingual NaCl stimulation. To examine the effect of dietary sodium deprivation on the responses of PBN gustatory neurons, we observed the taste responses of the PBN neurons to the four taste qualities and serial concentrations of NaCl in 15-day dietary sodium-deprived and control rats. The results showed that sodium deprivation reduced the responses of PBN taste neurons to 0.1-1.0M NaCl, but not to other tastants. Based on the analyses classified by best-stimulus categories, the number of NaCl-best neurons decreased from 68% to 45% following dietary sodium deprivation, and the responses of the NaCl-best neurons to 0.03-1.0M NaCl were significantly inhibited. Multidimensional scaling illustrated that sodium deprivation increased the similarity of the response profiles of the NaCl-best neurons. These findings suggest that dietary sodium deprivation might modulate sodium intake via increasing aversive threshold for salt rather enhancing salt discrimination.