Endocrine and ingestive behavioral responses to fluid deprivation in sheep chronically exposed to ethanol.

Endocrine responses to fluid deprivation/restoration and preference for ethanol solution vs. water were assessed in sheep maintained for 5 months on a 10% ethanol solution as their sole source of fluid. Blood pressure, body weight, plasma composition and hormone levels of the alcohol maintained sheep were all within a normal range, except for high plasma concentrations of ANG II and ALDO. During fluid deprivation, AVP concentration increased and fluid-deprived sheep displayed a natriuresis and then a rehydration anti-natriuresis. Sheep did not drink the 10% ethanol solution avidly upon fluid restoration, preferring to drink steadily over the following 24 h; there was an associated increase in blood alcohol concentration (BAC). PRC, ANG II and ALDO all increased throughout the fluid restoration period, whereas plasma AVP and ANP gradually fell. In a separate experiment when water was also supplied to the sheep, they preferred water to 10% ethanol; however, alcohol intake was not eliminated. Overall, this degree of chronic consumption of 10% ethanol solution did not appear to adversely affect physiological mechanisms concerned with body fluid homeostasis after fluid deprivation conditions.

Cardiovascular effects of long-term central and peripheral administration of urocortin, corticotropin-releasing factor, and adrenocorticotropin in sheep.

The neuroendocrine hormones ACTH and corticotropin- releasing factor (CRF), which are involved in the stress response, have acute effects on arterial pressure. New evidence indicates that urocortin (UCN), the putative agonist for the CRF type 2 receptor, has selective cardiovascular actions. The responses to long-term infusions of these hormones, both peripherally and centrally, in conscious animals have not been studied. Knowledge of the long-term effects is important because they may differ considerably from their acute actions, and stress is frequently a chronic stimulus. The present experiments investigated the cardiovascular effects of CRF, UCN, and ACTH in conscious sheep. Infusions were made either into the lateral cerebral ventricles (i.c.v.) or i.v. over 4 d at 5 microg/h. UCN infused i.c.v. or i.v. caused a prolonged increase in heart rate (HR) (P < 0.01) and a small increase in mean arterial pressure (MAP) (P < 0.05). CRF infused i.c.v. or i.v. progressively increased MAP (P < 0.05) but had no effect on HR. Central administration of ACTH had no effect, whereas systemic infusion increased MAP and HR (P < 0.001). In conclusion, long-term administration of these three peptides associated with the stress response had prolonged, selective cardiovascular actions. The striking finding was the large and sustained increase in HR with i.c.v. and i.v. infusions of UCN. These responses are probably mediated by CRF type 2 receptors because they were not reproduced by infusions of CRF.

The effect of urocortin on ingestive behaviours and brain Fos immunoreactivity in mice.

The influence of urocortin (UCN) on ingestive behaviours and brain neural activity, as measured immunohistochemically by the presence of Fos protein, was determined in mice. Rat UCN was administered by continuous intracerebroventricular (ICV) or subcutaneous (SC) infusion. ICV infusion of UCN (100 ng/h, 14 days) transiently reduced daily food and water intakes (days 1-4) but body weight was reduced from day 2 into the post-infusion period. Sodium intake was reduced from day 3 to the end of infusion. SC infusion of UCN caused similar but smaller reductions in food and water intakes and body weight, without change in sodium intake. In separate experiments, Fos immunoreactivity was increased in several brain nuclei known to be involved in the control of body fluid and energy homeostasis, e.g. central nucleus of the amygdala, median preoptic nucleus, bed nucleus of the stria terminalis and arcuate nucleus. Increased Fos expression was similar for ICV and SC infusions when measured on days 2-3 or 6-7 of infusion. In conclusion, increases of brain activity by UCN may be associated with stimulation of adrenocorticotrophic hormone release and sympathetic nervous activity, but increases may also indicate suppression of ingestive behaviours by stimulating central inhibitory mechanisms located in areas known to control body fluid and energy homeostasis.

Synergy between angiotensin and aldosterone in evoking sodium appetite in baboons.

The synergy between ANG II and aldosterone (Aldo) in the induction of salt appetite, extensively studied in rats, has been tested in baboons. ANG II was infused intracerebroventricularly at 0.5 or 1.0 microg/h; Aldo was infused subcutaneously at 20 microg/h. Separate infusions over 7 days had no significant effect on the daily intake of 300 mM NaCl. Concurrent infusions, however, increased daily NaCl intake approximately 10-fold and daily water intake approximately 2.5-fold. In addition, the combined infusions caused 1) a reduction in daily food intake, 2) changes in blood composition indicative of increased vasopressin release, and 3) changes of urinary excretion rates of cortisol and Aldo indicative of increased ACTH release. Arterial blood pressure, measured in two baboons, rose during concurrent ANG II and Aldo treatment. These results indicate a potent synergy between central ANG II and peripheral Aldo in stimulating salt appetite in baboons. At the same time, other ANG II-specific brain mechanisms concerned with water intake, food intake, vasopressin release, ACTH release, and blood pressure regulation appear to have been activated by the same type of synergy. These central enhancement processes have never been previously demonstrated in primates.

Ingestive responses to administration of stress hormones in baboons.

Experimental stress and the administration of the stress hormone ACTH have been reported to stimulate sodium appetite in many nonprimate species. Experiments were conducted to determine whether prolonged intracerebroventricular infusions of the neuropeptides corticotropin-releasing factor (CRF) and urocortin (Ucn), or systemic administration of ACTH, affected ingestive behaviors in a nonhuman primate, the baboon. Intracerebroventricular infusions of CRF or Ucn significantly decreased daily food intake. The decrease with Ucn continued into the postinfusion period. These infusions did not alter daily water intake. Daily voluntary intake of 300 mM NaCl solution was not increased, and there was evidence of reductions on days 2-4 of the infusions. Intramuscular injections of porcine ACTH or synthetic ACTH (Synacthen) for 5 days did not affect daily NaCl intake, although the doses were sufficient to increase cortisol secretion and arterial blood pressure. Sodium depletion by 3 days of furosemide injections did induce a characteristic sodium appetite in the same baboons. These results demonstrate the anorexigenic action of CRF and Ucn in this primate. Also, CRF, Ucn, and ACTH did not stimulate sodium appetite at the doses used.

Possible contribution of brain angiotensin III to ingestive behaviors in baboons.

Recent experiments with specific aminopeptidase inhibitors in rats have strengthened earlier proposals that ANG III may be an important regulatory peptide in the brain. Central mechanisms regulating blood pressure, ingestive behaviors, and vasopressin release could be involved. Arguments in favor of a role for ANG III depend, in part, on the efficacy of ANG III as an agonist. These first studies in primates tested whether ANG III stimulates ingestive behaviors in baboons. Intracerebroventricular (ICV) infusions of ANG III were as potent as ANG II in stimulating water drinking and intake of NaCl solution. On the basis of this criterion and consistent with findings in rats, ANG III could be a main effector peptide in the regulation of ingestive behaviors in a primate.

Cerebral Na concentration, Na appetite and thirst of sheep: influence of somatostatin and losartan.

Na and water intakes of Na-depleted sheep are influenced by changes in cerebral Na concentration. The effect of intracerebroventricular infusion of somatostatin or losartan, the ANG II type 1 receptor antagonist, on the Na appetite and thirst of Na-depleted sheep during infusions that decrease (intracerebroventricular hypertonic mannitol) or increase (intracerebroventricular or systemic hypertonic NaCl) cerebral Na concentration was investigated. Na intake was increased but water intake was unchanged during intracerebroventricular infusion of hypertonic mannitol. The increased Na appetite caused by intracerebroventricular infusion of hypertonic mannitol was decreased by concurrent intracerebroventricular infusion of either somatostatin or losartan, with somatostatin being most effective. Water intake was increased during intracerebroventricular infusion of hypertonic mannitol and somatostatin. Na intake was decreased and water intake was increased during systemic or intracerebroventricular infusion of hypertonic NaCl. Intracerebroventricular infusion of losartan blocked both (Na and water intake), whereas somatostatin did not influence either of these changes in intake. The results further consolidate a role for somatostatin and ANG II in the central mechanisms controlling Na appetite and thirst of sheep.

The inhibitory effect of hormones associated with stress on Na appetite of sheep.

Stress is a large stimulus of Na appetite in rabbits, rats, and mice. This study investigated the influence of some peptides implicated in stress, i.e., adrenocorticotropin (ACTH), corticotropin-releasing factor (CRF), and the recently discovered member of the CRF family, urocortin, on the ingestive behavior of sheep. Intracerebroventricular infusion of these peptides over 4 days decreased the need-free Na intake of Na-repleted sheep. Intracerebroventricular infusion of urocortin, however, did not alter Na intake of Na-depleted sheep. Systemic infusion of ACTH increased, whereas systemic infusion of either urocortin or CRF decreased, Na intake of Na-repleted sheep. The increase in Na intake caused by the peripheral infusion of ACTH was blocked by concurrent i.v. infusion of urocortin, substantiating the inhibitory role of this peptide on Na appetite. Central administration of all peptides and i.v. administration of urocortin or urocortin and ACTH combined decreased food intake. Water intake was not directly influenced by the peptides. Rather, decreased water intake, when observed, was secondary to decreased food intake, as determined by pair-feeding experiments. Whereas systemic infusion of ACTH mimics the increase in Na intake observed in several different stressful situations, CRF and urocortin actually inhibit Na intake, indicating a direct central action overriding any effect of these peptides on ACTH release. Indeed, the inhibition of Na intake by urocortin occurred despite its stimulation of ACTH release and the subsequent increase in peripheral level of cortisol. Thus it would appear that hormones associated with stress have both excitatory and inhibitory influences on Na intake. Presumably, other physiological processes entrained by stress also will be important in determining the quantitative outcome on Na appetite.

Effect of adrenocorticotrophic hormone on sodium appetite in mice.

A main vector of the effects of stress is secretion of corticotrophin releasing factor (CRF), adrenocorticotrophin (ACTH), and adrenal steroids. Systemic administration of ACTH (2.8 microgram/day sc) for 7 days in BALB/c mice caused a very large increase of voluntary intake of 0.3 M NaCl equivalent to turnover of total body sodium content each day. Intracerebroventricular infusion of ACTH (20 ng/day) had no effect. Intracerebroventricular infusion of ovine CRF (10 ng/h for 7 days) caused an increase of sodium intake. The large sodium appetite-stimulating effect of systemic ACTH was not influenced by concurrent systemic infusion of captopril (2 mg/day). Induction of stress by immobilization of mice on a running wheel caused an increase in Na appetite associated with a 50% decrease of thymus weight, indicative of corticosteroid effects. The present data suggest that stress and the hormone cascade initiated by stress evoke a large sodium appetite in mice, which may be an important survival mechanism in environmental conditions causing stress.

Angiotensin II stimulates intake of ethanol in C57BL/6J mice.

The influence of intracerebroventricular (i.c.v.) infusion of angiotensin II on intake of water and ethanol solutions was determined in C57BL/6J mice. Compared to other mice, C57 mice do not show an aversion to ethanol solutions. With both water and ethanol solutions available, the C57 mice consumed 40-60% of their total daily fluid intake as ethanol solution when the concentration of ethanol solution offered was 4-14%. When given a choice between 0.3 M KCl and either 4 or 10% ethanol solution, the mice clearly preferred the ethanol solution. With water only available, i.c.v. infusion of angiotensin II increased intake from 3-5 mL/day (baseline) to 11-12 mL/ day (Day 4 of infusion). A similar increase in intake occurred in mice with access to a nonpreferred solution of 0.3 M KCl. In comparison, when only 4% ethanol solution was available, angiotensin II increased intake to 7-8 mL/day, and when only 10% ethanol solution was available, intake was transiently increased. The results demonstrated that thirst for water caused by i.c.v. infusion of angiotensin II in C57 mice is similar to that observed in BALB/C mice. Unlike BALB/C mice, however, i.c.v. infusion of angiotensin II stimulated intake of ethanol solution. The failure of angiotensin II to cause a large increase in 4% ethanol solution or a sustained increase in 10% ethanol solution intake does not seem to be caused by an aversion to the taste of ethanol solution, but most likely due to postingestional factors.

The effects of angiotensin II on blood perfusion in the rat renal papilla.

1. Systemic infusion of angiotensin II (AII) increased papillary blood perfusion (PBP) measured by laser-Doppler flowmetry in rats, aged about 5 weeks. 2. The mechanisms involved in this response were determined by infusion of AII in the presence of systemic doses of losartan (a type 1 AII receptor antagonist), HOE-140 (a bradykinin B2 receptor antagonist), and an inhibitor of NO production - Nomega-nitro-L-arginine (NOLA). 3. Mean arterial blood pressure (MAP) and PBP increased in a dose-dependent manner in response to intravenous infusions of AII. Infusion of losartan abolished these responses to AII but HOE-140 was without effect. Infusion of NOLA abolished the increase in PBP but did not affect the pressor response to AII. Systemic infusion of sodium nitroprusside restored the response to AII in experiments with NOLA infusion. 4. The results indicate that the increase in PBP caused by AII is mediated via angiotensin AT1 receptors and does not involve bradykinin B2 receptors. The AII-induced increase in PBP is dependent upon the presence of NO, thus providing a mechanism for maintenance of papillary perfusion in the face of generalized renal vasoconstriction due to AII.

Sodium intake and reproduction in BALB/C mice.

The effect of sodium intake on the reproductive performance of BALB/C mice was assessed in four groups of 11 or 12 mice that received ad lib access to low or higher sodium food (LSF 4-5, HSF 120-143 mmol Na+/kg). The two groups that received HSF had (mean values) 100% matings, 83 and 91% litters, 5.9 pups/litter, pups weighing 2.05 and 2.22 g (3 days after birth) and 10.47 and 10.96 g at weaning (19 days). One of the HSF groups that also had 300 mM NaCl to drink did not show any benefit. Two groups received LSF, and one of them also received 30 mM NaCl. The group given LSF only had 83% matings, 20% litters, 1.5 pups/litter, and pups that were significantly smaller at birth and at weaning. However, the LSF group given 30 mM NaCl to drink performed almost as well as the two HSF groups. The results show that (a) the daily sodium requirement for optimal reproduction was > or = 400 (micromol/day, based on voluntary sodium intake late in gestation and lactation; (b) sodium deficiency was the cause of reproductive deficiency in mice on LSF; (c) severe sodium deficiency suppressed reproduction primarily at the gestation step; (d) this deficiency could be prevented by the voluntary sodium intake of mothers with access to salt solution; and (e) pups on the LSF showed an avid innate salt appetite when offered salt solution at 12 days of age.

Intracerebroventricular infusion of angiotensin II increases water and ethanol intake in rats.

The influence of prolonged ingestion of ethanol on stimulation of water or ethanol intake by intracerebroventricular infusion of ANG II was evaluated in rats. Animals were maintained for 5-6 mo with either 10% ethanol solution or water as their only source of fluid. In both groups of rats, infusion of ANG II caused a large increase in water intake (7-fold) and a lesser increase in 10% ethanol intake (2-fold). The effect of ANG II on the volume of ethanol solution ingested, however, was inversely related to the concentration of the ethanol solution. As the concentration of ethanol solution was decreased, frequency and duration of drinking bouts increased. The intake of sweetened 10% ethanol solution or commercially produced wine during infusion of ANG II was similar to the intake of 10% ethanol and not related to taste preference. In conclusion, chronic consumption of ethanol solution did not appear to adversely effect ANG II stimulation of water intake. The intake of ethanol solution during infusion of ANG II was inhibited by a direct effect of ingested ethanol and/or by indirect effect from metabolized ethanol.

Evidence that brain angiotensin II is involved in both thirst and sodium appetite in baboons.

The roles of ANG II in the brain mechanisms subserving thirst and Na appetite in baboons were investigated by chronic intracerebroventricular infusions of ANG II and AT1-receptor antagonists using subcutaneous miniosmotic pumps and by oral administration of captopril. ANG II at 3 or 5 micrograms/h for 7 days increased water intake from 2,455 +/- 107 to 7,052 +/- 562 ml/day by day 6 and 300 mM NaCl intake from 8.3 +/- 1.1 to 275 +/- 87 mmol/day by day 5. Concurrent intracerebroventricular losartan (300 micrograms/h) did not substantially reduce these responses, but they were abolished by intracerebroventricular ZD-7155 (50 micrograms/h). The increase of 300 mM NaCl intake when it was offered after intramuscular injection of furosemide, 2 mg . kg-1 . day-1 for 3 days, was unaltered by intracerebroventricular losartan (300 micrograms/h) but was reduced by intracerebroventricular ZD-7155 (50 micrograms/h) infused throughout Na depletion/repletion; oral captopril (1 g, 3 and 18 h before access to 300 mM NaCl) also reduced NaCl intake. Restriction of water intake to 25% of daily intake for 3 days caused a high intake of water on day 4, and this was reduced by intracerebroventricular losartan (300 micrograms/h) infused throughout the period of water restriction/rehydration. These novel results in a primate species suggest that brain ANG II is involved in both thirst and Na appetite, acting via AT1 receptors.

Na depletion-induced Na appetite of sheep is independent of brain angiotensin II.

Previous experiments indicated that the Na appetite of Na-deplete sheep is decreased by systemically administered captopril. The assumption that captopril does not readily cross the blood-brain barrier, lead to the conclusion that circulating ANG II acting in brain areas without a blood-brain barrier, i.e., circumventricular organs such as the subfornical organ or organum vasculosum of the lamina terminalis, contributes to Na appetite induced by Na depletion. The present experiments investigated the possibility that systemically administered captopril does, in fact, cross the blood-brain-barrier and thereby influence brain angiotensin II formation and that brain angiotensin II contributes to Na depletion-induced Na appetite of sheep. The results showed that systemically administered captopril blocked water intake caused by intracerebroventricular infusion of angiotensin I, and that Na depletion induced Na appetite was not decreased by intracerebroventricular infusion of various antagonists of the renin-angiotensin system. Thus, the results suggest that although captopril crosses the blood-brain-barrier and can influence the formation of brain angiotensin II, brain angiotensin II is not involved in the Na appetite of Na-deplete sheep.

Role of brain angiotensin II in thirst and sodium appetite of sheep.

The contribution of brain angiotensin II (ANG II) to thirst and Na+ appetite of sheep was evaluated. Thirst was stimulated by water deprivation, intracarotid or intracerebroventricular infusion of ANG II, or intracarotid or intracerebroventricular infusion of hypertonic solution. Intracerebroventricular infusion, over 1-3 h, of the ANG II type 1 (AT1) receptor antagonist, losartan, decreased or abolished water intake caused by all of the stimuli tested. Intracerebroventricular infusion of ZD-7155, another AT1-receptor antagonist, blocked ANG II-induced water intake. Neither losartan nor ZD-7155 infused intracerebroventricularly altered the Na+ appetite of Na(+)-depleted sheep. Intracerebroventricular infusion of losartan over 3 h, however, did block the increase in water intake and the decrease in Na+ intake caused by intracerebroventricular infusion of hypertonic NaCl in Na(+)-depleted sheep. Intracerebroventricular infusion of the ANG II type 2 (AT2) receptor antagonist, PD-123319, over 1-3 h, did not alter ANG II-induced water intake or Na+ depletion-induced Na+ intake. These results are consistent with the proposition that brain ANG II, working via AT1 receptors, is involved in the neural system controlling some aspects of physiological thirst and Na+ appetite. A role for AT2 receptors in physiological thirst or Na+ appetite is not supported by the present results.

Central infusion of the AT1 receptor antagonist losartan inhibits thirst but not sodium appetite in cattle.

Experiments in cattle compared the effects of intracerebroventricular (i.c.v.) infusions of losartan and PD-123319 on water intake caused by water restriction, i.c.v. infusion of hypertonic NaCl, or i.c.v. infusion of angiotensin II (ANG II). The effects of these receptor antagonists on sodium intake caused by sodium depletion were also examined. Losartan infusion caused dose-dependent inhibition of the high water intake caused by the physiological stimulus of water restriction or by ANG II infusion but did not affect salt appetite. PD-123319 infused at equimolar or greater (in ANG II experiments) doses did not affect water intake or salt intake due to sodium depletion. The results of these i.c.v. infusion experiments confirm our earlier proposal that the physiological regulation of water intake in cattle may be mediated by ANG II acting centrally via AT1 receptors. The dose of losartan that inhibited thirst in cattle did not inhibit sodium appetite, nor did an equimolar dose of PD-123319.

Role of brain angiotensin in thirst and sodium appetite of rats.

The role of brain angiotensin II (ANG II) in water, Na and food intake of rats was studied. Intracerebroventricular (i.c.v.) infusion (100 micrograms/h) of the non-peptide ANG II receptor antagonist losartan (type 1), but not PD123319 (type 2), completely blocked water intake caused by i.c.v. infusion of ANG II at 50 ng/h. Following food deprivation, food intake was reduced by PD123319 and associated water intake was decreased by losartan or PD123319. Neither water intake after water deprivation nor Na intake after Na depletion was altered by losartan or PD123319. In conclusion, evidence was consistent with a role for brain ANG II in both food and water intake after food deprivation but not in thirst subsequent to water deprivation or Na intake after Na depletion alone.

The role of angiotensin II in ingestive behaviour: a brief review of angiotensin II, thirst and Na appetite.

From the outset, the study of angiotensin II (Ang II) in body fluid homeostasis has been both complicated and intriguing. Since the publication of an early report of the dipsogenic action of this peptide, the pursuit of the role of Ang II in thirst and Na appetite has continued for the last 25 years. This pursuit captured the attention of all workers interested in the behavioural/physiological regulation of body fluid balance, with major contributions being made by James T. Fitzsimons and his colleagues. In spite of its powerful dipsogenic actions, delineation of its precise role in physiological thirst has been elusive and difficult to demonstrate. The influence of Ang II on Na intake took longer to show convincingly. However, in contrast to thirst, the role of Ang II in physiological Na appetite has been demonstrated clearly. The technological advances made during the recent years have greatly increased our ability to delineate the neurobiological context of Ang II-mediated responses. Thus, the future is promising in regard to illuminating the subtleties of the role of Ang II in body fluid balance.