Oxytocin antagonist disrupts hypotension-evoked renin secretion and other responses in conscious rats.

Previous experiments have indicated that arterial hypotension increases plasma oxytocin (OT) levels in rats and that OT infused intravenously causes an increase in plasma renin activity (PRA). The goal of the present study was to determine whether systemic administration of an OT receptor antagonist would attenuate the increase in PRA that is normally evoked by arterial hypotension in rats. In conscious male rats, intravenous injection of hydralazine or diazoxide produced sustained hypotension and evoked a significant increase in PRA, as expected. Intravenous infusion of an OT receptor antagonist did not alter the hypotension induced by hydralazine or diazoxide, but it did markedly blunt the induced increase in PRA. The OT receptor antagonist also blunted the hypotension-evoked increase in heart rate and plasma vasopressin levels, suggesting that the antagonist may have generally disrupted afferent signaling of hypotension. Thus hypotension-evoked OT secretion may contribute to cardiovascular homeostasis by enhancing baroreceptor signals that stimulate increases in renin secretion, vasopressin secretion, and heart rate during arterial hypotension in rats.

Osmoregulation in water-deprived rats drinking hypertonic saline: effect of area postrema lesions.

Rats drank rapidly when 0.3 M NaCl was the only drinking fluid available after overnight water deprivation, consuming approximately 200 ml/24 h. Although such large intakes of this hypertonic solution initially elevated plasma osmolality, excretion of comparable volumes of urine more concentrated than 300 meq Na(+)/l ultimately appears to restore plasma osmolality to normal levels. Rats drank approximately 100 ml of 0.5 M NaCl after overnight water deprivation, but urine Na(+) concentration (U(Na)) did not increase sufficiently to achieve osmoregulation. When an injected salt load exacerbated the initial dehydration caused by water deprivation, rats increased U(Na) to void the injected load and did not significantly alter 24-h intake of 0.3 or 0.5 M NaCl. Rats with lesions of area postrema had much higher saline intakes and lower U(Na) than did intact control rats; nonetheless, they appeared to osmoregulate well while drinking 0.3 M NaCl but not while drinking 0.5 M NaCl. Detailed analyses of drinking behavior by intact rats suggest that individual bouts were terminated by some rapid postabsorptive consequence of the ingested NaCl load that inhibited further NaCl intake, not by a fixed intake volume or number of licks that temporarily satiated thirst.

Acute hypertension inhibits thirst stimulated by ANG II, hyperosmolality, or hypovolemia in rats.

The present study sought to determine whether increases in arterial blood pressure inhibited drinking behavior evoked by ANG II, hyperosmolality, or hypovolemia in rats. Cumulative water intakes in 60- or 90-min tests and latency to the first lick were recorded as indexes of thirst. During intravenous infusions of 100 ng. kg(-1). min(-1) ANG II, attenuation of the induced increases in arterial pressure with the arteriolar vasodilator diazoxide resulted in greater water intakes and shorter latencies to drink. Drinking behavior stimulated by intravenous infusion of hypertonic saline was significantly inhibited by increases in arterial pressure caused by intravenous infusion of phenylephrine or endothelin-1, and this inhibition of drinking was proportional to the induced increase in pressure. Upon termination of the phenylephrine infusion, mean arterial pressure returned to basal values, and drinking was restored. Phenylephrine-induced increases in arterial pressure also inhibited drinking behavior in response to hypovolemia that could not be explained by differences in plasma renin activity, plasma protein concentration, or plasma osmolality. Thus increases in arterial pressure inhibit water drinking behavior in response to each of these three thirst stimuli in rats.

Thirst.

The homeostasis of body fluid traditionally is viewed as involving the regulation of its osmolality and of blood volume. However, the control of thirst is more complex than can be described in a two-factor model, and consideration of plasma sodium concentration and of arterial blood pressure also must be included in the discussion. This review is organized around those four variables and focuses on the seven distinct signals that appear to influence water intake in rats. These signals include four that are excitatory for thirst: increased plasma osmolality detected by cerebral osmoreceptors, decreased blood volume presumably detected by cardiac stretch receptors, increased circulating levels of angiotensin II detected by angiotensin II receptors in the subfornical organ, and increased gastric sodium load apparently detected by putative sodium receptors in the abdominal viscera. There also appear to be three signals that inhibit thirst: decreased plasma osmolality detected by cerebral osmoreceptors, increased arterial blood pressure detected by arterial baroreceptors, and increased gastric water load apparently detected by putative sodium receptors in the abdominal viscera.

Water ingestion provides an early signal inhibiting osmotically stimulated vasopressin secretion in rats.

Dehydrated dogs are known to inhibit secretion of vasopressin (VP) within minutes after drinking water, before plasma osmolality (P(osmol)) diminishes. The present studies determined whether water ingestion causes a similar rapid inhibition of neurohypophyseal hormone secretion in rats. Adult rats were infused with 1 M NaCl (2 ml/h iv) for 240 min to stimulate VP and oxytocin (OT) secretion. After 220 min of infusion, rats were given water to drink for 5 min, and blood samples were taken 5 and 15 min later for RIA. Plasma VP (pVP) was much lower when rats ingested water than when they drank nothing even though P(osmol) was not significantly altered. Plasma OT (pOT) was affected similarly. In contrast, no effects on pVP or pOT occurred when rats drank isotonic NaCl solution for 5 min in amounts comparable to the water intakes (approximately 5.5 ml). These results suggest that neurohypophyseal secretion of VP and OT in rats is inhibited rapidly by water drinking, and that this inhibition is mediated by a visceral signal of osmotic dilution rather than by the act of drinking per se.

Role of renin-angiotensin system in hypotension-evoked thirst: studies with hydralazine.

Injection of rats either with diazoxide (25 mg/kg iv), isoproterenol (0.33 mg/kg sc), or hydralazine (HDZ) (10 mg/kg ip) decreased arterial blood pressure from approximately 120 to 70-80 mmHg and stimulated renin secretion. However, diazoxide and isoproterenol treatments each stimulated water ingestion, whereas HDZ treatment did not. HDZ treatment did not reduce water intake evoked by systemic injection of hypertonic saline or 20% polyethylene glycol solution or by 24-h water deprivation, suggesting that HDZ treatment did not interfere with drinking behavior. In contrast, HDZ treatment markedly reduced water intake evoked by injection of diazoxide or isoproterenol or by intravenous infusion of renin. Furthermore, a highly significant correlation was observed when plasma ANG II levels were plotted as a function of plasma renin activity after intravenous infusion of renin and after diazoxide and isoproterenol treatments. However, values obtained after HDZ treatment alone or in combination with intravenous infusion of renin did not fall near the 99% confidence interval of the regression line, suggesting that HDZ treatment blocks ANG II production and/or promotes its clearance. Thus rats apparently do not increase water intake after HDZ treatment, because this drug interferes with the renin-angiotensin system. These results provide further evidence that arterial hypotension evokes thirst in rats predominantly by activation of the renin-angiotensin system.

Nucleus of the solitary tract lesions enhance drinking, but not vasopressin release, induced by angiotensin.

Rats with chronic nucleus of the solitary tract lesions (NTS-X) drink water and release vasopressin (VP) in response to reduced blood volume despite an absence of neural signals from cardiac and arterial baroreceptors. The present study determined whether rats with NTS-X have a greater sensitivity to circulating ANG II, which may contribute to the drinking and VP responses to hypovolemia. In conscious control rats and rats with NTS-X, ANG II was infused intravenously for 1 h at 10, 100, or 250 ng. kg(-1). min(-1). At the two higher doses, ANG II stimulated more water intake with a shorter latency to drink in rats with NTS-X than in control rats. In contrast, infusion of ANG II produced comparable increases in plasma VP in the two groups. At the two higher doses, ANG II produced an enhanced increase in arterial pressure (AP) in rats with NTS-X, and the bradycardia seen in control rats was reversed to a tachycardia. Infusion of hypertonic saline, which did not alter AP or heart rate, produced comparable drinking and VP release in the two groups. These results demonstrate that chronic NTS-X increases the dipsogenic response of rats to systemic ANG II but has no effect on ANG II-induced VP release or the osmotic stimulation of these responses.

Vasopressin and oxytocin release evoked by NaCl loads are selectively blunted by area postrema lesions.

The present study investigated the effect of area postrema lesions (APX) on stimulated neurohypophysial secretion of vasopressin (VP) and oxytocin (OT) in conscious rats. Blunted increases in plasma levels of both pituitary hormones were observed when rats with APX were infused intravenously with 1 M NaCl solution (2 ml/h for 6 h). In contrast, plasma VP and OT increased normally in rats with APX when equivalent increases in plasma osmolality (but not plasma Na(+)) resulted from intravenous infusion of an equiosmotic solution of 1 M mannitol and 0.5 M NaCl. Furthermore, APX did not affect increases in plasma VP and OT stimulated by plasma volume deficits, nor did APX disrupt OT secretion stimulated by intravenous injection of cholecystokinin. These findings suggest that the area postrema plays an important role in mediating secretion of VP and OT in response to an NaCl load, but not in response to an equiosmotic load that does not cause substantial hypernatremia, and not in response to other stimuli of neurohypophysial hormone secretion. Together with previous reports, these results suggest that APX impairs Na(+) regulation in rats.

Oxytocin-induced renin secretion in conscious rats.

Arterial hypotension and hypovolemia are known to stimulate neurohypophysial secretion of oxytocin (OT) in rats, although the physiological function of OT under these circumstances is uncertain. We now report that OT infused intravenously into conscious rats at 125 ng x kg(-1) x h(-1), a dose selected to mimic plasma OT levels during hypotension or hypovolemia, increased plasma renin concentration and plasma renin activity by twofold. This effect was prevented by systemic pretreatment with an OT receptor antagonist [[1-(3-mercaptopropionic acid)-2-O-ethyl-D-Tyr-Thr(4)-Orn(8)]-OT]. The OT antagonist did not block renin secretion induced by systemic injection of the beta-adrenergic receptor agonist isoproterenol, indicating that the OT antagonist does not interfere nonselectively with renin release. Pretreatment of rats with the beta-adrenergic receptor antagonist nadolol also prevented OT-induced renin secretion. Similarly, nadolol injected during infusion of OT markedly reduced the elevated plasma renin levels. These observations raise the possibility that pituitary OT secretion during hypotension or hypovolemia in rats may serve to support blood pressure by enhancing activation of the renin-angiotensin system via a beta-adrenergic receptor-dependent mechanism.

Impaired osmoregulatory responses in rats with area postrema lesions.

Area postrema lesions (APX) in adult male rats produced a robust spontaneous intake of 0.5 M NaCl, as reported previously. The largest NaCl intakes (up to 108 ml/day) were observed when there was little incidental damage in the medial subnucleus of the nucleus of the solitary tract adjacent to the caudal and middle portions of the area postrema. Rats with discrete APX also drank substantial amounts of 0.5 M NaCl when access to saline was restricted to 7 h/day (up to 30 ml in 1 h, 48 ml in 7 h). Such large NaCl intakes stimulated considerable water ingestion and renal sodium excretion, but together these responses usually were insufficient for osmoregulation during the 7-h test period. After systemic administration of hypertonic NaCl solution, rats with APX excreted less Na(+) in urine and secreted less vasopressin and oxytocin than control rats did. The prominent salt appetite, insufficient thirst and natriuresis in response to an ingested NaCl load, and blunted natriuresis and neurohypophysial hormone secretion in response to an injected NaCl load, all indicate that osmoregulatory responses are impaired in rats after APX.

Sodium excretion and renin secretion after continuous versus pulsatile infusion of oxytocin in rats.

Neurohypophyseal oxytocin (OT), secreted continuously under conditions of hyperosmolality, is a potent natriuretic hormone in rats. In contrast, OT secretion during lactation is pulsatile and is not accompanied by increased urinary Na+ excretion. The present experiments compared the effects of continuous and pulsatile infusion of OT on natriuresis in rats. In male rats anesthetized with Inactin, continuous infusion of OT (125 ng/kg x h) increased plasma OT to about 70 pg/ml; renal Na+ excretion increased 10-fold, and urine volume and K+ excretion also were elevated. However, when OT was administered i.v. in the same amount but in pulses given once every 5 or 10 min, to simulate the pattern of OT secretion during lactation, rats did not excrete significantly more urine, Na+, or K+ than did vehicle-treated animals. The plasma renin concentration, measured in these experiments because OT receptors are present in the macula densa, increased 2-fold when OT was infused either continuously or in pulses. These results indicate that the effects of OT administration on urinary Na+ excretion in rats varies depending on whether the infusion is pulsatile or continuous, whereas the effects of OT on renin secretion show no such difference.

Thirst and salt appetite elicited by hypovolemia in rats with chronic lesions of the nucleus of the solitary tract.

Cardiac vagal afferents terminating in the nucleus of the solitary tract (NTS) are believed to participate in stimulating neurohypophysial secretion of vasopressin as well as increased ingestion of water and NaCl solution in response to decreased blood volume. However, we recently reported that chronic lesions of NTS, which eliminate neural input from cardiac and arterial baroreceptors, do not impair hypovolemia-induced vasopressin secretion in rats. In the present investigation we sought to determine whether those sensory signals were necessary for hypovolemia-induced thirst and salt appetite. Rats with chronic lesions of the NTS increased consumption of water and NaCl solution normally when plasma volume was reduced isosmotically by subcutaneous injection of polyethylene glycol solution. These results were obtained whether rats were allowed to drink water or 0.15 M NaCl in one-bottle tests or water and 0.5 M NaCl in two-bottle tests. The induction of thirst and salt appetite by hypovolemia despite the apparent loss of neural input to the brain from cardiac volume-sensitive receptors indicates that other signals generated by plasma volume deficits can stimulate these behavioral responses in rats.

Medullary c-Fos activation in rats after ingestion of a satiating meal.

The distribution and chemical phenotypes of hindbrain neurons that are activated in rats after food ingestion were examined. Rats were anesthetized and perfused with fixative 30 min after the end of 1-h meals of an unrestricted or rationed amount of food, or after no meal. Brain sections were processed for localization of the immediate-early gene product c-Fos, a marker of stimulus-induced neural activation. Hindbrain c-Fos expression was low in rats that ate a rationed meal or no meal. Conversely, c-Fos was prominent in the medial nucleus of the solitary tract (NST) and area postrema in rats that ate to satiety. There was a significant positive correlation between postmortem weight of gastric contents and the proportion of NST catecholaminergic neurons expressing c-Fos. Cells in the ventrolateral medulla (VLM) were not activated in rats after food ingestion, in contrast with previous findings that stimulation of gastric vagal afferents with anorexigenic doses of cholecystokinin activates c-Fos expression in both NST and VLM catecholaminergic cells. These findings indicate that anatomically distinct subsets of hindbrain catecholaminergic neurons are activated in rats after food ingestion and that activation of these cells is quantitatively related to the magnitude of feeding-induced gastric distension.

Decreases in arterial pressure activate oxytocin neurons in conscious rats.

Hemorrhage and nonhypotensive hypovolemia are known to increase plasma levels of oxytocin (OT) and vasopressin (VP) in rats. The present experiments demonstrated that secretion of OT and VP also are stimulated by acute drug-induced hypotension. Injection of hydralazine abruptly decreased arterial blood pressure in conscious rats and induced Fos expression, a marker of neuronal activation, within OT and VP neurons in the hypothalamus. Hydralazine also elicited substantial increases in plasma levels of both OT and VP. Injection of chlorisondamine similarly elicited acute hypotension and increased plasma levels of OT and VP. Furthermore, when the hypotensive effect of chlorisondamine was blunted by coinfusion of phenylephrine, the induced increases in OT and VP were markedly attenuated. Across all treatments, arterial blood pressure was inversely related to plasma levels of OT and VP. Plasma osmolality was not increased by hydralazine, nor was there evidence of gastric malaise, two known stimuli for OT secretion in rats. These results suggest that arterial hypotension increases neurohypophysial release of OT and VP in conscious rats.

Central c-Fos expression in neonatal and adult rats after subcutaneous injection of hypertonic saline.

Centrally-mediated responses to plasma hyperosmolality include compensatory drinking and pituitary secretion of vasopressin and oxytocin in both adult and neonatal rats. However, the anorexia that is produced by plasma hyperosmolality in adult rats is not evident in neonates, perhaps due to functional immaturity of osmoresponsive hindbrain circuits. To examine this possibility, the present study compared treatment-induced brain expression of the immediate-early gene product c-Fos as a marker of neural activation in adult and two-day-old rats after subcutaneous injection of 2 M NaCl (0.1 ml/10 g body weight). This treatment produced marked hypernatremia in adult and two-day-old rats without altering plasma volume. Several brain regions (including components of the lamina terminalis, the paraventricular and supraoptic nuclei of the hypothalamus, and the area postrema) were activated to express c-Fos similarly in adult and two-day-old rats after 2 M NaCl injection, consistent with previous reports implicating a subset of these regions in osmotically-stimulated drinking and neurohypophyseal secretion. In contrast, other areas of the brain that were activated to express c-Fos in adult rats after 2 M NaCl injection were not activated in neonates: these areas included the central nucleus of the amygdala, the parabrachial nucleus and catecholamine cell groups within the caudal medulla. This study demonstrates that certain brain regions that are osmoresponsive in adult rats (as defined by induced c-Fos expression) are not osmoresponsive in two-day-old rats. When considered in the context of known differences between the osmoregulatory capacities of adult and neonatal rats, our results are consistent with the idea that osmoresponsive forebrain centres are primarily involved in osmotically-stimulated compensatory drinking and neurohypophyseal secretion, whereas osmoresponsive regions of the hindbrain are important for concomitant inhibition of feeding and gastric emptying.

Rats with area postrema lesions have lengthy eating and drinking bouts when fed ad libitum: implications for feedback inhibition of ingestive behavior.

Ad libitum ingestive behavior of rats with area postrema lesions (APX) was monitored electronically every 6 s for 23 hr. Whereas control rats ate on average 32.2 g of food each day in 16.3 distinct bouts, rats with APX ate comparable amounts of food (28.6 g) in much fewer daily bouts (5.8) that were very large. Controls drank 38.4 ml of water daily in 17.8 bouts, whereas rats with APX consumed more than twice as much water (101.5 ml) in a similar number of bouts (18.5). Controls drank 5.3 ml of 0.5 M NaCl daily in 7.0 bouts, whereas rats with APX consumed 9 times as much saline (45.5 ml) in more bouts (18.2) that were relatively large. These and other results suggest that the area postrema plays an important role in detecting inhibitory signals generated by food or fluid intake and that feeding and drinking bouts may increase in size after APX, because the feedback inhibition provided by those signals is diminished.

Enhanced fluid intake by rats after capsaicin treatment.

These studies examined stimulated fluid intake by rats in which vagally mediated signals of gastric distension were blunted by systemic treatment with the neurotoxin capsaicin, as verified by the loss of cholecystokinin-induced inhibition of feeding. After overnight food deprivation, intake of a 10% sucrose solution by capsaicin-treated rats was greater than that by control rats. Similarly, capsaicin-treated rats drank more water than did control rats when stimulated by plasma hyperosmolality after intraperitoneal administration of hypertonic NaCl or by isosmotic hypovolemia after subcutaneous administration of a hyperoncotic colloidal solution. Finally, during chronic administration of the mineralocorticoid deoxycorticosterone acetate, capsaicin-treated rats consumed more concentrated saline than did control rats. In all tests, intakes by capsaicin-treated rats were significantly greater than those by control rats within 5-15 min. These results suggest that early signals of gastric distension, such as those that occur during normal episodes of food, water, or NaCl intake, may modulate ongoing ingestion and that, with the attenuation of such general inhibitory signals, ingestion continues until gastric distension becomes larger and/or later postgastric signals are detected.

Central inhibition of salt appetite by oxytocin in rats.

Considerable evidence indicates an important role of hormones in the stimulation of fluid consumption. For example, angiotensin II (Ang II), together with afferent neural input from cardiovascular baroreceptors, is well known to stimulate thirst and NaCl intake in rats. Conversely, numerous studies have demonstrated that central oxytocin (OT) provides a stimulus for inhibition of salt appetite. The latter conclusion is supported by the following observations in rats: (a) intracerebroventricular (i.c.v.) injection of OT inhibits salt appetite stimulated by subcutaneous colloid; (b) treatments that inhibit NaCl intake, such as acute hyperosmolality, stimulate pituitary secretion of OT (which is correlated with central release of OT in these studies), whereas treatments that decrease OT secretion, such as systemic injection of deoxycorticosterone and dietary sodium deprivation, potentiate Ang-II-induced NaCl intake; (c) systemic ethanol administration inhibits OT secretion and enhances Ang-II-induced salt appetite; (d) naloxone, which augments stimulated OT secretion, inhibits NaCl appetite induced by colloid treatment, an effect that is abolished by i.c.v. pretreatment with an OT receptor antagonist; and (e) destruction of central neurons bearing OT receptors increases Ang II-induced salt appetite. By mediating the inhibition of NaCl intake in rats, central OT complements the known peripheral effects of OT to facilitate renal sodium excretion.

Area postrema lesions in rats appear to disrupt rapid feedback inhibition of fluid intake.

Area postrema lesions (APX) were produced by vacuum aspiration in adult male rats. After systemic administration of hypertonic saline solutions, significantly more water was consumed by rats with APX than by intact control rats. Similarly enhanced water intake by rats with APX also was observed when marked hypovolemia was induced by s.c. administration of a hyperoncotic colloidal solution. In both conditions, the increased water intake occurred within the first 15 min of the drinking tests. Intakes of liquid diet or 10% sucrose solution after food deprivation by rats with APX also were considerably larger than those of control rats. These and other results suggest that rats with APX experience less inhibition of ingestion while drinking. Thus, the AP may be important for the detection of early, inhibitory signals generated by fluid ingestion, and after its ablation increased drinking may occur because the feedback inhibition provided by such signals is diminished.

Dehydration anorexia in decerebrate rats.

Hypertonic saline (HS) administered intraperitoneally reduced the intake of sucrose solution infused intraorally in tube-fed decerebrate rats, as it did in control animals. Similarly, either intraperitoneal or intravenous HS markedly decreased the intake of laboratory chow by neurologically intact control rats. These observations complement recent findings that lesions of putative osmoreceptors in the ventral diencephalon, which eliminate thirst and blunt pituitary secretion of vasopressin and oxytocin in response to HS in rats, have no apparent effect on the HS-induced inhibition of food intake. Taken together they support previous studies indicating an important role for the caudal brainstem in the central control of food intake and suggest that such brainstem control may also include the inhibition of food intake induced by acute hyperosmolality.