Cellular and extracellular dehydration, and angiotensin as stimuli to drinking in the common iguana Iguana iguana

Update on common nutritional disorders of captive reptiles

Nutritional disorders of captive reptiles remain very common despite the increasing knowledge about reptile husbandry and nutrition. Many nutritional disorders are diagnosed late in the disease process; often secondary complications, such as pathologic fractures in reptiles suffering from nutritional secondary hyperparathyroidism have occurred. Therefore, every attempt should be made to educate reptile owners and keepers about the proper care and dietary needs of reptiles under their care because all nutritional disorders seen in captive reptiles are preventable.

Pressor responses to alligator Angiotensin I and some analogs in the spectacled caiman (Caiman crocodilus)

Discovery of the chemical structure of alligator (Alligator mississipiensis) [Asp(1), Val(5), Ala(9)]-Angiotensin I (ANG I) has permitted the investigation of cardiovascular responses to this peptide and its analogs in spectacled caimans (Caiman crocodilus), close relatives of alligators. ANG I and [Asp(1), Val(5)]- Angiotensin II (ANG II) i.v. gave dose-dependent increases in mean arterial pressure but there was no pressor response to [Val(4)]-ANG III (ANG III). Pressor responses to a series of doses of ANG II were compared with a range of doses of norepinephrine (NE) and epinephrine (E) which were found to be only about 1/100 as potent as ANG II on a molar basis. The replacement of d-leu(10)in the alligator ANG I molecule with l-leu(10) almost stopped its conversion to ANG II and attenuated the pressor response. [Asp(1), Val(5), Ala(9)]-ANG I (1-9), and ANG (1-7) both failed to increase arterial blood pressure, even at the relatively high non-physiological test dose of 194pmolkgbw(-1) i.v. Captopril blocked angiotensin converting enzyme (ACE) and prevented the pressor response to ANG I whereas the mammalian AT(1) inhibitor Losartan attenuated, but did not completely block the pressor response to ANG II. These are the first experiments which test the cardiovascular responses to alligator ANG I and its analogues in any crocodilian species.

Effects of dehydration on plasma osmolality, thirst-related behavior, and plasma and brain angiotensin concentrations in Couch's spadefoot toad, Scaphiopus couchii

Under dehydrating conditions, many terrestrial vertebrates species exhibit increases in plasma osmolality and their drinking behavior. Under some circumstances, this behavioral change is accompanied by changes in plasma and central angiotensin concentrations, and it has been proposed that these changes in angiotensin levels induce the thirst-related behaviors. In response to dehydration, the spadefoot toad, Scaphiopus couchii, exhibits thirst-related behavior in the form of cutaneous drinking. This behavior has been termed water absorption response (WR) behavior. Spadefoot toads live in harsh desert environments and are subject annually to dehydrating conditions that may induce thirst-related behavior. We tested the hypothesis that an increase in WR behavior is associated with both an increase in plasma osmolality and an increase in plasma and brain angiotensin concentrations. First, we determined the degree of dehydration that was necessary to initiate WR behavior. Animals dehydrated to 85% of their standard bladder-empty weight via deprivation of water exhibited WR behavior more frequently than control toads left in home containers with water available. Next, using the same dehydration methods, we determined the plasma osmolality and sodium concentrations of dehydrated toads. Toads dehydrated to 85% standard weight also had a significant increase in plasma osmolality, but exhibited no overall change in plasma sodium concentrations, indicating that while an overall increase in plasma osmolality appears to be associated with WR behavior in S. couchii, changes in sodium concentrations alone are not sufficient to induce the behavior. Finally, plasma and brain angiotensin concentrations were measured in control toads and toads dehydrated to 85% standard weight. Plasma and brain angiotensin concentrations did not increase in dehydrated toads, indicating that dehydration-induced WR behavior that is associated with changes in plasma osmolality may not be induced by changes in endogenous angiotensin concentrations in S. couchii.

Intra- and extracellular dehydration has no effect on plasma levels of angiotensin II in an amphibian

Previous studies have demonstrated that both dehydration (intra and extracellular) and treatment with angiotensin II (A-II) induce changes in thirst-related behavior in the spadefoot toad, Scaphiopus couchii. One of the steps in determining a causal relationship between a hormone and a behavior is to determine that there is association between an animal's performance of the behavior and changes in endogenous hormonal concentrations. The hypothesis tested that plasma levels of the peptide hormone A-II would change as a result of dehydration known to induce water absorption response (WR) behavior in the spadefoot toad. Plasma samples were taken from toads dehydrated intracellularly by injection of hypertonic solutions of NaCl or sucrose at levels known to induce WR behavior. As an osmotic control, a group of animals was injected with urea, which has been demonstrated to not induce WR behavior. In order to determine the effects of extracellular dehydration on plasma, A-II levels in toads dehydrated by plasma volume depletion via cardiac puncture were compared to sham-punctured controls. None of the treatments in any experiment resulted in significant differences in plasma levels of angiotensin II among groups sampled at the time when WR behavior occurs. These results do not support the hypothesis that dehydration-induced thirst is stimulated by changes in plasma A-II concentrations at the onset of WR behavior. J. Exp. Zool. 286:343-349, 2000.

Intra- and extracellular dehydration-induced thirst-related behavior in an amphibian

The behavioral response to dehydration is critical to an animal's survival. Because of their permeable skin, amphibians are particularly sensitive to dehydrating conditions. We tested the hypothesis that different forms of dehydration induce water absorption response (WR) behavior in the desert spadefoot toad, Scaphiopus couchii. First, we determined the behavioral response to intracellular dehydration by treating fully hydrated toads with increasing concentrations of hypertonic solutions of NaCl or sucrose via intraperitoneal injection (i.p.). Animals that were treated to induce intracellular dehydration with either solute exhibited a significant increase in WR behavior compared to vehicle-treated controls. To distinguish that the response was a result of an increased osmotic gradient between the intra- and extracellular compartments, we treated fully hydrated animals i.p. with urea, which freely passes into the intracellular compartment and increases overall animal osmolarity. Urea treatment did not induce WR behavior. To determine the response to extracellular dehydration, the blood volume of fully hydrated toads was reduced via cardiac puncture, and the WR behavior was measured. Animals who had a reduction in blood volume exhibited a significant increase in WR behavior compared to sham-punctured controls. Our results are the first to demonstrate that multiple forms of dehydration can induce thirst-related behavior in amphibians.

Effects of homologous atrial natriuretic peptide on drinking and plasma ANG II level in eels

The effects of eel atrial natriuretic peptide (ANP) on drinking were investigated in eels adapted to freshwater (FW) or seawater (SW) or in FW eels whose drinking was stimulated by a 2-ml hemorrhage. An intra-arterial infusion of ANP (0.3-3.0 pmol . kg-1 . min-1), which increased plasma ANP level 1.5- to 20-fold, inhibited drinking dose dependently in all groups of eels. The drinking rate recovered to the level before ANP infusion within 2 h after infusate was replaced by saline. The inhibition at 3.0 pmol . kg-1 . min-1 was profound in FW eels and hemorrhaged FW eels, whereas significant drinking still remained after inhibition in SW eels. Plasma ANG II concentration also decreased dose dependently during ANP infusion and recovered to the initial level after saline infusion in all groups of eels. The decrease at 3.0 pmol . kg-1 . min-1 was large in FW eels and hemorrhaged FW eels compared with that of SW eels. Thus the changes in drinking rate and plasma ANG II level were parallel during ANP infusion. Plasma sodium concentration and osmolality decreased during ANP infusion in SW and FW eels, and they were restored after saline infusion. In hemorrhaged FW eels, however, ANP infusion did not alter plasma sodium concentration and osmolality. Hematocrit did not change during ANP infusion in any group of eels. Collectively, ANP infusion at physiological doses decreased drinking rate and plasma ANG II concentration in parallel in both FW and SW eels. It remains undetermined whether the inhibition of drinking is caused by direct action of ANP or through inhibition of ANG II, which is known as a potent dipsogen in all vertebrate species, including eels.

Angiotensin, thirst, and sodium appetite

Angiotensin (ANG) II is a powerful and phylogenetically widespread stimulus to thirst and sodium appetite. When it is injected directly into sensitive areas of the brain, it causes an immediate increase in water intake followed by a slower increase in NaCl intake. Drinking is vigorous, highly motivated, and rapidly completed. The amounts of water taken within 15 min or so of injection can exceed what the animal would spontaneously drink in the course of its normal activities over 24 h. The increase in NaCl intake is slower in onset, more persistent, and affected by experience. Increases in circulating ANG II have similar effects on drinking, although these may be partly obscured by accompanying rises in blood pressure. The circumventricular organs, median preoptic nucleus, and tissue surrounding the anteroventral third ventricle in the lamina terminalis (AV3V region) provide the neuroanatomic focus for thirst, sodium appetite, and cardiovascular control, making extensive connections with the hypothalamus, limbic system, and brain stem. The AV3V region is well provided with angiotensinergic nerve endings and angiotensin AT1 receptors, the receptor type responsible for acute responses to ANG II, and it responds vigorously to the dipsogenic action of ANG II. The nucleus tractus solitarius and other structures in the brain stem form part of a negative-feedback system for blood volume control, responding to baroreceptor and volume receptor information from the circulation and sending ascending noradrenergic and other projections to the AV3V region. The subfornical organ, organum vasculosum of the lamina terminalis and area postrema contain ANG II-sensitive receptors that allow circulating ANG II to interact with central nervous structures involved in hypovolemic thirst and sodium appetite and blood pressure control. Angiotensin peptides generated inside the blood-brain barrier may act as conventional neurotransmitters or, in view of the many instances of anatomic separation between sites of production and receptors, they may act as paracrine agents at a distance from their point of release. An attractive speculation is that some are responsible for long-term changes in neuronal organization, especially of sodium appetite. Anatomic mismatches between sites of production and receptors are less evident in limbic and brain stem structures responsible for body fluid homeostasis and blood pressure control. Limbic structures are rich in other neuroactive peptides, some of which have powerful effects on drinking, and they and many of the classical nonpeptide neurotransmitters may interact with ANG II to augment or inhibit drinking behavior. Because ANG II immunoreactivity and binding are so widely distributed in the central nervous system, brain ANG II is unlikely to have a role as circumscribed as that of circulating ANG II. Angiotensin peptides generated from brain precursors may also be involved in functions that have little immediate effect on body fluid homeostasis and blood pressure control, such as cell differentiation, regeneration and remodeling, or learning and memory. Analysis of the mechanisms of increased drinking caused by drugs and experimental procedures that activate the renal renin-angiotensin system, and clinical conditions in which renal renin secretion is increased, have provided evidence that endogenously released renal renin can generate enough circulating ANG II to stimulate drinking. But it is also certain that other mechanisms of thirst and sodium appetite still operate when the effects of circulating ANG II are blocked or absent, although it is not known whether this is also true for angiotensin peptides formed in the brain. Whether ANG II should be regarded primarily as a hormone released in hypovolemia helping to defend the blood volume, a neurotransmitter or paracrine agent with a privileged role in the neural pathways for thirst and sodium appetite of all kinds, a neural organizer especially in sodium appetit

Water and NaCl intake of chicks as mediated by angiotensin II, renin, or salt deficiency

Water, feed and NaCl intakes were measured in response to angiotensin II (ANGII) injected SC and ICV, and renin injected ICV, as well as to dietary salt deficiency in female broiler chicks (Gallus domesticus). In the first experiment, SC (100 micrograms/bird) and ICV (10 micrograms/bird) ANGII injection resulted in increased initial water intake. An additive effect on drinking was noted in response to consecutive daily SC injections. In addition, feed efficiency and growth were depressed following repeated ANGII injections (p less than 0.001). In a 2nd experiment, ICV ANGII stimulated increased cumulative water intake through 18 hours postinjection (p less than 0.05). Intake of 3.0% NaCl solution and feed was unaffected through 48 hours. Renin (1 microgram ICV) failed to affect cumulative water intake up to 48 hours postinjection. In the third experiment, dietary salt deficiency reduced feed intake after just 48 hours on salt-deficient diets (p less than 0.01), and growth and feed efficiency were significantly impaired (p less than 0.001) through 20 days of age. Intakes of NaCl solutions (0.8, 0.7 or 0.6%), however, were unaffected in salt-deficient vs. control birds. While the chicks in these experiments demonstrated a consistent drinking response to ANGII when injected peripherally or centrally, a salt appetite could not be elicited in these birds by components of the renin-angiotensin system or by dietary salt depletion.

The renin-angiotensin system and vascular and dipsogenic regulation in elasmobranchs

The role of a renin-angiotensin-like system (RAS) in the regulation of blood pressure and drinking has been investigated in the elasmobranch, Scyliorhinus canicula. Injection of exogenous angiotensin II produced, as expected, a vasopressor response, though injection of the converting enzyme inhibitor, Captopril, alone produced little change in resting blood pressure. Papaverine, a smooth muscle relaxant, reduced blood pressure which completely recovered within 30 min. A subsequent injection of Captopril produced a rapid vasodepressor response with no recovery over 2 hr. The low basal levels of drinking in dogfish were not altered by Captopril injection but angiotensin II-induced increased drinking and papaverine administration resulted in markedly stimulated water intake, which was inhibited by coadministration with Captopril. Captopril inhibition of the recovery in blood pressure and associated dipsogenic response following the papaverine-induced hypotension is consistent with the activation of a RAS-like system in the dogfish. This and other evidence supporting the presence of a RAS-like system in elasmobranchs are discussed in relation to other vertebrates.

Endocrines and osmoregulatory mechanisms in the Nile crocodile, Crocodylus niloticus

The changes in body fluid economy and endocrine status associated with exposure of the Nile crocodile, Crocodylus niloticus, to hypertonic media have been related to the responses to altered renin-angiotensin system (RAS) activity observed in fresh water (FW) animals. Animals held in hypertonic media for 7 days showed a 18.2% body weight loss and raised plasma and urinary sodium, potassium, chloride, and osmotic concentrations. Within 6 hr of return to FW rapid imbibition had largely restored body weight and produced significant plasma dilution. Although plasma sodium, chloride, and osmotic concentrations remained higher than in FW controls, plasma levels of corticosterone, aldosterone, and arginine vasotocin were not significantly altered. Angiotensin I (AI) administration in FW crocodiles stimulated drinking and raised plasma aldosterone levels by comparison with animals given the converting enzyme inhibitor, Captopril, together with AI. The compensatory drinking behaviour exhibited by the Nile crocodile may thus involve the RAS. The RAS also appears to influence interrenal steroidogenesis and thus may afford an integrative role in crocodile fluid management as it does in homeotherms.

The pneumostome rhythm in slugs: a response to dehydration controlled by hemolymph osmolality and peptide hormones

1. One response of the terrestrial slug, Limax maximus to dehydration is the initiation and modulation of the pneumostome rhythm. When a slug has lost 15-20% of its initial body weight by evaporation, the frequency of pheumostome closures, which is less than 0.5 closures/min in fully hydrated slugs, begins to increase. 2. The frequency increases with further dehydration, but the average duration of each closure remains constant. Thus, the proportion of time during which the pneumostome is closed increases. Simultaneously, the area of the pneumostome opening decreases. 3. This behavior appears to be controlled in part by both the osmolality of the slug's hemolymph and by a peptide closely related to arginine vasotocin (AVT) and arginine vasopressin (AVP). Injecting intact slugs with mannitol, which increases the osmolality of the hemolymph, or with AVT or AVP, can initiate the pneumostome rhythm. 4. Mannitol injections, however, do not provoke the decrease in the area of the pneumostome opening which is induced by natural dehydration or by AVT or AVP injection. This suggests that at least two systems may be involved in the overall control of the pneumostome.

Intravenous hypertonic saline injections and drinking in domestic fowls

Fowls were given intravenous (IV) injections of hypertonic solutions of NaCl, and subsequent water intakes were recorded. All concentrations of hypertonic NaCl increased drinking in the 90 min after injection, compared with control treatments. Increments in drinking in this time agreed closely with calculated amounts required to restore normal osmolality. In further experiments, delaying access to water by periods of 60-360 min after injection failed to reduce drinking elicited by hypertonic NaCl. Injections of 2.0 M NaCl caused increases in plasma osmolality and sodium concentration which were maintained throughout 360 min water deprivation, and caused prolonged reductions in hematocrit and plasma protein concentrations. These results demonstrate that cellular dehydration is a potent thirst stimulus in fowls, and imply that fowls do not reduce hyperosmolality by excretion of salt when water is unavailable.

Water uptake by Rana temporaria: effects of diuretics and the renin--angiotensin system, and nephrectomy

Adult Rana temporaria, acclimated to tap water or hyperosmotic (0.9% NaCl saline) media, were injected with Acetazolamide, Frusemide, or Captopril, or were nephrectomized and injected with captopril. Saline-injected animals served as controls. Total water flux and drinking rates were determined by body weight changes and by the rate of accumulation of an environmental marker (phenol red) in the gut, respectively. Changes in plasma corticosteroids and ion concentrations were also assessed. Acetazolamide and frusemide produced hyponatraemia in tap water-acclimated animals, but induced increased aldosterone levels in frogs in both environments. Captopril reduced body weight and aldosterone levels of tap water frogs, but had no effect on plasma ion composition. Animals treated with captopril on immersion in saline had plasma hypoosmotic to their environment. Saline-acclimated frogs drank less environmental water than did those in tap water. Captopril, acetazolamide, and frusemide all stimulated drinking rates of saline-acclimated frogs; captopril, however, had no effect on the drinking rates of nephrectomized animals, indicating that the dipsogenic actions of this drug are probably reflected by inhibition of the renin-angiotensin system. In tap water animals, acetazolamide stimulated drinking, while frusemide stimulated integumental water uptake. No correlation was apparent between plasma aldosterone and corticosterone concentrations, or between changes in body weight and drinking rates. This suggests that there are independent mechanisms controlling aldosterone and corticosterone secretion, as well as integumentary and buccal uptake of water in R. temporaria.

Elevation of the panting threshold of the desert iguana, Dipsosaurus dorsalis, during dehydration: potential roles of changes in plasma osmolality and body fluid volume

Dehydration of the desert iguana, Dipsosaurus dorsalis, resulted in a progressive elevation in the magnitude of the skin temperature necessary to elicit thermal panting (i.e., the panting threshold). Panting threshold increased from 43.4 +/- 0.8 degrees C at 100% initial body weight (IBW) to 45.4 +/- 1.2 degrees C at 90% IBW to 45.7 +/- 0.9 degrees C at 80% IBW. Plasma osmolality showed no significant change with dehydration to 80% IBW. Changes in plasma osmolality, whether induced by NaCl or non-ionic sucrose loading, had a significant impact on panting threshold. Increasing plasma osmolality resulted in an elevation of panting threshold while decreasing plasma osmolality resulted in lower panting thresholds. Decreasing body fluid volume by exsanguination of 1 ml whole blood/100 g body weight resulted in a mean increase in panting threshold by 0.7 +/- 0.2 degrees C. Volume loading with 160 mM NaCl (approximately isosmotic) had no significant effect on panting threshold. These data suggest that plasma osmolality and decreases in body fluid volume may be potent modulators of panting threshold during periods of water deprivation. However, at least in desert iguanas, increases in plasma osmolality would not appear to be an important factor in the elevation of panting threshold during dehydration to 80% IBW.

Control of panting in the desert iguana: roles for peripheral temperatures and the effect of dehydration

Although it is generally held that panting is a physiological mechanism for the regulation of brain temperature during heat stress, a number of studies have pointed to the importance of peripheral input for the initiation of the panting response in a variety of animals. By presenting ambient heat loads of 47 degrees, 54 degrees, 58 degrees, and 65 degrees C, and measuring skin, ear and core temperatures of the desert iguana, Dipsosaurus dorsalis, at the onset of panting, we found that the skin temperature at panting onset was independent of ambient heat load. This suggests that skin (peripheral) temperature is the body temperature on which the central thermoregulatory center cues to initiate thermal panting. Peripheral temperature control of panting was retained when the plasma osmolality of the desert iguana was increased by 100 mOsm/kg H2O to simulate dehydration. Dehydration to 80% initial body weight (IBW) resulted in a progressive increase in panting threshold (skin) from 42 degrees C for untreated lizards to 42.5 degrees C at 90% IBW to 43.3 degrees C at 80% IBW. Injection of 80% IBW lizards with a volume of 10 mM NaCl equivalent to weight loss resulted in a decrease in panting threshold to 40.8 degrees C. Injection with 1% body weight 3000 mM NaCl produced a dramatic increase in panting threshold to 45.9 degrees C. These data suggest that the desert iguana responds to dehydration by elevating panting threshold, thus promoting water conservation. These data also suggest that changes in plasma osmolality may be involved in the "setting" of panting threshold.

Diurnal rhythm of water intake and plasma angiotensin II in the Japanese quail (Coturnix coturnix japonica)

A diurnal rhythm was noted in the hourly water intake of the Japanese quail exposed to a 12L:12D photoperiod. Two peaks for the water intake were observed: from 07:00 to 08:00, 1 hr after turning on the light source, and from 18:00 to 19:00, 1 hr before termination of the light source. The plasma angiotensin II (AII) concentration also showed two peaks: one at 06:00, 1 hr before the light source was turned on, and another at 18:00, 1 hr before the light was turned off. The two plasma AII peaks each occurred 1 hr before those for the water intake, respectively. The drinking rate was reduced by Captopril (SQ14225) administered at 07:05 and 18:14, when the plasma AII concentration and drinking rate were highest. The hematocrit was significantly higher during the dark period than the light period.

Drinking and renal responses to peripherally administered osmotic stimuli in the pigeon (Columbia livia)

Pigeons drank copiously in response to intravenous (I.V.) infusion of approximately equi-osmolar hypertonic solutions of NaCl (0.5 M), sucrose (1.0 M) or mannitol (1.0 M). I.V. infusions of hypertonic glucose (1.0 M) or urea (1.0 M) were less effective in causing drinking. The calculated percentage change in plasma osmolality at the onset of drinking was similar for the three hypertonic solutions, NaCl, sucrose and mannitol, irrespective of the concentration of the solution infused. A greater volume of water was drunk in response to I.V. infusion of 7 ml of 1.0 M-sucrose than in response to a similar volume of 1.0 M-NaCl or mannitol. This appeared to be in response to the large diuresis caused by sucrose infusions. Excretion of the osmotic load was more rapid following I.V. hypertonic sucrose and mannitol than following hypertonic NaCl, glucose or urea in the 10 h of the experiment. In anaesthetized pigeons, I.V. infusion of hypertonic NaCl (0.5 M), sucrose (1.0 M) or urea (1.0 M) caused similar increases in plasma osmolality. The haematocrit was significantly reduced after NaCl or sucrose but not after urea. Plasma Na+ concentration was significantly increased after NaCl, and decreased after sucrose, whereas urea produced little change. Following I.V. hypertonic NaCl or urea, the Na+ concentration of the cerebrospinal fluid (c.s.f.) was increased and its flow reduced compared with isotonic NaCl infusions. Hypertonic sucrose stopped the flow of c.s.f. almost completely during the course of the experiment. These experiments suggest that the drinking and renal responses of pigeons following osmotic stimuli are similar to those of mammals and that they appear to retain Na+.

The renin-angiotensin system and drinking in the euryhaline flounder, Platichthys flesus

Drinking behaviour and its possible regulation by the renin-angiotensin system (RAS) has been examined in the euryhaline flounder. Fluid intake was greater in seawater (SW)-adapted than freshwater (FW)-adapted fish, the latter having significantly lower plasma sodium, chloride, and osmotic concentrations. Oesophageal cannulation in SW-adapted fish resulted in further elevation of drinking rates, which increased proportionally with progressive body water loss as measured by the fall in body weight and rise in plasma tonicity. The influence of the RAS on drinking in SW-adapted fish was examined in animals with an intact gastrointestinal tract. Fluid intake fell markedly following administration of the converting enzyme inhibitor, Captopril. Infusions of angiotensin I (AI) and angiotensin II (AII) induced dose-related increments in the rate of drinking. The increased drinking in response to AI was inhibited, however, by the simultaneous administration of Captopril. The results are consistent with the presence in the flounder of the major elements of the RAS, including AI, AII, and a converting enzyme-like substance. The RAS appears to play an important regulatory role in the adaptative drinking behaviour associated with migration of euryhaline teleosts between FW and SW.

Mechanisms for induction of drinking with special reference to angiotensin II

The Japanese quail drinks water vigorously after water deprivation, haemorrhage and administration of hypertonic saline solution. Most avian species responded to angiotensin II (AII) by drinking, but carnivorous birds and those originating in arid regions were insensitive. The receptive sites for AII were the subfornical organ (SFO) and the preoptic area (POA) in the Japanese quail. Catecholaminergic fibers proceed from the POA to the SFO. Dipsogenic information generated by AII at the POA is transferred to the SFO through the catecholaminergic nerve fibres. Plasma AII increased following dehydration and haemorrhage and returned to a normal level immediately after rehydration. Following dehydration, arginine vasotocin, aldosterone and corticosterone increased in plasma as well as AII. A single intraperitoneal injection of AII induced increases of arginine vasotocin, aldosterone and corticosterone in plasma. It seems that AII functions as a trigger for release of these other hormones during dehydration.

Effects of exogenous angiotensin II in the Atlantic cod, Gadus morhua. Observations on gastric acid secretion, gastric sham drinking and gastric mucosal plasma flow (14C-aniline clearance)

Cods were equipped with cannulae for drainage of the stomach and for the separate perfusion of the stomach (pure seawater containing phenol red as a volume marker) and intestine (diluted seawater). Acidity of the gastric effluence was titrated, its volume calculated from the phenol red concentration. Gastric mucosal plasma flow (MPF) was estimated by gastric 14C-aniline clearance. I.m. injection of angiotensin II (AII) depressed basal acid secretion in a dose-dependent fashion. Also the MPF was reduced, but relatively less than the secretory depression. Therefore, the AII-induced secretory inhibition could not be explained by restrained mucosal blood flow. Perfusion of the intestine with diluted seawater, or a continuous i.m. infusion of 0.6% NaCl both rendered the fishes non-drinking. A high dose of AII (150 micrograms/kg . h) induced drinking in intestinally perfused cod while lower doses (15, 50 micrograms/kg . h) did not. In i.m. saline-injected cod, all three doses were dipsogenic. The results suggest that 0.6% saline infusion induces a permanent satiety and that intestinal perfusion in addition induces a preabsorptive satiety. The preabsorptive satiety appears more resistant to the dipsogenic action of AII than the permanent one.

Drinking and changes in blood pressure in response to angiotensin II in the pigeon Columba livia

1. Angiotensin II is as potent a stimulus to drink in pigeons as it is in mammals. There are striking similarities in the action of this peptide in pigeons and mammals. 2. Angiotensin II injected intracranially, I.V. or I.P. consistently caused short-latency and vigorous drinking in pigeons but no other behaviour. Drinking was completed rapidly and intakes were very large, sometimes in excess of 10% of the bird's body weight. 3. The latency to drink and the amount drunk were dose dependent for all routes of injection. Angiotensin II was most effective when injected directly into the brain. As little as 10(-4) mol angiotensin II injected into the cerebral ventricles caused birds to drink. 4. The rapid cessation of drinking after intracranial injection of angiotensin II was not caused by rapid loss of activity of the peptide in the brain but by the actual ingestion of the water. 5. The brain sites most sensitive to the dipsogenic action of angiotensin II in the pigeon were the dorsal and ventral third ventricle, the tissue adjacent and anterior to these sites, and the lateral ventricles. The lateral hypothalamic area was only slightly less sensitive. Negative sites for drinking were found in the lateral forebrain and the hind brain. These findings are similar to those in mammals. 6. Pigeons drank during I.V. infusion of as little as 16 X 10(-12) mol angiotensin II kg-1 min-1. This was near the threshold for increasing arterial pressure in pigeons and is near the threshold for drinking in rats and dogs. 7. The Asn1, Asp1, Val5 and Ile5 analogues of angiotensin II were equipotent as stimuli to drink but a wide range of other peptides and drugs injected into the brain failed to increase water intake. An exception was eledoisin which was, comparing molecule with molecule, only 10-100 times less potent than angiotensin II in the pigeon. 8. Injections of angiotensin II into brain sites which caused drinking failed to alter heart rate or arterial pressure in pigeons. 9. This and other recent studies demonstrate the wide phylogenetic distribution of the dipsogenic action of angiotensin II and support the idea that the control of water intake is an important physiological function of the renin-angiotensin system in vertebrates.

The mechanism of drinking induced by parenteral hyperonocotic solutions in the pigeon and in the rat

1. In pigeons, the I.V. injection of 0.3-1.3 ml. of 50% (w/w) solutions of either polyethylene glycol (mol.wt. 20,000) or dextran (mol.wt. 40,000) induced reliable, rapid dose-dependent drinking responses. The amount of water drunk in response to I.V. polyethylene glycol was greater than that in response to I.P. polyethylene glycol and twice that in response to I.V. dextran. I.V. polyethylene glycol induced a diuresis following the onset of drinking.2. The dipsogenic effect of I.P. polyethylene glycol solutions in the pigeon was depressed by I.V. isotonic NaCl solution 1 hr before offering water but was increased by simultaneous I.V. hyperoncotic polyethylene glycol solution.3. In contrast, in rats, the subcutaneous injection of 25% (w/w) polyethylene glycol (mol.wt. 20,000; 1.25-10.0 ml./kg body wt.) induced reliable drinking responses, while the same doses of polyethylene glycol, injected I.V., did not induce drinking consistently. The volume of water drunk by rats in response to subcutaneous polyethylene glycol was smaller per unit dose than that drunk by I.P. injected pigeons.4. The results suggest that receptors for drinking induced by extracellular dehydration in the pigeon could be situated in the extravascular interstitial section of the extracellular compartment.

The role of circulating renin in drinking in response to isoprenaline

1. In nephrectomized rats, S.C. (0.12 mg. kg body wt.(-1)) or intracerebroventricular (I.C.V.: 0.03 mg. kg(-1)), isoprenaline failed to elicit drinking. However, when preceded (5-20 min) by a non-dipsogenic dose of I.V. pig renin, S.C. isoprenaline induced a marked, and I.C.V. isoprenaline a smaller drinking response. 2 hr after I.V. renin, S.C. isoprenaline no longer caused drinking.2. Pig renin did not enhance drinking in response to 0.12 mg. kg(-1) isoprenaline S.C. in intact or sham-operated rats.3. Isoprenaline (0.12 mg. kg body wt.(-1), S.C.) caused a larger fall of blood pressure in unanaesthetized nephrectomized than in intact unanaesthetized rats, but it was not the resulting hypotension that interfered with the nephrectomized rats' ability to drink, since intact rats with similar falls in blood pressure drank avidly in response to large doses of isoprenaline.4. Since the rate of inactivation of pig renin in nephrectomized rats was not modified by isoprenaline, drinking in nephrectomized animals in response to renin+isoprenaline was not attributable to increased plasma renin levels.5. Since isoprenaline induces drinking in the presence of circulating renin, but in the absence of renin release from kidneys, renin plays a permissive role in isoprenaline-induced drinking. Angiotensin and isoprenaline may interact at the level of intracranial receptors.