Inhibition of Dehydration-Induced Water Intake by Glucocorticoids Is Associated with Activation of Hypothalamic Natriuretic Peptide Receptor-A in Rat

Atrial natriuretic peptide (ANP) provides a potent defense mechanism against volume overload in mammals. Its primary receptor, natriuretic peptide receptor-A (NPR-A), is localized mostly in the kidney, but also is found in hypothalamic areas involved in body fluid volume regulation. Acute glucocorticoid administration produces potent diuresis and natriuresis, possibly by acting in the renal natriuretic peptide system. However, chronic glucocorticoid administration attenuates renal water and sodium excretion. The precise mechanism underlying this paradoxical phenomenon is unclear. We assume that chronic glucocorticoid administration may activate natriuretic peptide system in hypothalamus, and cause volume depletion by inhibiting dehydration-induced water intake. Volume depletion, in turn, compromises renal water excretion. To test this postulation, we determined the effect of dexamethasone on dehydration-induced water intake and assessed the expression of NPR-A in the hypothalamus. The rats were deprived of water for 24 hours to have dehydrated status. Prior to free access to water, the water-deprived rats were pretreated with dexamethasone or vehicle. Urinary volume and water intake were monitored. We found that dexamethasone pretreatment not only produced potent diuresis, but dramatically inhibited the dehydration-induced water intake. Western blotting analysis showed the expression of NPR-A in the hypothalamus was dramatically upregulated by dexamethasone. Consequently, cyclic guanosine monophosphate (the second messenger for the ANP) content in the hypothalamus was remarkably increased. The inhibitory effect of dexamethasone on water intake presented in a time- and dose-dependent manner, which emerged at least after 18-hour dexamethasone pretreatment. This effect was glucocorticoid receptor (GR) mediated and was abolished by GR antagonist RU486. These results indicated a possible physiologic role for glucocorticoids in the hypothalamic control of water intake and revealed that the glucocorticoids can act centrally, as well as peripherally, to assist in the normalization of extracellular fluid volume

Arginine-vasopressin content of hippocampus and amygdala during passive avoidance behavior in rats

Arginine-vasopressin (AVP) is involved in memory processes. The memory effects of AVP are mediated by neuronal mechanisms taking place in limbic-midbrain structures. Therefore, immunoreactive AVP (IR-AVP) was measured in hippocampus and amygdala of male Wistar rats during acquisition and retention of passive avoidance behavior. IR-AVP concentration was decreased in the hippocampus immediately after the learning trial while IR-AVP content of the amygdala was not affected. Animals that showed the passive avoidance response (good avoiders) at the 24 h or 120 h retention test had a reduced IR-AVP concentration in the hippocampus immediately after the test. However, IR-AVP content of the hippocampus was not different from that of non-shocked control animals when measured immediately before the 120 h retention test. Poor avoiders that showed only minor avoidance behavior did not differ in hippocampal IR-AVP content from non-shocked control animals. IR-AVP content of the amygdala was also not altered after the retention session. These effects on IR-AVP content could only be shown in animals that were trained and habituated to the passive avoidance procedure. Such trained and habituated animals had an IR-AVP level in the hippocampus which did not differ from that of animals that were left undisturbed until sacrifice. When the animals were not trained, but place for the first time in the passive avoidance apparatus without being exposed to the learning trial, the hippocampal IR-AVP content was reduced. Under these circumstances additional exposure to the electric footshock did not lead to a measurable further decrease in IR-AVP content of the hippocampus. Again, IR-AVP content of the amygdala was not affected. It is proposed that learning and retention of a passive avoidance response is associated with a reduction in hippocampal IR-AVP content. The reduction ppossibly reflects increased secretory activity at the peptidergic terminal. This AVP released at the terminal might be instrumental in facilitating memory formation

Arginine-vasopressin content of hippocampus and amygdala during passive avoidance behavior in rats

Arginine-vasopressin (AVP) is involved in memory processes. The memory effects of AVP are mediated by neuronal mechanisms taking place in limbic-midbrain structures. Therefore, immunoreactive AVP (IR-AVP) was measured in hippocampus and amygdala of male Wistar rats during acquisition and retention of passive avoidance behavior. IR-AVP concentration was decreased in the hippocampus immediately after the learning trial while IR-AVP content of the amygdala was not affected. Animals that showed the passive avoidance response (good avoiders) at the 24 h or 120 h retention test had a reduced IR-AVP concentration in the hippocampus immediately after the test. However, IR-AVP content of the hippocampus was not different from that of non-shocked control animals when measured immediately before the 120 h retention test. Poor avoiders that showed only minor avoidance behavior did not differ in hippocampal IR-AVP content from non-shocked control animals. IR-AVP content of the amygdala was also not altered after the retention session. These effects on IR-AVP content could only be shown in animals that were trained and habituated to the passive avoidance procedure. Such trained and habituated animals had an IR-AVP level in the hippocampus which did not differ from that of animals that were left undisturbed until sacrifice. When the animals were not trained, but place for the first time in the passive avoidance apparatus without being exposed to the learning trial, the hippocampal IR-AVP content was reduced. Under these circumstances additional exposure to the electric footshock did not lead to a measurable further decrease in IR-AVP content of the hippocampus. Again, IR-AVP content of the amygdala was not affected. It is proposed that learning and retention of a passive avoidance response is associated with a reduction in hippocampal IR-AVP content. The reduction ppossibly reflects increased secretory activity at the peptidergic terminal. This AVP released at the terminal might be instrumental in facilitating memory formation

Levels of arginine-vasopressin in cerebrospinal fluid during passive avoidance behavior in rats

The concentration of immunoreactive arginine-vasopressin (IR-AVP) was measured in the cerebrospinal fluid (CSF) during acquisition and retention of passive avoidance behavior. IR-AVP level in CSF of male Wistar rats immediately after the learning trial was increased; the rate of which was related to the intensity of the electric footschock during the learning trial and the avoidance latency as measured 1 day after the learning trial. Immediately after the 24 h retention test IR-AVP levels were significantly increased in rats subjected to the low (0.25 mA) shock intensity during the learning trial, but IR-AVP levels of rats exposed to the high shock (1.0 mA) were under the limit of detection. If the retention test was postponed till 5 days after the learning trial, the increase of IR-AVP level in the CSF was related to avoidance latencies which reflect the intensity of aversive stimulation (electric footshock). The results suggest an association between central AVP release and passive avoidance behavior and may be indicative of the role of this peptide in neuronal mechanisms underlying learning and memory processes

The role of central corticoliberin in the ether stress-induced secretion of neurohypophyseal hormones and corticosterone in the rat

As corticotropin-releasing factor (CRF) and oxytocin (OXT) are released in response to various stressors and a role of CRF in stress-induced OXT secretion has been proposed by previous authors, the present experiments were scheduled to investigate the participation of the brain CRF system in the stress-evoked release of OXT, arginine-8-vasopressin (AVP) and corticosterone. CRF-antiserum (AS) was given into the lateral ventricle of the brain of Wistar male rats, and 24 h later, the injection was repeated 30 min prior to ether stress followed by decapitation in 5 min. Plasma OXT and AVP were measured by radioimmunoassay and corticosterone by fluorimetry. Ether stress increased the levels of corticosterone and OXT, but not that of AVP. CRF-AS alone did not change the secretion of these hormones. CRF-AS pretreatment blocked the corticosterone-releasing action of ether stress, whereas it exerted no influence on the stress-induced OXT secretion into the circulation. There was no effect of a combined application of CRF-AS and stress on the plasma AVP level. These results suggest that the central CRF system is involved in the ether stress-elicited corticosterone response, however CRF is unlikely to be connected with the regulation of OXT secretion under these experimental conditions