The relationship of saline-induced changes in vasopressin secretion to basal and corticotropin-releasing hormone-stimulated adrenocorticotropin and cortisol secretion in man

To investigate the effect of endogenous arginine vasopressin (AVP) on ACTH secretion, normal subjects were given infusions of either hypertonic saline (HS) or isotonic saline (NS) combined with human corticotropin-releasing hormone (CRH) or placebo. Basal plasma AVP was 2.3 +/- 0.3 (+/- SE) pg/ml, did not change with NS treatment, and rose to 5.4 +/- 0.6 pg/ml during HS infusion (P less than 0.01). Both basal and CRH-stimulated plasma ACTH and cortisol concentrations increased during HS infusion. Peak plasma ACTH and cortisol levels were 11.4 +/- 1.5 pg/ml and 8.6 +/- 0.8 micrograms/dl, respectively, during the HS (plus placebo) infusion. During the NS (plus placebo) infusion, plasma ACTH and cortisol gradually declined to 6.8 +/- 0.5 pg/ml and 2.6 +/- 0.4 micrograms/dl. The timing of the rise in ACTH during the HS infusion paralleled the rise in AVP. When an iv dose of 1 microgram/kg CRH was administered during the saline infusions, peak plasma ACTH and cortisol levels were 27.7 +/- 6.3 pg/ml and 17.5 +/- 1.0 micrograms/dl, respectively, during the HS infusion and 15.6 +/- 1.7 pg/ml and 13.4 +/- 1.2 micrograms/dl during the NS infusion. When the areas under the hormone response curves were compared, CRH stimulated ACTH and cortisol secretion to a greater extent than did HS (P less than 0.05). The hormonal stimulation due to combined CRH and hypertonic saline was greater than that attributable to either factor alone (P less than 0.025), but was not different than the sum of the effects of the individual factors. These results indicate that increases in endogenous AVP produced by HS are associated with increases in both basal and CRH-stimulated ACTH and cortisol release. The effect of HS appears to be additive to but not consistently synergistic with the effect of CRH.     

The physiological significance of arginine vasopressin in potentiating the response to corticotrophin-releasing factor in sheep

In order to assess the physiological importance of endogenous arginine vasopressin (AVP) in augmenting the ACTH response to corticotrophin-releasing factor (CRF), the response to CRF during hypertonic saline infusion in six Coopworth sheep was examined. A 4-h infusion of 5% (w/v) NaCl (3.8 ml/min) resulted in significantly (P less than 0.01) greater rises in ACTH and cortisol, but not aldosterone, than were observed after CRF alone. Infusion of hypertonic saline without CRF resulted in a highly significant (P less than 0.001) rise in plasma osmolality and AVP but no significant change in plasma ACTH, cortisol or aldosterone. It is concluded that a marked but physiological increase in peripheral (and presumably central) levels of AVP does not result in any demonstrable change in plasma ACTH concentration. However, under these conditions, the ACTH and cortisol responses to CRF are considerably augmented.     

Galaninergic mechanisms are involved in the regulation of corticotropin and thyrotropin secretion in the rat.

Galanin (GAL), a 29-amino acid peptide, affects the secretion of several anterior pituitary hormones, including PRL and GH. Since GAL coexists with vasopressin and CRH in the hypothalamic paraventricular nucleus (PVN), we have studied the pharmacological and physiological actions of GAL on ACTH and TSH secretion in freely moving male rats. Cannulae were surgically implanted in the right atria and brain, intraventricular or adjacent to the PVN, of adult Sprague-Dawley rats. Seven days later, GAL (500 or 1000 ng) or saline was infused into the PVN, and serial blood samples were obtained 5, 10, 20, and 40 min after the infusion. Some animals were also stressed by the inhalation of ether vapors for 2 min after the PVN infusion. Basal ACTH concentrations were increased 2-fold in saline-treated rats; however, plasma ACTH levels were unchanged after GAL infusion. The exposure of rats to ether vapors for 2 min after the infusion of saline into the PVN increased plasma ACTH concentrations from 22.8 +/- 6.0 to 596.6 +/- 59.9 pg/ml 10 min later. However, the infusion of GAL into the PVN attenuated stress-induced ACTH secretion. After GAL infusion, peak ACTH levels (332.7 +/- 84.0 pg/ml) were attained 5 min after ether exposure, followed by a rapid decline at 10 min (P less than 0.001) and 20 min (P less than 0.05). Plasma TSH concentrations were unchanged by GAL or saline infusion and were not affected by ether vapor inhalation. To determine the physiological significance of GAL in the control of ACTH and TSH secretion, endogenous GAL was immunoneutralized by the infusion of 3 microliters GAL antiserum (GAL-AS) into the third cerebral ventricle 25 and 1 h before withdrawing blood samples every 15 min for 6 h. Animals treated with normal rabbit serum (NRS) served as controls. Plasma ACTH concentrations were unchanged by NRS during the 6-h period. However, infusion of GAL-AS raised plasma ACTH concentrations to over 400 pg/ml 75 min after infusion in some animals. In general, plasma ACTH concentrations were increased 4 h of the 6-h sampling period compared to levels in NRS-treated controls. In contrast, GAL-AS reduced TSH concentrations by 50% compared to control values. In contrast to these marked actions of centrally administered GAL, ACTH secretion from dispersed anterior pituitary cells in vitro was unaffected by GAL in concentrations up to 10(-6) M. Furthermore, GAL did not alter CRH (1 nM)-induced ACTH secretion.(ABSTRACT TRUNCATED AT 400 WORDS)     

Histamine- and stress-induced secretion of ACTH and beta-endorphin: involvement of corticotropin-releasing hormone and vasopressin.

Histamine (HA) stimulates the release of the pro-opiomelanocortin (POMC)-derived peptides ACTH, beta-endorphin (beta-END), beta-lipotropin and alpha-melanocyte-stimulating hormone, and HA is involved in the mediation of the stress-induced release of these peptides. The effect of HA is indirect and may involve the hypothalamic regulating factors, corticotropin-releasing hormone (CRH) and/or arginine-vasopressin (AVP). We studied the effect of immunoneutralization with specific antisera against CRH or AVP on the response of ACTH and beta-END to HA, restraint stress, CRH, AVP or a posterior pituitary extract in male rats. Intracerebroventricular infusion of HA (34-540 nmol) increased the plasma levels of ACTH and beta-END immunoreactivity (beta-ENDir) in a dose-dependent manner. Pretreatment with antiserum to CRH or AVP prevented the ACTH response to 270 nmol HA and inhibited the beta-ENDir response by 30-60%. One to five minutes of restraint stress caused an increase in the plasma levels of ACTH and beta-ENDir. The increase was dependent on the duration of stress exposure. Pretreatment with CRH antiserum abolished the ACTH response to 5 min of restraint stress and inhibited the beta-ENDir response by 60%. Immunoneutralization with AVP antiserum had only half the inhibitory effect of that seen with CRH antiserum. CRH (100 pmol i.v.) increased the plasma levels of ACTH and beta-ENDir. This effect was abolished by pretreatment with CRH antiserum, whereas pretreatment with AVP antiserum prevented the CRH-induced ACTH release and inhibited the beta-ENDir response by 50%. AVP (24-800 pmol i.v.) stimulated ACTH and beta-ENDir in a dose-dependent manner. CRH and AVP antisera each prevented the effect of AVP (800 pmol) on ACTH secretion, whereas the beta-ENDir response to AVP was only inhibited by about 60% by the antisera. An extract of the posterior pituitary gland administered in a dose corresponding to 0.15 or 0.5 pituitary equivalents had no effect on ACTH secretion, while 1.0 pituitary equivalent increased the ACTH concentration in plasma. This effect was abolished by AVP antiserum. The posterior pituitary extract caused a dose-dependent rise in plasma beta-ENDir which might be due to an unavoidable contamination of the posterior pituitary extract by a small amount of beta-END from the intermediate lobe. Consistent with this view, AVP antiserum had no effect on the rise in the plasma concentration of beta-ENDir following administration of the posterior pituitary extract.(ABSTRACT TRUNCATED AT 400 WORDS)     

Rapid corticosterone inhibition of corticotropin-releasing hormone binding and adrenocorticotropin release by enriched populations of corticotropes: counteractions by arginine vasopressin and its second messengers

We have demonstrated that anterior pituitary corticotropes can be identified cytochemically by their capacity to bind potent biotinylated analogs of CRH. In addition, 50-80% of corticotropes bind biotinylated arginine vasopressin (AVP). The percentage of CRH-bound cells is rapidly reduced after 1-h exposure to glucocorticoids. However, the rapid effects of glucocorticoids on AVP binding by corticotropes have not been tested. The first aim of this study was to examine the binding capacity of small and large corticotropes enriched to 90% by counterflow centrifugation. Biotinylated analogs of CRH or AVP were detected cytochemically on the cells by avidin-biotin-peroxidase complex protocols. At least 80% of the cells bound CRH after 1 day of culture. More large corticotropes bound AVP (93%) than small corticotropes (80%). AVP pretreatment of large corticotropes stimulated an increase in CRH-bound cells to over 90%, but it had no effect on CRH binding by small corticotropes. Corticosterone pretreatment (100 nM) for 10 min caused a 50% reduction in the percentage of cells that bound CRH and in the levels of ACTH released in response to biotinylated CRH. After 30 and 60 min of pretreatment, the percentages of CRH-bound cells were reduced by 75%, and ACTH levels remained low. No reduction in percentages of AVP-bound cells was evident at any time point after corticosterone pretreatment. These studies stimulated further tests based on previous reports that showed that AVP or its activated second messengers enhanced CRH binding. We reasoned that this potentiation might promote a recovery in CRH binding to corticosterone-inhibited cells. However, 1-h stimulation by AVP or activation of calcium channels (by Bay K 8644) or protein kinase-C by 12-O-tetradecanoyl-phorbol-13-acetate did not restore CRH binding. AVP evoked a partial recovery in ACTH release. Furthermore, Bay K and 12-O-tetradecanoyl-phorbol-13-acetate pretreatment effectively blocked the fast feedback effects of corticosterone on CRH-mediated ACTH release. Thus, these studies demonstrate that glucocorticoids rapidly inhibit CRH-receptor binding in a domain that is not affected by AVP potentiation of ACTH release. Perhaps they immobilize transport processes needed to bring unoccupied CRH receptors to the surface for binding and cytochemical detection.     

Role of endogenous arginine vasopressin in potentiating corticotropin-releasing hormone-stimulated corticotropin secretion in man

Exogenously administered vasopressin (VP) augments ACTH secretion stimulated by CRH. This study was performed to elucidate the role of endogenous VP in potentiating CRH-induced ACTH secretion in man. Synthetic human CRH (100 micrograms) was injected iv into seven normal men after they had been water loaded (20 mL/kg; 60 and 30 min before CRH injection; WL-CRH test) and water deprived (water restriction for 18 h before CRH injection; WD-CRH test). Blood samples were obtained before and 5, 15, 30, 60, 90, and 120 min after CRH injection at 0900 h for determination of plasma ACTH, cortisol, arginine vasopressin (AVP), CRH, and catecholamine levels and osmolality. Urine was obtained immediately before and 120 min after CRH injection for determination of osmolality. The mean plasma AVP levels were significantly higher during the WD-CRH test [1.8 +/- 0.4 (+/- SE) to 1.9 +/- 0.4 pmol/L] than during the WL-CRH test (0.6 +/- 0.1 to 0.9 +/- 0.1 pmol/L). The mean plasma ACTH and cortisol levels rose significantly from basal (4.5 +/- 0.6 pmol/L and 320 +/- 20 nmol/L, respectively) to peak values of 14.0 +/- 2.1 pmol/L at 30 min and 700 +/- 50 nmol/L at 60 min, respectively, during the WD-CRH test. During the WL-CRH test, mean basal plasma ACTH and cortisol levels were 3.5 +/- 0.7 pmol/L and 420 +/- 50 nmol/L, respectively, and reached peak values of 7.7 +/- 1.1 pmol/L at 60 min and 550 +/- 40 nmol/L at 30 min, respectively. Both the mean peak levels and integrated ACTH and cortisol responses were significantly higher during the WD-CRH than during the WL-CRH test. There was no significant difference between the plasma CRH and catecholamine concentrations in both tests. These results suggest that endogenous AVP potentiates CRH-stimulated ACTH secretion and, thus, plays a physiologically significant role in regulating CRH-stimulated ACTH and cortisol secretion in man.     

Interactions of CRH, AVP and cortisol in the secretion of ACTH from perifused equine anterior pituitary cells: "permissive" roles for cortisol and CRH

To further elucidate the interaction of CRH, AVP and cortisol in the control of ACTH secretion, we used an in vitro perifusion model with dispersed equine anterior pituitary cells. To approximate the in vivo milieu in the horse, CRH was perifused continuously (at 0, 2 and 20 pmol/L) and 5-min pulses of AVP (0, 1, 3 and 10 nmol/L) were given every 30 min in the presence of 0 or 100 nmol/L cortisol. Total (baseline + incremental) ACTH secretion increased as both the CRH (p<0.001) and the AVP (p<0.001) concentration increased and interaction between CRH and AVP was significant (p=0.042). Cortisol reduced total ACTH secretion in the presence of 2 pmol CRH/L (p=0.001) but not 0 or 20 pmol CRH/L. For incremental ACTH there was interaction between CRH and AVP (p<0.0001), with increased secretion at higher concentrations, and no significant main effect of cortisol. There was significant (p=0.001) interaction between cortisol and CRH, with cortisol attenuating ACTH release at 0 pmol CRH/L (p=0.008), having no effect at 2 pmol CRH/L and potentiating it at 20 pmol CRH/L (p=0.026). We conclude that (1) CRH at high physiological levels has a "permissive" role in preventing the cortisol inhibition of the ACTH response to AVP, and (2) basal cortisol levels have a "permissive" action in priming the HPA axis for maximal responsiveness to stimulated levels of CRH and AVP.     

The hypothalamic melanocortin system stimulates the hypothalamo-pituitary-adrenal axis in vitro and in vivo in male rats

alpha-Melanocyte-stimulating hormone (alpha-MSH) is an agonist, and agouti-related protein (Agrp) an endogenous antagonist at the melanocortin 3 and 4 receptors which are found in the central nervous system (CNS). We have examined the effect of alpha-MSH and Agrp on the hypothalamo-pituitary-adrenal (HPA) axis in vitro and in vivo in male rats. Intraparaventricular nuclear (iPVN) injection of [Nle(4),D-Phe(7)]-alpha-MSH (NDP-MSH) (a long-acting alpha-MSH analogue) increased plasma adrenocorticotropic hormone (ACTH) (10 min post-injection: 25.0 +/- 3.9 vs. saline 10.9 +/- 2.0, p < 0.05) and plasma corticosterone (10 min post-injection: 174.1 +/- 14.2 vs. saline 124.7 +/- 16.3 ng/ml, p < 0.05). iPVN injection of Agrp(83-132) increased plasma ACTH (24.2 +/- 4.0 vs. saline 10.1 +/- 1.0 pg/ml, p < 0.01). The combination of NDP-MSH and Agrp(83-132) administered iPVN significantly increased plasma ACTH (10 min post-injection: 21.3 +/- 3.8 vs. 10.9 +/- 2.0, p < 0.05) and plasma corticosterone (10 min post-injection: 169.0 +/- 15.1 vs. saline 124.7 +/- 16.3 ng/ml, p < 0.05), but there was no additive effect. Hypothalamic explants treated with alpha-MSH (100 nM) resulted in a 159 +/- 23% increase in corticotropin-releasing hormone (CRH) release (p < 0.01) and 175 +/- 12% increase in arginine vasopressin (AVP) release (p < 0.001) compared to basal. Agrp(83-132) (100 nM) administered to hypothalamic explants resulted in a 161 +/- 20% increase in CRH (p < 0.01) and 174 +/- 13% increase in AVP release (p < 0.001) compared to basal. Hypothalamic explants treated with the combination of alpha-MSH and Agrp(83-132) (100 nM) resulted in a 179 +/- 31% increase in CRH release (p < 0.01) and 130 +/- 9% increase in AVP release (p < 0.01) compared to basal, but there was no additive effect. This is the first report that both alpha-MSH and Agrp(83-132) stimulate the HPA axis. The combination of alpha-MSH and Agrp(83-132) has no additive effect in vitro and in vivo in male rats. These results suggest that there may be another receptor independent of the known melanocortin receptors at which Agrp is acting.     

Responsivity of the baboon fetal pituitary to corticotropin-releasing hormone in utero at midgestation.

The present study was designed to determine whether the baboon fetal pituitary at midgestation was responsive in utero to a bolus injection of CRH. On day 100 of gestation (term = day 184), baboons were anesthetized with halothane/nitrous oxide, the fetus was exteriorized, and a cannula was inserted into a fetal carotid artery. Five minutes later (experimental time zero), a fetal carotid blood sample was obtained, and saline (0.5 ml) with (n = 6) or without (n = 3) ovine CRH (100 ng estimated to equal 500 ng/kg BW) was then infused via the fetal carotid over a 3-min period. Fetal blood samples were taken 5, 15, 30, 45, and 60 min post-CRH/saline treatment and assayed for ACTH. Mean (+/- SE) pretreatment fetal plasma ACTH concentrations were similar in animals that subsequently received saline (26 +/- 3 pg/ml) or CRH (29 +/- 6 pg/ml). Fetal plasma ACTH remained constant after the infusion of saline. In contrast, CRH increased (P less than 0.05) fetal plasma ACTH within 5 min in six of six baboons to a value (58 +/- 12 pg/ml) that exceeded (P less than 0.05) the zero time value and the respective mean value (27 +/- 5 pg/ml) in saline-treated fetuses. Fetal plasma ACTH concentrations continued to rise in four of six baboons 15 min after CRH injection to a level (68 +/- 15 pg/ml) which exceeded that in saline controls (27 +/- 2 pg/ml). In fetuses treated with CRH, overall mean fetal plasma ACTH concentrations from 0-60 min increased at a rate (1.47 pg/min) greater (P less than 0.05) than that in fetuses injected with saline (0.07 pg/min). In contrast to the effects of intracarotid CRH injection, fetal plasma ACTH was not increased after the infusion of 100 ng CRH into a fetal antecubital vein of three additional animals. Collectively, these findings indicate that intracarotid injection of a bolus of CRH into the baboon fetus rapidly increased fetal plasma ACTH concentrations. Moreover, the site of action of CRH was presumably the fetal pituitary. Therefore, we suggest that the baboon fetal hypothalamic-pituitary axis at midgestation has the capacity to secrete ACTH in response to a challenge of CRH.     

Atrial natriuretic peptide in physiological doses does not inhibit the ACTH or cortisol response to corticotrophin-releasing hormone-41 in normal human subjects.

Whilst it has been postulated that atrial natriuretic peptide (ANP) may modulate pituitary hormone release, several investigations in non-human species have reported conflicting results when looking for an effect on the hypothalamo-pituitary-adrenal axis. However, in a recent study significant inhibition of corticotrophin-releasing hormone (CRH)-stimulated ACTH in cultured rat anterior pituitary cells occurred only with the complete peptide alpha-ANP(1-28). We have therefore investigated whether this form of ANP can inhibit CRH-stimulated ACTH and cortisol release in human subjects. Six healthy male volunteers received human alpha-ANP or placebo, and human CRH or placebo, on four separate occasions. ANP was infused at a rate of 0.01 micrograms/kg per min in order to achieve levels in the high physiological range. CRH was given as a bolus dose of 100 micrograms 30 min into the ANP infusion. Cortisol and ANP were measured by radioimmunoassay, the latter after extraction. ACTH was measured by immunoradiometric assay. The data were analysed by Student's paired t-test on basal, peak and incremental levels. Basal levels of ANP were within the normal range (2-5 pmol/l). With ANP infusion, mean +/- S.E.M. peak ANP levels were 29.6 +/- 3.1 pmol/l. There were no significant differences in mean basal cortisol and ACTH levels on each of the 4 study days. Mean peak cortisol and ACTH levels after CRH and ANP did not significantly differ from those achieved with CRH and placebo ANP. We thus conclude that at high physiological doses, circulating ANP does not inhibit CRH-stimulated ACTH or cortisol release.     

Desensitization of the adrenocorticotrophin responses to arginine vasopressin and corticotrophin-releasing hormone in ovine anterior pituitary cells

Following repeated or prolonged exposure to either corticotrophin-releasing hormone (CRH) or arginine vasopressin (AVP), pituitary adrenocorticotrophin (ACTH) responsiveness is reduced. This study compared the characteristics of desensitization to CRH and AVP in perifused ovine anterior pituitary cells. Desensitization to AVP occurred at relatively low AVP concentrations and was both rapid and readily reversible. Treatment for 25 min with AVP at concentrations greater than 2 nM caused significant reductions in the response to a subsequent 5 min 100 nM AVP pulse (IC(50)=6.54 nM). Significant desensitization was observed following pretreatment with 5 nM AVP for as briefly as 5 min. Desensitization was greater following a 10 min pretreatment, but longer exposures caused no further increase. Resensitization was complete within 40 min following 15 min treatment with 10 nM AVP. Continuous perifusion with 0.01 nM CRH had no effect on AVP-induced desensitization. Treatment with 0.1 nM CRH for either 25 or 50 min caused no reduction in the response to a subsequent 5 min stimulation with 10 nM CRH. When the pretreatment concentration was increased to 1 nM significant desensitization was observed, with a greater reduction in response occurring after 50 min treatment. Recovery of responsiveness was progressive following 50 min treatment with 1 nM CRH and was complete after 100 min. Our data show that in the sheep AVP desensitization can occur at concentrations and durations of AVP exposure within the endogenous ranges. This suggests that desensitization may play a key role in regulating ACTH secretion in vivo. If, as has been suggested, CRH acts to set corticotroph gain while AVP is the main dynamic regulator, any change in responsiveness to CRH may significantly influence the overall control of ACTH secretion.     

Corticotropin-releasing hormone is not the sole factor mediating exercise-induced adrenocorticotropin release in humans.

To determine whether CRH is the sole mediator of ACTH release during exercise, five men and five women were given, in a subject-blinded random manner at separate visits, both a 6-h infusion of ovine CRH (1 microgram/kg.h) and a saline infusion as a placebo. After the fourth hour of each infusion, when plasma concentrations of ovine CRH were sufficiently elevated to saturate the capacity of the corticotroph to respond further to CRH, each subject completed a high intensity intermittent run. Plasma ACTH and cortisol levels increased significantly during the CRH infusion from 4.6 +/- 0.8 (mean +/- SE) to 8.6 +/- 1.6 pmol/L and from 361 +/- 39 to 662 +/- 70 nmol/L, respectively (P less than 0.05). Despite elevated preexercise cortisol levels during the CRH infusion, plasma ACTH rose to 32.0 +/- 8.5 pmol/L after exercise. During the saline infusion, plasma ACTH rose from 3.4 +/- 0.6 pmol/L before exercise to 18.1 +/- 4.2 after exercise. Time-integrated responses for postexercise values of ACTH and cortisol were higher during the CRH infusion than during the saline infusion (P less than 0.05). No significant exercise-induced differences in heart rate or plasma concentrations of lactate, epinephrine, and norepinephrine were observed between the two tests. The findings suggest that some factor(s) in addition to CRH causes ACTH release during exercise. Vasopressin, produced by the magnocellular and/or parvocellular neurons of the hypothalamus, is a likely candidate.     

Effects of incremental infusions of arginine vasopressin on adrenocorticotropin and cortisol secretion in man

Arginine vasopressin (AVP) regulates ACTH release under certain conditions, and exogenously administered AVP is used clinically to stimulate ACTH secretion. We attempted to determine at what plasma concentration AVP can stimulate ACTH release. Six normal men were given infusions of AVP (Ferring) or vehicle between 1600 and 1700 h on five occasions: 1) saline (30 mL/h); 2) 10 ng AVP/min; 3) 30 ng AVP/min; 4) 100 ng AVP/min; and 5) 300 ng AVP/min. Plasma AVP, ACTH, and cortisol concentrations were measured every 10 min during the infusions. Basal plasma AVP levels were less than 1 ng/L (less than 0.92 pmol/L). The lowest AVP dose raised plasma AVP into the range found in fluid-deprived subjects (7-8 ng/L;6.5-7.3 pmol/L), but had no effect on plasma ACTH concentrations. AVP in a dose of 30 ng/min also had no effect. The 100 ng AVP/min dose raised plasma AVP concentrations to 51.4-65.5 ng/L (46-60 pmol/L). This increase led to a transient insignificant increase in plasma ACTH from 13.9 +/- 1.2 (+/- SEM) ng/L (3.1 +/- 0.3 pmol/L) to 20.0 +/- 1.4 ng/L (4.4 +/- 0.3 pmol/L), while plasma cortisol rose significantly from 146 +/- 10 to 209 +/- 19 nmol/L (P less than 0.01) after 60 min of infusion. The 300 ng AVP/min dose raised plasma AVP levels to about 260 ng/L (239 pmol/L); the maximal plasma ACTH and cortisol levels were 39.5 +/- 5.0 ng/L (8.7 +/- 1.1 pmol/L; P less than 0.01) and 348 nmol/L (P less than 0.01), respectively. Thus, peripheral plasma AVP levels have to be raised high above the physiological range before ACTH release is stimulated. We conclude that any AVP reaching the adenohypophysis through the peripheral circulation is of much less importance for the regulation of ACTH secretion than is AVP derived from the pituitary portal circulation.     

Dehydration, but not vasopressin infusion, enhances the adrenocortical responses of sheep to corticotropin-releasing hormone or restraint.

Two experiments were carried out using adult castrated sheep prepared with jugular vein catheters. In Experiment 1, sheep (N = 8) were injected iv with saline vehicle, vehicle + 15 or 30 micrograms oCRH, or subjected to 120 min mild physical stress (restraint), following a 48 h period during which water was freely available or withheld. Blood samples were taken for 30 min before and 120 min after oCRH injection, and before and during restraint, and the plasma analysed for AVP and cortisol content. Levels of AVP increased by over 500% after dehydration, but were unaffected by oCRH or restraint. In contrast, plasma cortisol was unchanged after dehydration, but increased after oCRH and restraint. Moreover, these cortisol responses were significantly greater when the sheep were dehydrated. In Experiment 2, euhydrated sheep (N = 6) were infused iv with saline vehicle or vehicle + AVP for a 5-h pretreatment period, followed by a 2-h experimental period in which the animals were injected with 15 micrograms oCRH or subjected to 120 min restraint, as in Experiment 1. Blood samples were taken throughout the experiment from a contralateral catheter and the plasma analysed for AVP and cortisol content. The AVP infusion produced plasma levels of the hormone approximately twice those seen after 48 h dehydration in Experiment 1, but did not affect cortisol secretion. Furthermore, the cortisol response to oCRH, or restraint, was not enhanced by the AVP infusion. These results suggest that pituitary responsiveness to exogenous or endogenous CRH (restraint stress) may be enhanced in sheep by dehydration through a mechanism that does not involve an adrenal or pituitary action of circulating AVP.     

Effect of administration of corticotropin-releasing hormone and glucocorticoid on arginine vasopressin response to osmotic stimulus in normal subjects and patients with hypocorticotropinism without overt diabetes insipidus

We examined the effect of CRH administration on the response of plasma arginine vasopressin (AVP) induced by an osmotic stimulus in six normal subjects and five patients with hypocorticotropinism without overt diabetes insipidus (four patients with Sheehan's syndrome and one with idiopathic pituitary dwarfism with ACTH deficiency). Hypertonic saline infusion (855 mmol/L saline solutions at a rate of 205 mumol/kg.min for 10 min) increased plasma AVP 5.7-fold (P less than 0.01) in normal subjects and 2.4-fold (P less than 0.05) in the patients. CRH administration significantly augmented the plasma AVP response to the osmotic stimulus in the normal subjects, but not in the patients with hypocorticotropinism. CRH administration alone did not influence plasma AVP. These findings suggest that a central CRH-related mechanism(s) was at least partly involved in the augmentation of AVP release. Based on the relatively low plasma AVP response to the osmotic stimulus in patients and their lower plasma AVP levels and higher plasma osmolality under basal conditions, we suggest that patients with hypocorticotropinism have partial diabetes insipidus, in which impairment of central CRH action might be, at least in part, involved. The response of plasma AVP to the osmotic stimulus was attenuated significantly when the patients were given cortisol. Since basal PRA, plasma aldosterone, plasma osmolality, hematocrit, body weight, mean blood pressure, and heart rate were similar with and without cortisol administration, this effect of cortisol may have been due to central suppression of the AVP response to the osmotic stimulus.     

Distinct classes of corticotropes mediate corticotropin-releasing hormone- and arginine vasopressin-stimulated adrenocorticotropin release.

ACTH release from the anterior pituitary gland is principally driven by the two hypothalamic hormones, corticotropin-releasing hormone (CRH) and arginine vasopressin (AVP). Using the reverse hemolytic plaque assay, we have compared the effects of CRH and AVP on ACTH release from individual, dispersed pituitary cells. A small percent (0.36 +/- 0.06%) of pituitary cells formed plaques when exposed to medium alone. AVP caused 3.44 +/- 0.10% of cells to form plaques (P less than 0.01 compared with medium alone), CRH produced 4.85 +/- 0.20% plaque-forming cells (P less than 0.01 compared with AVP), and the combination of CRH and AVP produced a still greater percent of plaque-forming cells (5.80 +/- 0.20%, P less than 0.01 compared with CRH alone). A double reverse hemolytic plaque assay was then employed to examine whether some cells formed plaques only in the presence of one or other secretagogue. Using this technique we found clear evidence of cells that formed plaques in response to CRH but not AVP (P less than 0.005); CRH or AVP (P less than 0.0001), and CRH and AVP (P less than 0.05). There was no evidence of a corticotrope forming a plaque with AVP but not CRH (P = 0.52). Thus there appears to be functionally distinct classes of corticotropes. These findings have important implications for our understanding of the relative responsiveness of the pituitary to hypothalamic secretagogues and provide a new physiological perspective on recent reports of stress-specific hypothalamic responses regulating ACTH release.     

Effect of an osmotic stimulus on the secretion of arginine vasopressin and adrenocorticotropin in the horse

Arginine vasopressin (AVP) is released in response to changes in blood osmolality and is also a putative secretagogue for ACTH. However, it is unclear whether osmotically generated increases in AVP in the physiological range influence ACTH secretion. We have studied this question using our unique noninvasive technique for collecting pituitary venous blood in six normal conscious horses that received an iv infusion of hypertonic saline (HS; 5%, 0.07 ml/kg.min) for 45-60 min. Pituitary and jugular venous samples were collected every 5 min for 40 min before, during, and for 20 min after HS. During HS, mean blood osmolality rose (P less than 0.01), with a mean peak increase of 14.8 mosmol/kg (range, +6-+37 mosmol/kg). Jugular AVP rose (P less than 0.01) from 0.56 +/- 0.18 pmol/liter (mean +/- SEM) before HS to 2.16 +/- 0.86 pmol/liter during HS. Mean jugular AVP and osmolality were correlated (r = 0.82; P less than 0.05) during HS. Mean jugular ACTH concentrations increased (P less than 0.01) from 49 +/- 9 ng/liter before HS to 148 +/- 54 ng/liter during HS, while mean cortisol levels during and after HS exceeded basal levels (P less than 0.05). Pituitary AVP and ACTH concentrations exceeded jugular concentrations by up to 100-fold, and mean (P less than 0.01 for both) and peak (P less than 0.001 for both) levels increased during HS. AVP and ACTH secretion during HS were pulsatile. The mean and peak changes in pituitary AVP were significantly correlated with those in ACTH. For the six horses together, pituitary ACTH and AVP concentration changes occurred synchronously during the experiment (P less than 0.001), and the paired AVP and ACTH concentrations were highly correlated (r = 0.73; n = 129 pairs; P less than 0.001). We conclude that 1) physiological changes in AVP secretion are closely associated with comparable changes in ACTH secretion, and 2) osmotic signals that presumably activate the magnocellular neurons of the supraoptic and paraventricular nuclei may be physiologically relevant regulators of corticotrope function.     

Gastrin-releasing peptide stimulation of corticotropin secretion in male rats.

Gastrin-releasing peptide (GRP; mammalian bombesin) may be involved in the neuroendocrine regulation of pituitary hormone secretion. We investigated the effect of GRP on ACTH secretion in conscious male rats. GRP (7-700 pmol) stimulated ACTH secretion dose-dependently after intracerebroventricular (icv) administration but had no effect after iv administration. GRP infused icv in a dose of 7 pmol, which alone increased ACTH 1.5-fold, potentiated the ACTH-releasing effect of arginine vasopressin (AVP; 80 pmol iv) and corticotropin-releasing hormone (CRH; 100 pmol iv). A higher dose of GRP (70 pmol icv), which stimulated ACTH secretion 2-fold, potentiated the effect of 80 and 400 pmol AVP iv, but had only additive effect on the ACTH response to 800 pmol AVP iv or 100 pmol CRH iv. GRP infused iv in a dose of 210 pmol, which in itself had no effect on ACTH secretion, potentiated the ACTH-stimulating effect of AVP and CRH approximately 2.5-fold. The effect of GRP (icv or iv) on AVP or CRH-stimulated ACTH release was only slightly smaller than the effect of combined administration of AVP and CRH (80 + 100 pmol iv). The ACTH-stimulating effect of GRP (700 pmol icv) was inhibited about 60% by pretreatment with either CRH or AVP antiserum and prevented by combined pretreatment with the antisera. The results indicate that: 1) GRP affects ACTH secretion indirectly at a suprapituitary level--possibly in the hypothalamus--by stimulating the release of AVP and CRH to the pituitary portal blood; and 2) GRP acts directly at the pituitary level to augment the effect of AVP and CRH on the corticotrophs. We suggest that GRP is involved in the multifactorial regulation of ACTH secretion.     

Morphine inhibits the pituitary-adrenal response to ovine corticotropin-releasing hormone in normal subjects

To determine the locus of opiate modulation of ACTH secretion, 11 normal subjects were given ovine corticotropin-releasing hormone (CRH) 30 min after receiving either placebo or morphine sulfate. Plasma ACTH, cortisol, arginine vasopressin (AVP), epinephrine, norepinephrine, and CRH were measured 30 min before and up to 150 min after CRH administration. Morphine blunted the ACTH response for the first 60 min and cortisol response for the first 90 min after CRH administration. Morphine did not lower arginine vasopressin or catecholamine levels. To determine whether morphine's effect on ACTH and cortisol was due to a direct action on the corticotroph cell, dispersed rat pituitary cells were perifused with medium containing 1 microgram/ml morphine sulfate or medium alone. Morphine had no effect on the ACTH response of these cells to 10 nM CRH pulses. Similarly, morphine had no effect on ACTH production by dispersed rat pituitary cells in monolayer culture in response to 90- and 180-min incubations with 5 nM CRH. We conclude that morphine blunts the early response of the pituitary gland to CRH in vivo. Based on the lack of a direct effect of morphine on rat pituitary cells in vitro, we postulate that morphine given in vivo may modulate the pituitary ACTH response to CRH through other suprapituitary factors.     

Combined hypervolemia and hypoosmolality alter hypothalamic-pituitary-adrenal axis response to endotoxin stimulation.

Changes in corticotropin (ACTH) and glucocorticoid secretion have been described during disturbances of body fluid homeostasis and attributed to alterations in arginine vasopressin (AVP) secretion from magnocellular hypothalamic neurons. In order to further characterize the mechanisms involved in the interactions between body fluid alterations and pituitary adrenal function, we manipulated osmolality and volemia in sheep under stimulation of the pituitary-adrenal axis by acute injection of endotoxin. We have recently shown that endotoxin injection induces a long-lasting release of both corticotropin releasing hormone (CRH) and AVP into hypophysial portal blood, and an early stimulation of AVP secretion into peripheral vessels, thus suggesting a joint activation of magnocellular and parvocellular neurons of the PVN. We used the same experimental model to investigate the effect of combined volume loading and plasma dilution (achieved by 1-deamino-8-D-arginine (dDAVP) administration together with infusion of 2 liters of 2.5% glucose solution) on CRH, AVP, ACTH and cortisol responses to endotoxin stimulation. In volume-loaded animals, ACTH and cortisol responses to endotoxin were significantly blunted and we observed a parallel decrease in portal CRH and jugular and portal AVP levels. These data show that hypoosmolality and/or hypervolemia reduce(s) ACTH and cortisol response to stress in sheep as in other species. They strongly suggest that this reduction in ACTH and cortisol responses to endotoxin involve not only magnocellular hypothalamic neurons secreting AVP, as usually assumed, but also PVN parvocellular neurons secreting both CRH and AVP.