Dynamics of the regulation of the hypothalamo-pituitary-adrenal (HPA) axis determined using a nonsurgical method for collecting pituitary venous blood from horses.
Abstract: Since 1985, we have applied our nonsurgical technique for collecting pituitary venous (PitVen) blood from ambulatory horses to investigate the regulation of adrenocorticotropic hormone (ACTH) secretion. This method offers particular advantages for studying the hypothalamo-pituitary-adrenal axis since its benign nature enables hypothalamic and pituitary interactions to be monitored without disturbing the animal, and the horse's large blood volume allows 3- to 4-ml samples to be collected as frequently as every 20s for prolonged periods so that the secretion patterns of ACTH and its secretagogues can be precisely defined. When PitVen blood was sampled every 20 or 30s during the circadian maximum, arginine vasopressin (AVP) and ACTH secretion patterns were complex and irregular, with mean interpeak intervals of approximately 5 min. Despite their erratic patterns, AVP and ACTH secretions were closely coupled on cross-correlation analysis. By contrast, PitVen corticotropin-releasing hormone (CRH) concentrations were low, relatively stable, and not consistently related to ACTH secretion. However, when cortisol negative feedback was reduced acutely by metyrapone infusion, CRH and AVP secretion were stimulated. Mathematical modeling suggested that CRH had become the more effective secretagogue and that much of the ACTH response was mediated by increased pituitary responsiveness to CRH. Elevated blood osmolality triggered synchronous AVP and ACTH secretion, without altering PitVen CRH. In this case, the source of PitVen AVP was presumably the magnocellular/neurohypophysial pathway, which is thought to respond primarily to changes in blood osmolality and pressure. Our results suggest that this pathway also participates in ACTH regulation. We have studied the effect of several perturbations and found, as have others, that the secretagogues released vary with the stimulus given. For example, vigorous exercise promptly raised PitVen AVP and ACTH, but not PitVen CRH. Hypoglycemia provoked both CRH and AVP secretions, with the CRH increment being inversely proportional to the glucose nadir. Administration of the opioid antagonist, naloxone, increased PitVen ACTH; however, changes in AVP and CRH were variable and overall could not account for the ACTH response. This suggests that endogenous opioids inhibit a third ACTH secretagogue, stimulate an inhibitory factor, or also act at the pituitary. Chronic social stress, induced by confining newcomers with aggressive, resident mares, caused most introduced horses to become submissive. In such horses, plasma cortisol declined to levels similar to those during metyrapone infusion. Despite hypocortisolemia, PitVen ACTH was low, whereas PitVen CRH tended to be elevated. Moreover, chronically stressed horses did not respond to exogenous CRH. We conclude that at rest and during some perturbations AVP is the immediate stimulus for ACTH release. Even ACTH micropulses, previously thought to occur spontaneously, appear to be regulated by AVP in horses. On the other hand, CRH secretion and pituitary responsiveness to CRH rise when cortisol falls, suggesting that a major role for CRH is to fix the cortisol setpoint. However, during chronic stress, these relationships become disturbed, with results to date pointing toward the existence of an ACTH-release inhibiting factor.
Publication Date: 1996-01-01 PubMed ID: 8788568DOI: 10.1006/frne.1996.0001Google Scholar: Lookup
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- Journal Article
- Research Support
- Non-U.S. Gov't
- Research Support
- U.S. Gov't
- P.H.S.
- Review
Summary
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This research investigates the regulation of adrenocorticotropic hormone (ACTH) secretion in horses using a nonsurgical technique for collecting pituitary venous blood. Through various stimulus conditions and mathematical modelling, the study shows the dynamic relationships between ACTH, arginine vasopressin (AVP), and corticotropin-releasing hormone (CRH).
Research Methodology
- The researchers applied a nonsurgical technique for collecting pituitary venous (PitVen) blood from ambulatory horses to study the regulation of adrenocorticotropic hormone (ACTH) secretion.
- This technique allowed the team to extensively study the interactions between hypothalamus and pituitary hormones without causing any harm to the horses.
- The horses’ large blood volume enabled them to collect samples as frequently as every 20 seconds for prolonged durations. This high frequency of sample collection helped to obtain precise secretion patterns of ACTH and its secretagogue.
Main Findings
- Prolonged collection of PitVen blood found irregular secretion patterns of ACTH and AVP, with close correlations between the two.
- The corticotropin-releasing hormone (CRH) concentrations were low and not consistently related to ACTH secretion. However, when cortisol negative feedback was reduced, CRH and AVP secretions were stimulated.
- Results from mathematical modelling suggested that in such cases, CRH is a more effective secretagogue and much of the ACTH response was driven by an increased pituitary response to CRH.
- When blood osmolality (the concentration of dissolved particles in the blood) increased, it triggered simultaneous secretion of AVP and ACTH, but without altering PitVen CRH. This suggested that the pathway responding primarily to changes in blood osmolality and pressure also participated in the regulation of ACTH.
Effects of Varied Stimulus and Conditions
- The secretion patterns differed based on the type of stimulus. For example, intense physical exercise resulted in raising PitVen AVP and ACTH levels, but not PitVen CRH.
- Under hypoglycemia, secretion of both CRH and AVP increased, with CRH increment being inversely proportional to the depth of the glucose decline.
- The study also found that chronic social stress induced by confined newcomer horses with aggressive resident mares resulted in a decline of plasma cortisol to levels similar to those during metyrapone infusion. Despite this, PitVen ACTH was low, while PitVen CRH tended to be elevated.
- Chronic stress also led to the horses exhibiting no response to external CRH, suggesting that CRH’s primary role could be fixing the cortisol setpoint, with potential disturbances during periods of stress.
Conclusions
- The researchers concluded that under resting and some perturbed conditions, AVP seems to be the immediate stimulant for ACTH release, and that even minor ACTH fluctuations previously believed to occur spontaneously, are regulated by AVP in horses.
- Contrastingly, they suggested that secretion and pituitary receptiveness to CRH rises when cortisol falls, pointing to CRH’s important function in determining the cortisol setpoint.
- They also surmised that there could be an ACTH-release inhibiting factor that emerges during periods of chronic stress.
Cite This Article
APA
Alexander SL, Irvine CH, Donald RA.
(1996).
Dynamics of the regulation of the hypothalamo-pituitary-adrenal (HPA) axis determined using a nonsurgical method for collecting pituitary venous blood from horses.
Front Neuroendocrinol, 17(1), 1-50.
https://doi.org/10.1006/frne.1996.0001 Publication
Researcher Affiliations
- Department of Endocrinology, Christchurch Public Hospital, New Zealand.
MeSH Terms
- Adrenal Glands / physiology
- Adrenocorticotropic Hormone / metabolism
- Animals
- Blood Specimen Collection / methods
- Homeostasis
- Horses
- Hydrocortisone / metabolism
- Hypothalamus / physiology
- Pituitary Gland / blood supply
- Pituitary Gland / physiology
Grant Funding
- NIDDK-38322 / NIDDK NIH HHS
Citations
This article has been cited 6 times.- Elder E, Wong D, Johnson K, Robertson H, Marner M, Dembek K. Assessment of the hypothalamic-pituitary-adrenocortical axis function using a vasopressin stimulation test in neonatal foals. J Vet Intern Med 2023 Sep-Oct;37(5):1881-1888.
- Johnson K, Peterson J, Kopper J, Dembek K. The hypothalamic-pituitary-adrenal axis response to ovine corticotropin-releasing-hormone stimulation tests in healthy and hospitalized foals. J Vet Intern Med 2023 Jan;37(1):292-301.
- Carmalt JL, Scansen BA. Development of two surgical approaches to the pituitary gland in the Horse. Vet Q 2018 Dec;38(1):21-27.
- Hart KA, Barton MH. Adrenocortical insufficiency in horses and foals. Vet Clin North Am Equine Pract 2011 Apr;27(1):19-34.
- Keenan DM, Licinio J, Veldhuis JD. A feedback-controlled ensemble model of the stress-responsive hypothalamo-pituitary-adrenal axis. Proc Natl Acad Sci U S A 2001 Mar 27;98(7):4028-33.
- Van Loh BM, Yaw AM, Breuer JA, Jackson B, Nguyen D, Jang K, Ramos F, Ho EV, Cui LJ, Gillette DLM, Sempere LF, Gorman MR, Tonsfeldt KJ, Mellon PL, Hoffmann HM. The transcription factor VAX1 in VIP neurons of the suprachiasmatic nucleus impacts circadian rhythm generation, depressive-like behavior, and the reproductive axis in a sex-specific manner in mice. Front Endocrinol (Lausanne) 2023;14:1269672.
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