Braz J Med Biol Res, April 1997, Volume 30(4) 465-469

Atrial natriuretic peptide and feeding activity patterns in rats

M.H.A. Oliveira¹, J. Antunes-Rodrigues³, J. Gutkowska², A.M.O. Leal⁴, L.L.K. Elias⁴ and A.C. Moreira⁴

¹Departamento de Medicina, Universidade Federal de Sergipe, 49060-100 Aracaju, SE, Brasil
²Centre de Recherche Hôtel-Dieu de Montreal, Pavilion Marie-de-la-Ferre, Montréal, Québec, H2W 1T8, Canada
Departamentos de ³Fisiologia and ⁴Clínica Médica, Faculdade de Medicina de Ribeirão Preto, Universidade de São Paulo, 14048-900 Ribeirão Preto, SP, Brasil

Abstract
Text
References
Acknowledgments
Correspondence and Footnotes

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Abstract

This review presents historical data about atrial natriuretic peptide (ANP) from its discovery as an atrial natriuretic factor (ANF) to its role as an atrial natriuretic hormone (ANH). As a hormone, ANP can interact with the hypothalamic-pituitary-adrenal axis (HPA-A) and is related to feeding activity patterns in the rat. Food restriction proved to be an interesting model to investigate this relationship. The role of ANP must be understood within a context of peripheral and central interactions involving different peptides and pathways.

Key words: atrial natriuretic peptide, corticosterone, ACTH, food restriction

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A factor, at the beginning

The discovery of a natriuretic factor from cardiac atria (1,2) led to further characterization of a complex natriuretic hormonal system, including a 126-amino acid prohormone synthesized within myocytes of the heart and stored in granules for release into the circulation. This hormonal system includes several peptides such as the prohormone pro-atrial natriuretic factor (ANF) 1-30, a long-acting sodium stimulator, pro-ANF 31-67, a vasodilator, pro-ANF 79-98, a kaliuretic stimulator, and pro-ANF 99-126. Each of these peptides has blood pressure-lowering, diuretic, natriuretic, and/or kaliuretic properties in both humans and animals. When released into the circulation, these peptides circulate as a 28-amino acid C-terminus (i.e, ANF) of this prohormone and as a 98-amino acid N-terminus which is proteolytically cleaved into pro-atrial natriuretic peptide (ANP) 31-67 and pro-ANF 1-30. The peptides enhance the particulate form of the enzyme guanylate cyclase increasing the intracellular messenger cGMP that has been shown to be the final mediator of the observed vasodilatation and natriuresis secondary to atrial natriuretic peptides (3,4). A single ANF gene has been identified in all mammalian species examined to date. In man this gene is located on chromosome 1, band p36, and is one of a syntenic group that is present on chromosome 4 of the mouse. The gene consists of three exons separated by two introns. More recently, brain natriuretic peptide (BNP) and C-type natriuretic peptide (CNP) and at least three subtypes of receptors were identified (5). In this review we will use the name ANP although the term atrial natriuretic hormone (ANH) would be more appropriate.

Atrial, but not only atrial

ANP has been identified in many different tissues and may have several important physiological functions other than natriuresis and vasodilation. In brain it exists as amino-terminally truncated form. Two systems are involved in the secretion of ANP: peripheral ANP (heart and plasma) and central ANP (paraventricular, periventricular, arcuate, and pre-optical-medial nuclei and other sites) (6). Despite the blood-brain barrier, these systems communicate through the circumventricular organs, the organum vasculosum lamina terminalis and the organum subfornicalis (7-9). They are connected by neuronal synapses (9-14), or by discharge of peptides such as vasopressin (15), endothelin (11) and oxytocin (16) from the hypothalamus. Therefore, ANP may participate in the control of different functions such as the reduction of the activity of the renin-angiotensin-aldosterone system and inhibition of salt and water intake in the rat (17,18). Nevertheless, ANP originating from the paraventricular nucleus (PVN) is responsible for 87 to 92% of the content of ANP in the median eminence and is involved in the regulation of the function of the anterior pituitary (19). Several experiments using immunoneutralization techniques have demonstrated that ANP, in addition to participating in the control of LH and prolactin secretion (20,21), may be a factor inhibiting corticotropin release (21-24).

Natriuretic, but where?

ANP was discovered on the basis of its pharmacological properties of producing diuresis and natriuresis, although at the periphery its vasodilating action is probably more important. Transgenic mice with ANP levels 2- to 10-fold the normal values exhibit essentially normal fluid and electrolyte homeostasis, a fact that argues against a fundamental role of peripheral ANP in water and sodium metabolism. However, the mice with the highest ANP levels were significantly hypotensive indicating that these pharmacologic renal effects of the peptide are less important than its hemodynamic actions (4). On the other hand, in rats or in humans, high ANP concentrations are hypotensive even when they are lower than natural concentrations in the pituitary portal system, and are able to inhibit ACTH secretion in vitro (25). Nevertheless, under appropriate conditions, the antagonism between the natriuretic peptide system and the renin-angiotensin system can promote natriuresis. For instance, ANP inhibition of stress-induced vasopressin release may increase renal water loss and the diminished ACTH release induced by ANP may lead to a reduction in aldosterone secretion, thereby diminishing the stress-induced sodium retention (26), a mechanism demonstrating the central natriuretic action of ANP.

And what else? ANP and the HPA-A

Two lines of research have been exhaustively followed by our group since the early eighties. First, the investigation involved the brain ANPergic neuron system and its role as antagonist of the renin-angiotensin system, its influence on ANP release including ANP release induced by volume expansion (9-14,17-18), and other hormonal effects of the brain ANP system on LH, prolactin, GH, TSH, and ACTH secretion (20,24). In parallel, we investigated the circadian rhythmicity of the hypothalamic-pituitary-adrenal axis (HPA-A) in rats with continuous or restricted access to food (27). It is well known that rats manifest a circadian peak of plasma corticosterone and ACTH just before the onset of predominant food intake (28). We demonstrated for the first time circadian and parallel ANP and corticosterone variations in rats with continuous (peak at 20:00 h) or restricted access to food from 9:00 to 11:00 h, with a peak at 8:00 h (29). Both lines of investigation led to a better understanding of the relationship between brain and peripheral ANP involving neuronal and peptidergic interactions. The activation of the central noradrenergic pathway is involved in the volume expansion-induced ANP release and the circadian variation of corticosterone and ANP in rats. High levels of noradrenaline and elevated numbers of alpha-2-adrenoreceptors are found in PVN (30), producing a large burst of food intake and activity at the beginning of the dark period simultaneously with an increase of cardiac rate and pressure (31). In addition, the central noradrenergic pathway is activated before feeding time in food-restricted rats. Food restriction induces a disruption of activity-rest and sleep-wake patterns with changes in the hippocampal content of norepinephrine and serotonin, and in the cortical content of serotonin (32), and corticotropin-releasing hormone (CRH)-related neurotransmitters involved in feeding behavior (33). Feeding patterns result from a complex balance between anorectic (CRH, cholecystokinin (CCK), neurotensin) and orectic (neuropeptide Y (NPY), pancreatic polypeptide, galanine) factors, constituting a complex circuitry. CRH and NPY deserve additional comments. Food restriction induces an increase of NPY mRNA level in the arcuate nucleus and reduces the CRH mRNA level in PVN in a physiological response to restore food intake (34). Dallman et al. (35) suggested that the NPYergic system, the activity of which is increased by fasting and reduced by feeding, by insulin and lack of glucocorticoids, may mediate the fasting-induced override of diurnal rhythms in the HPA-A. We propose that the food-restricted high corticosterone levels may contribute to the observed reduction of CRH mRNA through an action of ANP. In addition, glucocorticoids areable to stimulate ANP secretion or genic activity (36-41). This effect may be consistent with a possible hypothalamic-cardio-adrenal feedback control mechanism (29).

Diurnal ANP variations and food restriction

Because rats drink when they eat and eat when they drink, restriction of water or food effectively restricts consumption of both (35). To test the hypothesis of food restriction being a paramount "zeitgeber" for the diurnal variation of corticosterone, ACTH and ANP and to determine the role of water restriction, we studied these rhythms in water-restricted rats (water from 9:00-11:00 h). Water-restricted rats showed a double corticosterone peak at 8:00 and 20:00 h and an ACTH peak at 8:00 h, and did not show diurnal variation of ANP. We concluded that food intake is a more important synchronizer than water intake for the activity and HPA rhythmicity. We believe that the effects of water restriction on corticosterone and ACTH secretion are mediated by changes in food intake since there is a spontaneous burst of feeding in the presence of a water supply. Water-restricted rats are less active during the light period than food-restricted rats. In fact, food-restricted rats with exclusive 0.9% or 1.5% NaCl intake exhibit more hyperactivity and more intense drink-seeking behavior, thereby abolishing the diurnal circadian variation in ANP due to a high ANP secretion during this period. Free fed adrenalectomized rats showed no diurnal ANP variation. This may be attributed to a reduction of the spontaneous food intake and activity during the dark period in comparison to the light period, due to a reduction in the alpha-2-adrenoreceptors in PVN, as shown by Bhakthavatsalam and Leibowitz (42) and Jhanwar-Uniyal et al. (30). We do not know whether a stimulating effect of glucocorticoids on the genic transcription of ANP contributes to the evening ANP peak and is eventually suppressed by adrenalectomy (ADX). We demonstrated that dexamethasone (50 µg/kg body weight) administered intraperitoneally to ADX rats produced a drastic reduction of ACTH accompanied by a pronounced ANP increase within 90 min. This result suggests that a simultaneous increase in portal ANP content may mediate the reduction of ACTH hypersecretion in ADX rats. It is interesting that this feedback mechanism uses the same type II receptor that mediates the high food intake occurring at the onset of darkness, which is abolished by ADX and restored by corticosterone (43).

ANP, a feeding-related peptide? Peripheral or central actions?

The interaction between insulin and corticosteroid serves as a peripheral hormonal feedback loop that regulates the well-known NPYergic feeding and fasting system, but if plasma insulin levels were elevated in an attempt to increase CNS insulin levels (in the hope of observing a consequent decrease in food intake) the resulting hypoglycemia would elicit an emergency increase in food intake (44). Similarly, if plasma ANP levels were increased to the high levels needed to inhibit the HPA-A, the resulting hypotension could have a stimulatory effect. Therefore, central ANP sites (PVN, arcuate nucleus, perifornical lateral hypothalamus, AV3V, subfornical organ, supraoptic nucleus) may act as integrating sites of a complex system that couples feeding, HPA-A, physical activities and cardiovascular status. Corticosteroids and insulin may act as peripheral signals, and the locus ceruleus, nucleus tractus solitarius and dorsomedial nucleus as intermediate stations. The activation of noradrenergic and serotonergic pathways may be involved, but the nature of other interactions and peptides deserves further study.

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Acknowledgments

The authors thank Miss Ana Cristina C. Pereira and Mr. Alex A. da Silva for secretarial assistance.

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Correspondence and Footnotes

Address for correspondence: A.C. Moreira, Departamento de Clínica Médica, Faculdade de Medicina de Ribeirão Preto, USP, 14048-900 Ribeirão Preto, SP, Brasil. Fax: 55 (016) 633-1144.

Presented at the International Symposium "Neuroendocrine Control of Body Fluid Homeostasis", Ribeirão Preto, SP, Brasil, August 17-20, 1996. Research supported by CNPq and HCFMRP-FAEPA. Publication supported by FAPESP. Received November 29, 1996. Accepted January 6, 1997.