Down-regulation of angiotensin II receptors in subfornical organ of young male rats by chronic dietary sodium depletion

Challenged sodium balance and expression of angiotensin type 1A receptor mRNA in the hypothalamus of Wistar and Dahl rat strains

The present study investigates the influence of a chronic high Na+ diet (8% Na+) on the expression of the angiotensin type 1A (AT1A) receptor gene in the lamina terminalis and paraventricular nucleus of the hypothalamus (PVH) in normotensive Wistar (W) rats, as well as in Dahl salt-resistant (DR) and Dahl salt-sensitive (DS) rats. Three weeks of 8% Na+ diet led to a higher blood pressure in DS rats compared to DR and W rats. Moreover, the high Na+ diet was correlated with a decreased expression of AT1A receptor mRNA in the median preoptic nucleus (MnPO) and in the PVH of DS rats, compared to DR and W rats. Contrastingly, the AT1A receptor mRNA expression was not altered by the high Na+ diet in the forebrain circumventricular organs of all the rat strains. Interestingly, a furosemide-induced Na+ depletion was correlated with an increased expression of AT1A receptor mRNA in the PVH, MnPO and SFO of both the DS and DR rats. It is concluded that chronic high Na+ diet did differently regulate the expression of AT1A receptor mRNA in two hypothalamic integrative centers for hydromineral and cardiovascular balance (the PVH and MnPO) in DS rats, compared to DR and W rats. However, the AT1A receptor mRNA expression was similarly regulated in DS and DR rats in response to an acute Na+ depletion, suggesting a distinct high Na+ -induced regulation of the AT1A receptor gene in the PVH and MnPO of DS rats.

Perinatal dietary NaCl level: effect on angiotensin-induced thermal and dipsogenic responses in adult rats

We have shown previously that administration of angiotensin II (Ang II) produces an apparent decrease in thermoregulatory set point. Exposure to high salt diets either perinatally or later in life has been shown to increase pressor responsiveness to administration of Ang II, so in the present studies we examine whether high dietary NaCl would also increase the thermal responsiveness to Ang II. In the first study, we show that exposure to a basal NaCl diet (0.12%) during gestation through 4 weeks postnatally produced very large elevations in plasma renin activity (PRA) and aldosterone concentrations in the offspring. Exposure to high salt diet (3%) did not decrease the levels of these parameters below those fed mid salt diet (1%). In the second study, we show that rats raised through 4 weeks of age on basal diet, but then fed standard chow until adulthood, showed greater changes in tail skin (T(sk)) and colonic (T(c)) temperatures following administration of Ang II (200 microg/kg sc) than either mid- or high-salt-raised groups. In the third study, we confirmed this finding and extended it to show that rats raised on a very high salt diet (6%) also did not differ from the mid-salt group. In both studies, acute water intake measured in a separate test following administration of Ang II did not differ as a function of perinatal salt diet. In a fourth study, the period of exposure to the diets was extended from the perinatal period through adulthood and, surprisingly, there was no longer an enhanced thermal response to Ang II in basal diet rats compared with rats fed the very high salt diet. In the final study, rats raised on a regular diet but exposed only as adults to the test diets showed a nonsignificant trend toward a decreased thermal response in the basal group. Thus, dietary salt level may have opposite effects on Ang II effects on adult thermoregulation, depending on the age at the exposure.

Structure of the subfornical organ: a review

In this review, the light microscopic and fine structural characteristics of neurons, axons, dendrites, glial cells, and capillaries and their topography within the subfornical organ are summarized, with an emphasis on recent findings. Structure-function relationships are discussed whenever possible and put into perspective in a concluding section.

Selective chronic sodium or chloride depletion specifically modulates subfornical organ atrial natriuretic peptide receptor number in young rats

1. We studied the effects of selective chronic sodium depletion of chloride depletion on atrial natriuretic peptide receptor number in the subfornical organ and paraventricular nucleus of young rats. 2. Sodium or chloride depletion decreased plasma levels of atrial natriuretic peptide, increased plasma renin activity, and induced extracellular fluid volume contraction. Chloride depletion induced more significant changes in extracellular fluid volume contraction than sodium depletion. 3. In the subfornical organ, atrial natriuretic peptide receptor number significantly decreased (30%) after sodium depletion, while chloride depletion induced a smaller, not statistically significant decrease. Conversely, atrial natriuretic peptide receptors located in the paraventricular nucleus of young rats were not significantly affected by sodium or chloride depletion. 4. Water deprivation reversed the decrease in atrial natriuretic peptide receptors produced by sodium depletion. Water-deprived sodium-depleted rats actually had higher numbers of atrial natriuretic peptide receptors in the subfornical organ than control rats. These changes were associated with severe extracellular fluid volume contraction and up regulation of brain vasopressin mRNA steady-state levels. Thus, the direction of change in the number of subfornical organ atrial natriuretic peptide receptors was dependent on the degree of extracellular fluid volume contraction. 5. Our results suggest that atrial natriuretic peptide receptors located in the subfornical organ, and not in the paraventricular nucleus, are selectively regulated by sodium depletion and extracellular fluid volume contraction.

Differential regulation of angiotensinogen and natriuretic peptide mRNAs in rat brain by osmotic stimulation: focus on anterior hypothalamus and supraoptic nucleus

Central angiotensin II and natriuretic peptide systems have been shown to be involved in the central regulation of blood fluid homeostasis with alterations in central peptide and/or receptor levels observed following changes in osmotic status. The present study investigated the effects of sodium loading on mRNA encoding the angiotensin II precursor, angiotensinogen (AOGEN), and the natriuretic peptides, atrial natriuretic peptide (ANP) and C-type natriuretic peptide (CNP) in rat brain using quantitative in situ hybridization histochemistry of [35S]- and [33P]-labeled oligonucleotide probes. Following 7 and 14 days of 2% sodium chloride in drinking water a significant increase was detected in preproAOGEN (ppAOGEN) mRNA in presumed astrocytes in regions of the anterior hypothalamus, including the periventricular nucleus, the medial preoptic area and medial preoptic nucleus, while a decrease was observed in astrocytes in the supraoptic nucleus. Other forebrain regions examined including the subfornical organ, bed nucleus of the stria terminalis and the arcuate nucleus showed no significant alteration in the level of ppAOGEN mRNA. Sodium loading did not appreciably alter ppANP or ppCNP mRNA levels in neurons of the anteromedial preoptic or arcuate nuclei or hippocampus at the times studied. PpANP mRNA levels were also unaltered in Barrington's nucleus following sodium loading, while preprocorticotropin-releasing hormone mRNA was significantly decreased. These results indicate that AOGEN mRNA transcription/stability in vivo is modulated by alterations in osmotic balance, consistent with previous reports of a central role for AII in cardiovascular and body fluid homeostasis. In contrast, despite reports of modulation of hypothalamic ANP-immunoreactivity following changes in osmotic status, it would appear that osmotic stimulation over periods of 7-14 days does not markedly alter the transcription or stability of hypothalamic natriuretic peptide mRNAs in vivo.

Gene expression of central and peripheral renin-angiotensin system components upon dietary sodium intake in rats

The effects of dietary sodium intake on the gene expression of the renin-angiotensin system (RAS) were investigated in rat central and peripheral tissues in a single set of experiment. Northern and reverse transcriptase-polymerase chain reaction (RT-PCR) techniques were used to detect mRNA expression in rats fed a low- or a high-sodium diet (5 or 500 mmol Na+/kg diet) for 20 days. Plasma and renal renin levels were elevated in rats maintained on the low-sodium diet. Sodium deprivation enhanced the expression of angiotensinogen, renin, AT1A and AT1B receptor subtypes in the hypothalamus, but suppressed them in the brainstem. Kidney and adrenal levels of those mRNAs were also enhanced in the sodium-restricted rats. Both AT1A and AT1B mRNAs changed in a similar magnitude in each tissue examined upon dietary sodium intake. AT1A was the predominant receptor subtype of AT1 in all the tissues examined in the present study except the adrenal gland. The present study demonstrated that dietary sodium modulated the gene expression of the RAS components in the central and peripheral tissues. It also showed that the RAS components in the brainstem and hypothalamus were differentially expressed upon sodium deprivation. This suggests different roles of the RAS in these tissues in maintaining body fluid homeostasis in response to different sodium intakes.

Angiotensin II receptor content within the subfornical organ and organum vasculosum lamina terminalis increases after experimental subarachnoid haemorrhage in rats

Nests of cells within the central nervous system, namely the circumventricular organs (CVOs) which include the subfornical organ (SFO), organum vasculosum lamina terminalis (OVLT), area postrema (AP) and the median eminence (ME) are known to contain not only receptors for angiotensin II (ANG II) but also ANG II itself. Though the significance of this central ANG II network in the pathophysiology of certain conditions like hypertension is well established, there appears to be a lack of knowledge as to how this system might be involved after subarachnoid haemorrhage (SAH). In this study, we have investigated ANG II receptor content change at various circumventricular organs after experimental subarachnoid haemorrhage in rats using a transcervical transclival model. ANG II receptor content was detected by in vivo autoradiography using intracisternal ANG II Sar 1, Ile 8 labelled with iodine (I) 125 both at 30 minutes and 48 hours after the SAH. Serum angiotensin converting enzyme activity was also detected during the time course reflecting the involvement of the peripheral angiotensin system and showed an early rise and a fall after two days. Immunohistochemistry was utilized to show the ANG II-containing cells within the circumventricular organs. SFO and OVLT were found to have a statistically significant increase in ANG II receptor content persisting over two days after the SAH. These alterations in the receptor content of CVOs may indicate their possible role in delayed ischaemic deficits seen after SAH.

Sodium or chloride deficiency lowers muscle intracellular pH in growing rats

Sodium deficiency and chloride deficiency are associated with a contracted extracellular (ECF) volume and impaired growth in young children and growing rats. In cell culture, lowering sodium in the medium reduces growth factor-stimulated Na+/H+ exchange activity, intracellular pH (pHi), and DNA synthesis. We studied the effect of chronic sodium deficiency and chloride deficiency upon growth, extracellular acid base status, and muscle pHi in young rats. We fed growing rats for 21 days either a control diet, or one deficient in sodium (0.005%), chloride (0.005%), or calories. Muscle pHi was measured using 31phosphorus nuclear magnetic resonance spectroscopy. Rats fed either the sodium-deficient or chloride-deficient diet developed ECF volume contraction and hyponatremia; growth in length and weight was impaired. Muscle pHi was decreased (pHi = 7.074 +/- 0.006, 7.078 +/- 0.006 vs. control 7.100 +/- 0.002; P < 0.02). In calorie-restricted rats, growth was impaired but pHi was not affected (pHi 7.103 +/- 0.008). Metabolic alkalosis developed in the chloride-deficient group; acid base status was not affected in the sodium-deficient group. Despite differences in ECF acid base status, both groups had a low muscle pHi. We speculate that the low muscle pHi was a result of the ECF volume contraction and hyponatremia; low muscle pHi may contribute to retarded cell growth.

Different effects of chronic K+ depletion on forebrain and peripheral angiotensin II receptors in young rats

K+ depletion stimulates the circulating renin-angiotensin system and affects the regulation of peripheral angiotensin II receptors. The effects of K+ depletion on the regulation of central angiotensin II receptors are unknown. We studied the effects of selective K+ depletion (less than 0.05% in diet for 16 days) on angiotensin II receptor number in kidneys, adrenal glands, and selected brain areas of young rats. K+ depletion caused a significant increase in plasma renin activity and significantly decreased angiotensin II receptor number in the kidney glomeruli and medulla, and in the adrenal zona glomerulosa and adrenal medulla. In the brain, the angiotensin II receptor number was unchanged in the subfornical organ and the hypothalamic paraventricular nucleus after 16 days of K+ depletion. An additional NaCl supplementation (0.02% in the drinking water) to K(+)-depleted rats produced a decrease in plasma renin activity but failed to affect subfornical organ or paraventricular angiotensin II receptor number. Our results suggest that in young animals, K+ depletion has a significant impact on the peripheral renin-angiotensin system without affecting the density of forebrain angiotensin II receptors.

Increased dithiothreitol-insensitive, type 2 angiotensin II receptors in selected brain areas of young rats

1. Angiotensin II receptors have been studied by quantitative autoradiography in selected brain areas of young (2-week-old) and adult (8-week-old) rats. 2. In young rats, angiotensin II receptors were present in brain areas which did not express receptors in the adult brain, such as thalamic nuclei, cortical areas, and the cerebellum. 3. Young rats had more angiotensin II receptors in the subfornical organ than adult rats. In the inferior olive, the number of angiotensin receptors in young animals was 10 times higher than that in adult rats. Angiotensin II binding in the inferior olive was insensitive to incubation in the presence of dithiothreitol. 4. Conversely, the number of angiotensin II receptors in the nucleus of the solitary tract was lower in young rats compared to adults. Incubation in the presence of dithiothreitol resulted in a more than 90% inhibition of angiotensin II binding in the nucleus of the solitary tract. 5. Our results indicate the presence of two types of angiotensin II receptor in brain, one sensitive (type 1) and one insensitive (type 2) to the reducing agent dithiothreitol. 6. The expression of type 2 angiotensin II receptors, insensitive to dithiothreitol, is more marked in young rats, indicating a role for this type of angiotensin receptors in brain development.

Autoradiographic localization of subtypes of angiotensin II antagonist binding in the rat brain

The non-peptide angiotensin II receptor compounds DuP 753 and WL 19 were utilized to detect subtypes of [125I]Sar1-Ile8-angiotensin II binding to angiotensin II receptors in the rat brain. In rat forebrain homogenates, DuP 753 and WL 19 produced a partial displacement of [125I]Sar1-Ile8-angiotensin II binding with DuP 753 displacing approximately 65% of the binding and WL 19 displacing approximately 35% of the binding. Using the techniques of quantitative receptor autoradiography, a distinct regional distribution of the subtypes of angiotensin II antagonist bind was detected. The angiotensin II-1 binding site (the receptor subtype preferentially displaced by DuP 753) appeared to predominate in the dipsogenic, cardiovascular and endocrine areas, including the subfornical organ, paraventricular and periventricular nuclei of the hypothalamus, anterior pituitary, dorsal motor nucleus of the vagus, nucleus of the solitary tract and the area postrema. Additional areas that contained predominantly the angiotensin II-1 receptor subtype were the ventral hippocampus, substantia gelatinosa of the trigeminal nucleus, nucleus of the lateral olfactory tract, piriform cortex and median preoptic nucleus. The angiotensin II-2 binding site (displaced by WL 19) was the predominant subtype in the thalamus, inferior olive, lateral septum, subthalamic nucleus, locus coeruleus, medial geniculate and medial amygdala. Several areas of the brain appeared to contain both receptor subtypes, including the superior and inferior colliculi, and the olfactory bulb. The angiotensin II-1 binding site was concentrated in areas of the brain involved in mediating angiotensin II effects on drinking, endocrine status and blood pressure. Localization of angiotensin II-2 sites in the thalamus and areas of the brain which process sensory information suggests a novel modulatory role for angiotensin II at this receptor subtype. These results indicate that DuP 753 and WL 19 are highly selective for angiotensin II binding site subtypes in the brain and that, in general these subtypes are compartmentalized in distinct brain regions. The non-peptide compounds used in these studies should provide excellent tools to discern the functional role of angiotensin II receptor subtypes in the brain.