Immunccytochemical localization of angiotensinogen in rat brain: dependence of neuronal immunoreactivity on method of tissue processing

Brain angiotensin and body fluid homeostasis

Angiotensinogen, the precursor molecule of the peptides angiotensin I, II, and III, is synthesized in the brain and the liver. Evidence is reviewed that angiotensin II, and possibly angiotensin III, that are generated within the brain act within neural circuits of the central nervous system to regulate body fluid balance. Immunohistochemical studies in the rat brain have provided evidence of angiotensin-containing neurons, especially in the hypothalamic paraventricular nucleus, subfornical organ, periventricular region, and nucleus of the solitary tract, as well as in extensive angiotensin-containing fiber pathways. Angiotensin immunoreactivity is observed by electron microscope in synaptic vesicles in several brain regions, the most prominent of these being the central nucleus of the amygdala. Neurons in many parts of the brain (lamina terminalis, paraventricular and parabrachial nuclei, ventrolateral medulla, and nucleus of the solitary tract) known to be involved in the regulation of body fluid homeostasis exhibit angiotensin receptors of the AT(1) subtype. Pharmacological studies in several species show that intracerebroventricular administration of AT(1) receptor antagonist drugs inhibit homeostatic responses to the central administration of hypertonic saline, intravenous infusion of the hormone relaxin, or thermal dehydration. Responses affected by centrally administered AT(1) antagonists are water drinking, vasopressin secretion, natriuresis, increased arterial pressure, reduced renal renin release, salt hunger, and thermoregulatory adjustments. We conclude that angiotensinergic neural pathways in the brain probably have an important homeostatic function, especially in regard to osmoregulation and thermoregulation, and the maintenance of arterial pressure.

Angiotensinogen, prorenin, and renin are Co-localized in the secretory granules of all glandular cells of the rat anterior pituitary: an immunoultrastructural study

In addition to the circulating renin-angiotensin system (RAS), a local system has been postulated in the anterior pituitary because immunodetection of its components in various mammalian species. However, different cell types appear to be involved in different species, and there is no general consensus on the subcellular localization of prorenin, renin and angiotensinogen. In this ultrastructural study, we investigated and quantified the presence of these components using double or triple immunogold labeling methods, in all the immunologically identified glandular cell types of the rat anterior pituitary. In contrast to previous reports, all these components were identified not only in lactotropes and gonadotropes but also in somatotropes, corticotropes, and thyrotropes. The highest levels were detected in lactotropes and gonadotropes, and renin gave the greatest signal. Angiotensinogen, prorenin, and renin were co-localized in the secretory granules of all rat pituitary glandular cell types. The simultaneous detection of the substrate (angiotensinogen) and both its specific cleavage enzyme and its proenzyme within the same granule suggests intragranular processing of this component. Moreover, the localization of these three constituents in the secretory granules also suggests that, in the rat anterior pituitary, they follow the regulated secretory pathway.

Novel perspectives on pituitary and brain angiotensinogen

All the angiotensin peptides originate from angiotensinogen, a glycoprotein synthesized by several tissues, including the brain and the anterior pituitary. In the rat, immunohistochemistry has been used to localize angiotensinogen in gonadotropes and in uncharacterized cells surrounding sinusoids. Both cell types are capable of secreting angiotensinogen in cell culture; only the gonadotropes contain angiotensin II (AngII) and are capable of secreting it in culture. It has been asserted that the perisinusoidal cells are the only source of angiotensinogen for the generation of AngII by gonadotropes. Our current data favor the existence of a complete intracellular renin-angiotensin system (RAS) in gonadotropes and a separate extracellular system which utilizes the high concentration of angiotensinogen from perisinusoidal cells. Furthermore, we postulate that gonadotrope AngII serves mainly reproductive functions, while the proximity of angiotensinogen-secreting cells to folliculostellate cells, and their access to the intercellular sinusoidal and follicular spaces, places the extracellular RAS in a strategic position to affect pituitary growth and the mediation of acute-phase immune responses. In the rat brain, angiotensinogen is expressed by the 16-18th day of fetal life and by areas generally concerned with vasopressor, electrolyte, and fluid homeostasis. Antisense deoxyoligonucleotides to angiotensinogen mRNA lower blood pressure in hypertensive rats and inhibit in vitro growth of neuroblastoma cells, indicating a significant role for angiotensinogen in mitogenic and homeostatic functions. It is commonly agreed that astrocytes express angiotensinogen. Neuronal angiotensinogen has also been demonstrated by immunohistochemistry, as a secretion from neuronal cell cultures, and by reverse-transcriptase polymerase chain reaction. The fate of secreted astrocytic and neuronal angiotensinogen remains obscure. Angiotensinogen is regulated in a tissue-specific manner with smaller or absent responses observed for brain tissue. By using astrocyte and neuronal cultures the actions on angiotensinogen production of growth hormone, IGF-1, inflammatory lipopolysaccharide, and phorbol ester have been examined. Recent observations show that angiotensinogen is regulated positively or negatively by glucocorticoids and that a positive synergism between cAMP and glucocorticoids exists. On the basis of analogous systems for other proteins, a scheme involving glucocorticoid receptors, CREB, and AP-1 transcription factors is formulated to explain glucocorticoid-cAMP interactions. These transcriptional interactions may form a significant functional link between the RAS and adrenergic mechanisms.

Subcellular localization of angiotensin II immunoreactivity in the rat cerebellar cortex

We localized angiotensin II (Ang II) immunoreactivity in the rat cerebellar cortex with immunogold staining methods. Perfusion fixation with high amounts of glutaraldehyde and the use of cryoultramicrotomy caused remarkable changes in immunostaining versus formaldehyde/picric acid fixation. With the use of monoclonal and polyclonal anti-Ang II, Ang II immunoreactivity was prominent in cerebellar neurons such as Purkinje, granule, basket, and stellate cells. At the subcellular level, the peptide was clearly localized in nuclei, and in some cell types, such as endothelial and granule cells, it was nearly exclusively present in the transcriptionally active euchromatin. Intracellular Ang II immunoreactivity was also detected in vesicle-like structures in cytoplasm and mitochondria and at cell-cell contacts. Additional experiments with liver and adrenal tissue confirmed the nuclear localization of Ang II immunoreactivity, suggesting a role of Ang II in the regulation of gene transcription.

Molecular forms of rat angiotensinogen in plasma and brain: identification by isoelectric focusing and immunoblot analysis

Angiotensinogen (Ao) is the glycoprotein precursor of the vasoactive peptide angiotensin II. While Ao is synthesized as multiple molecular forms, the biochemical characteristics of this protein in blood and other tissues have not been defined. In this study, the charge heterogeneity of Ao in rat plasma, cerebrospinal fluid and that secreted by astrocyte and neuronal cultures was examined using analytical isoelectric focusing in combination with immunoblotting and quantitative image analysis. Normal rat male plasma Ao separated into 9 isoforms in the pI range 4.34-4.92 (1, 4.34; 2, 4.41; 3, 4.48; 4, 4.58; 5, 4.61; 6, 4.66; 7, 4.68; 8, 4.81; 9, 4.92); the percentage contribution of each to total plasma Ao was 13, 20, 23, 18, 2, 7, 10, 5, and < 1, respectively. A similar isoelectric focusing pattern was observed in female rat plasma with the exception that the relative contribution of isoform 6 was reduced to 2% of total Ao. Cerebrospinal fluid Ao displayed a more diverse charge heterogeneity than plasma Ao, focusing over a broader pI range of 4.42-5.24. Astrocytes and neurons secreted Ao isoforms in the pI range 4.44-5.29 and 4.42-4.95, respectively, with the astrocyte cultures showing additional bands towards the cathode. It was concluded that rat Ao is secreted as multiple charged forms that are regulated in a sex- and cell-specific manner. These differences between plasma and brain Ao suggest a functional diversity, a view which is supported by recent evidence linking Ao variants to hypertension.

Immunocytochemical localization of angiotensinogen in the fetal and neonatal rat brain

The aim of this study was to define the temporal appearance and regional distribution of angiotensinogen in the fetal and neonatal rat brain. This was done by immunocytochemical localization of angiotensinogen in brains from embryonic day 16 to postnatal day 12. Immunostaining was first observed on embryonic day 18, and persisted to postnatal day 2, in the choroid plexus and ependymal cells lining the third ventricle. This initial expression of angiotensinogen at embryonic day 18 was followed at postnatal day 20 by a rapid progression of angiotensinogen staining appearing in astrocytes in the paraventricular nucleus, medial preoptic area, ventromedial and arcuate hypothalamic nuclei; these areas showed the highest astrocyte staining intensity in the brain. This was followed sequentially by staining in areas of the thalamus, midbrain, forebrain and brainstem. In general, neuroglial staining was higher in regions proximal to the cerebral ventricles and cerebral aqueduct. Neuronal angiotensinogen was observed at day postnatal day 0 and later. The most consistent immunopositive areas were in the forebrain and thalamus; in particular, the hippocampus, anterior and posterior cingulate cortex, basal and lateral amygdala, the caudate-putamen, globus pallidus, lateral septum, medial habenular nuclei and lateral thalamic nuclei. Most of the immunopositive cells in the hypothalamus and brainstem were astrocytes, while those in the cortex were almost exclusively neurons. Staining in thalamic regions was both neuronal and neuroglial. From the intensity of staining and cell density, it was determined that a rapid increase in angiotensinogen occurs between embryonic day 20 and postnatal day 0, followed by further, smaller increases postnatally. In conclusion, this study has shown that angiotensinogen, the protein from which angiotensin II is generated, is present in the rat fetal brain. The timing of its appearance supports the establishment of a renin-angiotensin system by late gestation. Its predominance in fetal hypothalamic nuclei and in thalamic, cerebellar and cortical neurons suggests major roles in prenatal fluid and electrolyte balance, in sensorimotor development and in brain maturation.

Location and secretion of brain angiotensinogen

Angiotensinogen is a glycoprotein with intriguing structural similarities to the serine proteinase inhibitors but with only one known function: to act as a substrate in the enzymatic generation of angiotensin peptides. It is expressed as a constitutive protein by the liver and various other tissues, including the brain. It is in this tissue that the expression of angiotensinogen attains its most complex and controversial manifestations. In late gestation, an unfolding of cellular expression occurs, starting at an epicentre in the eppendymal and astroglia cells of the hypothalamus, which rapidly and sequentially spreads to sub-cortical and then cortical regions, concentrating at sites of electrolyte, fluid and pressure regulation. This initial burgeoning of astroglial angiotensinogen is trailed by a wave of neuronal expression in various limbic and sensorimotor regions of the brain. The predominance of AT2 receptors in these regions suggests that the RAS actions are mediated by AT2 receptors. The angiotensinogen found in the CSF and secreted by cultures of glia and neurones is similar to the two major molecular sizes found in plasma. However, by electrophoretic separation on the basis of charge imparted by differential glycosylation, it can be shown that glia and neurones secrete distinct forms. The expression of different forms is under hormonal regulation. If these structural forms are shown to affect function, then the resulting ramifications may extend to pathological conditions, such as hypertension. Primary cell cultures of astrocytes secrete angiotensinogen constitutively and in a region-specific manner related to the size of the sub-population of secretory cells. Neurone cultures secrete angiotensinogen at about 25% the rate of hypothalamic astrocytes. The use of RT-PCR shows that both cell types express angiotensinogen mRNA. There is still an unresolved mismatch between these data and in situ hybridization histochemistry which shows expression limited to astrocytes but it is suggested that changes to more appropriate techniques will resolve any outstanding discrepancies.

Angiotensin peptides in spontaneously hypertensive and normotensive Donryu rats

The renin-angiotensin system has been implicated in the pathogenesis of hypertension in spontaneously hypertensive rats (SHR). Given that SHR may have normal or suppressed plasma levels of renin and angiotensin peptides, we examined whether the tissue levels of angiotensin peptides are elevated in these rats. We measured angiotensin-(1-7) [Ang-(1-7)], Ang II, and Ang I in plasma, kidney, adrenal, heart, aorta, brown adipose tissue, lung, and brain of male SHR and normotensive Donryu rats at 6, 10, and 20 weeks of age. SHR had higher blood pressures and ratios of heart weight to body weight at all ages. Plasma renin levels of SHR were 13% to 32% of the levels of Donryu rats. Although plasma angiotensin-converting enzyme activity was lower in SHR than in Donryu rats, lung was the only SHR tissue with a reduced Ang II-Ang I ratio. Ang II levels in SHR adrenal were 24% to 42% of the levels of Donryu adrenal, and for SHR plasma, aorta, brown adipose tissue, and lung, Ang II levels were 38% to 93% of the levels of Donryu rats. For kidney and heart, Ang II levels were similar in SHR and Donryu rats at 6 weeks of age although suppressed in SHR at 10 and 20 weeks. Moreover, brain Ang II levels were higher in SHR than Donryu rats at 6 weeks of age and similar at 10 and 20 weeks of age.(ABSTRACT TRUNCATED AT 250 WORDS)

Angiotensin and bradykinin peptides in the TGR(mRen-2)27 rat

The transgenic TGR(mRen-2)27 rat, in which the Ren-2 mouse renin gene is transfected into the genome of the Sprague-Dawley rat, develops severe hypertension at a young age that responds to inhibitors of angiotensin-converting enzyme and to antagonists of the type 1 angiotensin II (Ang II) receptor. Despite this evidence that the hypertension is Ang II dependent, TGR(mRen-2)27 rats have suppressed renal renin and renin mRNA content, and there is controversy concerning the plasma levels of renin and Ang II in these rats. We investigated the effect of the transgene on circulating and tissue levels of angiotensin and bradykinin peptides in 6-week-old male homozygous TGR(mRen-2)27 rats. Systolic blood pressure of TGR(mRen-2)27 rats was 212 +/- 4 mm Hg (mean +/- SEM, n = 25) compared with 108 +/- 2 mm Hg (n = 29) for age- and sex-matched Sprague-Dawley rats. Compared with control rats, TGR(mRen-2)27 rats had increased plasma levels of active renin (4.5-fold), prorenin (300-fold), and Ang II (fourfold) as well as tissue levels of Ang II (twofold to fourfold in kidney, adrenal, heart, aorta, brown adipose tissue, and lung and 18-fold in brain). Plasma angiotensinogen levels were reduced to 73% of control, and plasma aldosterone levels were increased fourfold. Plasma angiotensin-converting enzyme was reduced to 64% of control. Compared with control rats, TGR(mRen-2)27 rats had increased bradykinin levels in brown adipose tissue (1.9-fold) and lung (1.6-fold).(ABSTRACT TRUNCATED AT 250 WORDS)

Sheep hypothalamus contains a non-angiotensin ligand for type 1 and type 2 angiotensin II receptors

1. The aim of this study was to determine whether the brain contains an alternative ligand for angiotensin II (AII) receptors. 2. A radioreceptor assay based upon bovine cerebellar membranes (Type 2 AII receptors) was used to monitor the partial purification of an AII-like material from sheep hypothalami. 3. This material displaces 125I-[Sar1, Ala8]-AII from both type 1 (rat adrenal capsular membranes) and Type 2 AII receptors in a manner parallel to that of AII. It has a size of approximately 30,000 Da, is strongly cationic, is stable to boiling but is destroyed by trypsin. It is not recognized by AII antisera. 4. These data provide direct evidence for a non-angiotensin endogenous ligand for brain AII receptors. This novel ligand may play a role in the regulation of blood pressure and other actions mediated by brain AII receptors.

Angiotensinogen is secreted by pure rat neuronal cell cultures

Previous studies are divided between those which support a neuroglial (astrocyte) source for brain angiotensinogen and those which indicate that both astrocytes and neurones synthesize the precursor of angiotensin II. In this study, separate cultures of astrocytes and neuronal cells were prepared and established as being essentially pure by appropriate immunocytochemical cell markers. Angiotensinogen production by these cultures, as measured by a direct radioimmunoassay, was 20.74 +/- 3.62 ng angiotensinogen/10(6) cells/24 h (mean +/- S.D., n = 8) for astrocytes and 4.39 +/- 0.94 ng/10(6) cells/24 h (mean +/- S.D., n = 29) for neurones. Angiotensinogen secretion from both cell types was unaffected by treatments which stimulate the regulatory secretory pathway by modulating intracellular cAMP levels. In contrast, it was reduced from 23.20 +/- 2.14 to 8.14 +/- 1.31 ng/10(6) cells/24 h (S.E.M., n = 7) in astrocyte cultures by the constitutive pathway inhibitor, monensin. Angiotensinogen secreted by astrocytes and neurones was compared to pure angiotensinogen and that in plasma and cerebrospinal fluid (CSF) by cation-exchange mono S column chromatography. Pure angiotensinogen eluted as two separate peaks corresponding to the major forms of plasma angiotensinogen, whereas angiotensinogen in CSF and culture media coeluted with a third minor form of plasma angiotensinogen. It was concluded that neuronal cells as well as astrocytes secrete angiotensinogen which is distinctly different from plasma angiotensinogen.

Angiotensin peptides in brain and pituitary of rat and sheep

Several lines of evidence indicate that angiotensin peptides may be formed in the brain, where angiotensin II (Ang II) and angiotensin-(1-7) (Ang-(1-7)) may function as neurotransmitters. However, there is considerable controversy concerning the identity and levels of angiotensin peptides in the brain. We have used a novel high performance liquid chromatography-based radioimmunoassay to measure Ang-(1-7), Ang II, Ang-(1-9) and Ang I in various brain regions and in the pituitary of the rat and sheep. We also studied the effect of different methods of tissue extraction, and the effect of the converting enzyme inhibitor ramipril, on angiotensin peptide levels in the rat hypothalamus. The levels of Ang-(1-7), Ang II, Ang-(1-9) and Ang I were low (<25 fmol/g) in all brain regions examined, except for the sheep median eminence and cerebellar cortex where Ang II levels were 385±116 and 193±37 fmol/g (mean ± SEM, n = 6), respectively. Pituitary Ang II levels were 103±13 fmol/g in the rat and 63±18 fmol/g in the sheep. The levels of Ang-(1-7), Ang-(1-9) and Ang I were much lower than those of Ang II in brain and pituitary. Ang-(1-7) levels in the rat hypothalamus were low (<6 fmol/g) but methods of extraction which involved freezing and thawing of the tissue resulted in substantially higher levels of this peptide. Ang II levels in the rat hypothalamus (18±3 fmol/g) were reduced to undetectable levels (<6 fmol/g) by ramipril administration. The low levels of angiotensin peptides in the hypothalamus and brainstem indicate that if these peptides function as neurotransmitters in these regions, then they are of particularly low abundance. Moreover, our results indicate that the high levels of Ang-(1-7) reported previously for rat hypothalamus may be artefactual, due to the method of tissue extraction.