Central effects of angiotensins on drinking and blood pressure: structure-activity relationships

Angiotensin AT1 receptors modulate the anxiogenic effects of angiotensin (5-8) injected into the rat ventrolateral periaqueductal gray

Losartan and PD 123,319 are non-peptide angiotensin (Ang) receptor antagonists for the AT1 and AT2 subtypes of Ang II receptors, respectively. The tetrapeptide Ang (5-8) is the smallest Ang-peptide that elicits anxiogenic effects on unconditioned and conditioned experimental models upon injection into the ventrolateral column of the periaqueductal gray (vlPAG), and Ang (5-8) can be synthesized (from Ang II or Ang III) and inactivated in this mesencephalic structure. The vlPAG is also known to play a central role in mechanisms of fear and anxiety. We therefore utilized male Wistar rats to examine the effects of losartan and PD 123,319 injections, selective antagonists of the AT1 and AT2 receptors, respectively, into the vlPAG in the elevated plus-maze, a classic rat model of anxiety, and against the anxiogenic effect of Ang (5-8) (0.4 nmol/0.25μL) upon injection into the same region. The anxiolytic profile was dependent on the dose of intra-vlPAG losartan, whereas no effects on experimental anxiety were observed in the plus-maze following PD 123,319 injection. The anxiogenic effect of Ang (5-8) injection into the vlPAG remained unchanged in the PD 123,319-pretreated rats, but the effect did not occur in losartan-pretreated rats. The results led us to suggest that the anxiogenic effect of Ang (5-8) injection into the vlPAG may depend on the local activation of AT1, but not AT2 receptors. Activation of AT1 receptors in structures nearby vlPAG may be tonically involved in fear and experimental anxiety.

Salt, Angiotensin II, Superoxide, and Endothelial Function

Proper function of the vascular endothelium is essential for cardiovascular health, in large part due to its antiproliferative, antihypertrophic, and anti-inflammatory properties. Crucial to the protective role of the endothelium is the production and liberation of nitric oxide (NO), which not only acts as a potent vasodilator, but also reduces levels of reactive oxygen species, including superoxide anion (O2•-). Superoxide anion is highly injurious to the vasculature because it not only scavenges NO molecules, but has other damaging effects, including direct oxidative disruption of normal signaling mechanisms in the endothelium and vascular smooth muscle cells. The renin-angiotensin system plays a crucial role in the maintenance of normal blood pressure. This function is mediated via the peptide hormone angiotensin II (ANG II), which maintains normal blood volume by regulating Na+ excretion. However, elevation of ANG II above normal levels increases O2•- production, promotes oxidative stress and endothelial dysfunction, and plays a major role in multiple disease conditions. Elevated dietary salt intake also leads to oxidant stress and endothelial dysfunction, but these occur in the face of salt-induced ANG II suppression and reduced levels of circulating ANG II. While the effects of abnormally high levels of ANG II have been extensively studied, far less is known regarding the mechanisms of oxidant stress and endothelial dysfunction occurring in response to chronic exposure to abnormally low levels of ANG II. The current article focuses on the mechanisms and consequences of this less well understood relationship among salt, superoxide, and endothelial function.

Angiotensin III: a physiological relevant peptide of the renin angiotensin system

The renin angiotensin system (RAS) is a peptide hormone system that plays an important role in the pathophysiology of various diseases, including congestive heart failure, hypertension, myocardial infarction, and diabetic nephropathy. This has led researchers to focus extensively on this system, leading to the discovery of various peptides, peptidases, receptors and signal transduction mechanisms intrinsic to the RAS. Angiotensinogen (AGT), angiotensin (Ang) II, Ang III, Ang IV, and Ang-(1-7) are the main biologically active peptides of RAS. However, most of the available studies have focused on Ang II as the likely key peptide from the RAS that directly and indirectly regulates physiological functions leading to pathological conditions. However, data from recent studies suggest that Ang III may produce physiologically relevant effects that are similar to those produced by Ang II. Hence, this review focuses on Ang III and the myriad of physiological effects that it produces in the body.

Angiotensin (5-8) modulates nociception at the rat periaqueductal gray via the NO-sGC pathway and an endogenous opioid

Angiotensins (Angs) modulate blood pressure, hydro-electrolyte composition, and antinociception. Although Ang (5-8) has generally been considered to be inactive, we show here that Ang (5-8) was the smallest Ang to elicit dose-dependent responses and receptor-mediated antinociception in the rat ventrolateral periaqueductal gray matter (vlPAG). Ang (5-8) antinociception seems to be selective, because it did not alter blood pressure or act on vascular or intestinal smooth muscle cells. The non-selective Ang-receptor (Ang-R) antagonist saralasin blocked Ang (5-8) antinociception, but selective antagonists of Ang-R types I, II, IV, and Mas did not, suggesting that Ang (5-8) may act via an unknown receptor. Endopeptidase EP 24.11 and amastatin-sensitive aminopeptidase from the vlPAG catalyzed the synthesis (from Ang II or Ang III) and inactivation of Ang (5-8), respectively. Selective inhibitors of neuronal-nitric oxide (NO) synthase, soluble guanylyl cyclase (sGC) and a non-selective opioid receptor (opioid-R) inhibitor blocked Ang (5-8)-induced antinociception. In conclusion, Ang (5-8) is a new member of the Ang family that selectively and strongly modulates antinociception via NO-sGC and endogenous opioid in the vlPAG.

The role of the renin—angiotensin system in the pathogenesis of intracranial aneurysms

Introduction: Recent work has begun to elucidate the pathogenesis of intracranial aneurysms (IA) and has shown that many genes are involved in the risk for this condition. There has also been increasing research interest in the renin—angiotensin system (RAS) in the brain and its involvement in a range of cardiovascular and neurological disorders. The possibility that the RAS is implicated in the pathogenesis of IA merits further investigation. The aim of this article is to review the literature on the pathogenesis of IA and the pathophysiological significance of the brain RAS, and to identify directions for research into their association.

Methods and results : A survey of the literature in these fields shows that although factors contributing to systemic hypertension predispose to IA, a large number of genes involved in endothelial cell adhesion, smooth muscle activity, extracellular matrix dynamics and the inflammatory and immune responses are also implicated. The brain RAS has a significant role in regulating blood pressure and in maintaining cerebrovascular autoregulation, but angiotensin II receptors are also involved in the maintenance of endothelial cell and vascular smooth muscle function and in the inflammatory response in the brain.

Conclusions: There is strong, albeit largely circumstantial, evidence in the literature for a relationship between the brain RAS and the formation of IA. Research on the association between polymorphisms in RAS-related genes and the incidence of unruptured and ruptured IA is indicated.

The brain RAS and Alzheimer's disease

Alzheimer's disease (AD) has become a major world-wide health problem with ever rising costs associated with the treatment and care of afflicted individuals. As life expectancy has increased the occurrence of dementia has also increased. Hypertension during middle adulthood is correlated with a significantly elevated risk of cognitive impairment later in life. Treatment with antihypertensive drugs, particularly angiotensin converting enzyme (ACE) inhibitors and angiotensin receptor blockers (ARBs), has been reported to reduce the likelihood and slow the progression of AD; however, the use of ACE inhibitors may be accompanied by an increase in amyloid beta protein(1-42) accumulation. This review summarizes available information regarding the brain renin-angiotensin system (RAS), and specifically the efficacy of ACE inhibitors as anti-dementia agents, and considers the recently discovered AT(4) receptor and associated agonist drugs as potential new therapeutic targets to treat memory impairments associated with AD. We conclude with a description of recent efforts by members of our laboratory to develop blood-brain barrier penetrant angiotensin IV analogue drugs that facilitate cognition in animal models of AD. These efforts have resulted in a small molecule with desirable hydrophobicity characteristics that shows promise with respect to memory facilitation when peripherally administered.

Angiotensin receptor subtype mediated physiologies and behaviors: new discoveries and clinical targets

The renin-angiotensin system (RAS) mediates several classic physiologies including body water and electrolyte homeostasis, blood pressure, cyclicity of reproductive hormones and sexual behaviors, and the regulation of pituitary gland hormones. These functions appear to be mediated by the angiotensin II (AngII)/AT(1) receptor subtype system. More recently, the angiotensin IV (AngIV)/AT(4) receptor subtype system has been implicated in cognitive processing, cerebroprotection, local blood flow, stress, anxiety and depression. There is accumulating evidence to suggest an inhibitory influence by AngII acting at the AT(1) subtype, and a facilitory role by AngIV acting at the AT(4) subtype, on neuronal firing rate, long-term potentiation, associative and spatial learning, and memory. This review initially describes the biochemical pathways that permit synthesis and degradation of active angiotensin peptides and three receptor subtypes (AT(1), AT(2) and AT(4)) thus far characterized. There is vigorous debate concerning the identity of the most recently discovered receptor subtype, AT(4). Descriptions of classic and novel physiologies and behaviors controlled by the RAS are presented. This review concludes with a consideration of the emerging therapeutic applications suggested by these newly discovered functions of the RAS.

The brain angiotensin system and extracellular matrix molecules in neural plasticity, learning, and memory

The brain renin-angiotensin system (RAS) has long been known to regulate several classic physiologies including blood pressure, sodium and water balance, cyclicity of reproductive hormones and sexual behaviors, and pituitary gland hormones. These physiologies are thought to be under the control of the angiotensin II (AngII)/AT1 receptor subtype system. The AT2 receptor subtype is expressed during fetal development and is less abundant in the adult. This receptor appears to oppose growth responses facilitated by the AT1 receptor, as well as growth factor receptors. Recent evidence points to an important contribution by the brain RAS to non-classic physiologies mediated by the newly discovered angiotensin IV (AngIV)/AT4 receptor subtype system. These physiologies include the regulation of blood flow, modulation of exploratory behavior, and a facilitory role in learning and memory acquisition. This system appears to interact with brain matrix metalloproteinases in order to modify extracellular matrix molecules thus permitting the synaptic remodeling critical to the neural plasticity presumed to underlie memory consolidation, reconsolidation, and retrieval. There is support for an inhibitory influence by AngII activation of the AT1 subtype, and a facilitory role by AngIV activation of the AT4 subtype, on neuronal firing rate, long-term potentiation, associative and spatial learning. The discovery of the AT4 receptor subtype, and its facilitory influence upon learning and memory, suggest an important role for the brain RAS in normal cognitive processing and perhaps in the treatment of dysfunctional memory disease states.

AT4 receptor binding in the developing rabbit

The binding of the AT(4)-specific analog, divalinal-AngIV (Dival), was studied in rabbit fetuses of various gestational ages. Saturation isotherm and competition data from selected tissues indicate that fetal Dival binding sites are saturable and specific for AT(4) ligands. Autoradiographs revealed that binding was present in all the specimens examined. The peripheral nerves, kidneys, and heart were particularly heavily labeled. Labeling of some tissues, such as forming bones, was not constant as gestational age increased. Other tissues, including multilocular fat, sinus hairs, and enamel organs of nascent teeth, exhibited substantial binding as these tissues developed.

Neural plasticity and the brain renin-angiotensin system

The brain renin-angiotensin system mediates several classic physiologies including body water balance, maintenance of blood pressure, cyclicity of reproductive hormones and sexual behaviors, and regulation of pituitary gland hormones. In addition, angiotensin peptides have been implicated in neural plasticity and memory. The present review initially describes the extracellular matrix (ECM) and the roles of cell adhesion molecules (CAMs), matrix metalloproteinases, and tissue inhibitors of metalloproteinases in the maintenance and degradation of the ECM. It is the ECM that appears to permit synaptic remodeling and thus is critical to the plasticity that is presumed to underlie mechanisms of memory consolidation and retrieval. The interrelationship among long-term potentiation (LTP), CAMs, and synaptic strengthening is described, followed by the influence of angiotensins on LTP. There is strong support for an inhibitory influence by angiotensin II (AngII) and a facilitory role by angiotensin IV (AngIV), on LTP. Next, the influences of AngII and IV on associative and spatial memories are summarized. Finally, the impact of sleep deprivation on matrix metalloproteinases and memory function is described. Recent findings indicate that sleep deprivation-induced memory impairment is accompanied by a lack of appropriate changes in matrix metalloproteinases within the hippocampus and neocortex as compared with non-sleep deprived animals. These findings generally support an important contribution by angiotensin peptides to neural plasticity and memory consolidation.

Angiotensin, thirst, and sodium appetite

Angiotensin (ANG) II is a powerful and phylogenetically widespread stimulus to thirst and sodium appetite. When it is injected directly into sensitive areas of the brain, it causes an immediate increase in water intake followed by a slower increase in NaCl intake. Drinking is vigorous, highly motivated, and rapidly completed. The amounts of water taken within 15 min or so of injection can exceed what the animal would spontaneously drink in the course of its normal activities over 24 h. The increase in NaCl intake is slower in onset, more persistent, and affected by experience. Increases in circulating ANG II have similar effects on drinking, although these may be partly obscured by accompanying rises in blood pressure. The circumventricular organs, median preoptic nucleus, and tissue surrounding the anteroventral third ventricle in the lamina terminalis (AV3V region) provide the neuroanatomic focus for thirst, sodium appetite, and cardiovascular control, making extensive connections with the hypothalamus, limbic system, and brain stem. The AV3V region is well provided with angiotensinergic nerve endings and angiotensin AT1 receptors, the receptor type responsible for acute responses to ANG II, and it responds vigorously to the dipsogenic action of ANG II. The nucleus tractus solitarius and other structures in the brain stem form part of a negative-feedback system for blood volume control, responding to baroreceptor and volume receptor information from the circulation and sending ascending noradrenergic and other projections to the AV3V region. The subfornical organ, organum vasculosum of the lamina terminalis and area postrema contain ANG II-sensitive receptors that allow circulating ANG II to interact with central nervous structures involved in hypovolemic thirst and sodium appetite and blood pressure control. Angiotensin peptides generated inside the blood-brain barrier may act as conventional neurotransmitters or, in view of the many instances of anatomic separation between sites of production and receptors, they may act as paracrine agents at a distance from their point of release. An attractive speculation is that some are responsible for long-term changes in neuronal organization, especially of sodium appetite. Anatomic mismatches between sites of production and receptors are less evident in limbic and brain stem structures responsible for body fluid homeostasis and blood pressure control. Limbic structures are rich in other neuroactive peptides, some of which have powerful effects on drinking, and they and many of the classical nonpeptide neurotransmitters may interact with ANG II to augment or inhibit drinking behavior. Because ANG II immunoreactivity and binding are so widely distributed in the central nervous system, brain ANG II is unlikely to have a role as circumscribed as that of circulating ANG II. Angiotensin peptides generated from brain precursors may also be involved in functions that have little immediate effect on body fluid homeostasis and blood pressure control, such as cell differentiation, regeneration and remodeling, or learning and memory. Analysis of the mechanisms of increased drinking caused by drugs and experimental procedures that activate the renal renin-angiotensin system, and clinical conditions in which renal renin secretion is increased, have provided evidence that endogenously released renal renin can generate enough circulating ANG II to stimulate drinking. But it is also certain that other mechanisms of thirst and sodium appetite still operate when the effects of circulating ANG II are blocked or absent, although it is not known whether this is also true for angiotensin peptides formed in the brain. Whether ANG II should be regarded primarily as a hormone released in hypovolemia helping to defend the blood volume, a neurotransmitter or paracrine agent with a privileged role in the neural pathways for thirst and sodium appetite of all kinds, a neural organizer especially in sodium appetit

The neuronal role of angiotensin II in thirst, sodium appetite, cognition and memory

Within the past two decades, a great deal has been learnt about the renin-angiotensin system in the brain. The renin-angiotensin system is one of the best-studied enzyme-neuropeptide systems in the brain. The diversity of localization of this peptide throughout the brain has implied a variety of potential functions. Besides its classical role in the regulation of blood pressure and body-fluid homeostasis, it has more subtle functions involving complex mechanisms such as learning and memory. The profound effects on behaviour produced by angiotensin are of broad interest to neuroscientists. The mechanisms of action differ depending on whether angiotensin is locally synthesized and whether regulation is governed by neural or metabolic inputs impinging on the neurones. Its central action is mediated through peptidergic receptors present on neurones. The description of the receptor subtypes AT1 and AT2 for angiotensin II and the development of non-peptidic specific angiotensin receptor subtype antagonists have opened a new area in this field of research. The AT1 site, which preferentially binds to angiotensin II and angiotensin III, appears to mediate the classical angiotensin functions concerned with maintenance of blood pressure and body-fluid control. In addition, most of the behavioural effects described so far are linked with AT1, although so-called psychotropic effects are presumed to be mediated by receptor systems other than the known specific angiotensin receptors. In fact, evidence for the existence of such receptors with high-affinity binding has been reported. The central action of angiotensin II mediated by AT2 is as yet unclear. Most reports concerning this receptor subtype suggest a role in differentiation and development, since the number of binding sites is higher in fetal and young rats than in adults. Furthermore, the neuronal effect of angiotensin II in the inferior olivary nucleus which is blocked specifically by AT2 antagonists suggests an involvement in motor control. Over the next few years we should find answers to many of the questions currently unanswered about angiotensin function and, given the rapid progress in research on this neuropeptide, it may serve as a model for the action of peptides on neuronal function in general.

Angiotensin III and IV activation of the brain AT1 receptor subtype in cardiovascular function

The present investigation determined that native angiotensins II and III (ANG II and III) were equipotent as pressor agents when ICV infused in alert rats, whereas native angiotensin IV (ANG IV) was less potent. An analogue of each of these angiotensins was prepared with a hydroxyethylamine (HEA) amide bond replacement at the N-terminus, yielding additional resistance to degradation. These three angiotensin analogues, HEA-ANG II, HEA-ANG III, and HEA-ANG IV, were equivalent with respect to maximum elevation in pressor responses when ICV infused; and each evidenced significantly extended durations of effect compared with their respective native angiotensin. Comparing analogues, HEA-ANG II had a significantly longer effect compared with HEA-ANG III, and HEA-ANG IV, whereas the latter were equivalent. Pretreatment with the AT1 receptor subtype antagonist, Losartan (DuP753), blocked subsequent pressor responses to each of these analogues, suggesting that these responses were mediated by the AT1 receptor subtype. Pretreatment with the specific AT4 receptor subtype antagonist, Divalinal (HED 1291), failed to influence pressor responses induced by the subsequent infusion of these analogues. These results suggest an important role for Ang III, and perhaps ANG IV, in brain angiotensin pressor responses mediated by the AT1 receptor subtype.

Comparative effects of angiotensin II and its degradation products angiotensin III and angiotensin IV in rat aorta

1. In the present study, the contractile effects of angiotensin III (AIII) and angiotensin IV (AIV) compared with those of angiotensin II (AII) were determined in rat aortic ring preparations. 2. All three peptides caused concentration-dependent contractions with similar maximal responses. AIII proved approximately 4 times less potent than AII, whereas AIV was about 1000 times less active than AII. 3. The selective AT1-receptor antagonist, losartan (10-300 nM) caused parallel rightward shifts of the concentration-response curves (CRC) for all three peptides. The Schild plot slopes for the effect of losartan on AIII curves were significantly lower than unity (P < 0.05). The selective AT2-receptor antagonist, PD123177 did not influence the CRCs for AII and AIV. However, the AIII curves were moderately shifted leftward in the presence of PD123177 (0.1 and 1 microM). 4. Destruction of the endothelium or incubation with the NO-synthesis inhibitor NG-monomethyl-L-arginine acetate (L-NMMA) (0.1 mM) significantly enhanced the contractile responses to all three peptides. 5. Tachyphylaxis was investigated by constructing a second CRC for all three peptides, after an interval of 1 h. The presence of endothelium significantly enhanced the development of tachyphylaxis to all three peptides. However, in endothelium-denuded preparations, the Emax value of the second curve elicited by AII was about 50%, compared with the first one, whereas for AIII and AIV Emax values were as high as 90% and 100%, respectively. 6. Our results indicate that both AIII and AIV are less potent but similarly efficacious vasoconstrictor agents compared with AII. Their contractile effects are also mediated by AT1-receptors and probably modulated by endothelium. Tachyphylaxis induced by AIII and AIV proved weaker than that for AII. Tachyphylaxis appears to be enhanced by the presence of an intact endothelium.

Characterization of a binding site for angiotensin IV on bovine aortic endothelial cells

We have characterized a specific binding site for angiotensin IV on bovine aortic endothelial cell membranes. Pseudo-equilibrium studies at 37 degrees C for 2 h have shown that this binding site recognizes angiotensin IV with a high affinity (Kd = 0.71; average of two experiments that yielded values of 0.71 and 0.72 nM). The binding site is saturable and relatively abundant with a maximal binding capacity of 0.59 pmol/mg protein (average of two experiments that yielded values of 0.39 and 0.78 pmol/mg of protein). Non-equilibrium kinetic analyses at 37 degree C revealed a calculated Kd of 59 pM (average of two experiments that yielded values of 67 and 50 pM). The binding site displays a high affinity for angiotensin receptors AT1 or AT2. An analysis of specificity showed that the binding site displays a high affinity for angiotensin IV, low affinities for angiotensin II, [Sar1, Val5, Ala8]angiotensin II and does not recognize L-158,809 (5,7-dimethyl-2-ethyl-3-[(2'-(1 H-tetrazole-5-yl)[1,1'-biphenyl]-4-yl)methyl]-3H-imidazo[4, 5-beta]pyridine H2O) and PD 123319 (1-[4-dimethylamino)3-methylphenyl]methyl-5-(diphenylacetyl) 4,5,6,7-tetrahydro-1 H-imidazo[4,5-c]pyridine-6-carboxylic acid). A few unrelated hormones (bradykinin, [Arg8] vasopressin, endothelin-1, atrial natriuretic factor, isoproterenol and adrenocorticotropic hormone) were unable to inhibit any 125I-angiotensin IV binding. The affinities of different structural analogues of angiotensin IV revealed that the N-terminal position is critical for receptor recognition and the C-terminal proline is also important. GTP gamma S and polyvinyl sulfate did not affect the binding, suggesting that the receptor is not coupled to a G-protein. The divalent cations Mg2+ and Ca2+ were shown to diminish the binding of 125I-angiotensin IV. Cross-linking of 125I-angiotensin IV to bovine aortic endothelial cell membranes in the presence of disuccinimidyl suberate, followed by sodium dodecyl sulfate-polyacrylamide gel electrophoresis (SDS-PAGE) revealed a major band of 186 +/- 12 kDa. The presence in high concentration of this angiotensin binding site on aortic endothelial cells suggest the existence of a novel mechanism involved in the control of vascular tone or vascular permeability.

A specific binding site for angiotensin II(3-8), angiotensin IV, in rabbit cardiac fibroblasts

This study demonstrates the existence of a high affinity binding site on rabbit cardiac fibroblasts of the hexapeptide (3-8) fragment of angiotensin II (AngIV). [125I]-AngIV binding is saturable, reversible and distinct from angiotensin II (AngII) receptors. At 37 degrees C equilibrium of [125I]-AngIV binding is reached within 2 h. AngIV displaces [125I]-AngIV bound to cultured rabbit cardiac fibroblasts whereas AngII receptor-specific ligands ([Sar1, Ile8]-AngII, Dup753, CGP42112A) do not. Scatchard plot analysis revealed that [125I]-AngIV binds to a single class of sites with Kd = 4.87 +/- 0.11 x 10(-9) mol/l, Bmax = 371 +/- 8.3 fmol/mg protein and a Hill coefficient of 0.92. In the presence of the non-hydrolyzable GTP analog GTPgammaS [125I]-AngIV binding in rabbit cardiac fibroblasts was not markedly affected, whereas binding of [125I]-(Sar1,IIe8)-AngII is reduced. The role of AngIV in the heart and in particular in cardiac fibroblasts is unknown, and the putative interaction of AngIV with AngII needs further characterization.

A specific binding site recognizing a fragment of angiotensin II in bovine adrenal cortex membranes

We have characterized a specific binding site for angiotensin IV in bovine adrenal cortex membranes. Pseudo-equilibrium studies at 37 degrees C for 2 h have shown that this binding site recognizes angiotensin IV with a high affinity (Kd = 0.24 +/- 0.03 nM). The binding site is saturable and relatively abundant (maximal binding capacity around 0.5 pmol/mg protein). Non-equilibrium kinetic analyses at 37 degrees C revealed a calculated kinetic Kd of 47 pM. The binding site is pharmacologically distinct from the classic angiotensin receptors AT1 or AT2. Competitive binding studies with bovine adrenal cortex membranes demonstrated the following rank order of effectiveness: angiotensin IV (Val-Tyr-Ile-His-Pro-Phe) = angiotensin II-(3-7) (Val-Tyr-Ile-His-Pro) > angiotensin III (Arg-Val-Tyr-Ile-His-Pro-Phe) > or = angiotensin II-(4-7) (Tyr-Ile-His-Pro) > angiotensin II (Asp-Arg-Val-Tyr-Ile-His-Pro-Phe) > angiotensin II-(1-6) (Asp-Arg-Val-Tyr-Ile-His) > angiotensin II-(4-8) (Tyr-Ile-His-Pro-Phe) > > > angiotensin II-(3-6) (Val-Tyr-Ile-His), angiotensin II-(4-6) (Tyr-Ile-His), L-158,809 (5,7-dimethyl-2-ethyl-3-[(2'(1-H-tetrazol-5-yl)[1,1'-biphenyl]-4-y l) methyl]-3-H-imidazo[4,5-beta]pyridine H2O) and PD 123319 (1-[4-(dimethylamino)3-methylphenyl]methyl-5-(diphenylacetyl)4,5,6 ,7- tetrahydro-1H-imidazo[4,5-c]pyridine-6-carboxylic acid). The divalent cations Mg2+ and Ca2+ were shown to diminish the binding of 125I-angiotensioffn IV to bovine adrenal cortex membranes.(ABSTRACT TRUNCATED AT 250 WORDS)

AT4 receptors: specificity and distribution

The AT4 receptor specifically binds Angiotensin (Ang) IV and is distinct from the AT1 and AT2 receptors which bind Ang II and Ang III. The AT4 receptor in bovine adrenal cortex has a Kd of 0.74 +/- 0.14 nM and a Bmax of 3.82 +/- 1.12 pmol/mg prot. Competition curves demonstrated the following rank order of affinity: Ang IV >> Ang III >> d-Arg - Ang II >> Sar1,Ile8 - Ang II = Ang II = Ang II (1-7) >> DuP753 = CGP42112A = PD 123177. AT4 receptors were present in many tissues from several mammalian species including human and monkey. AT4 and AT1/AT2 receptors revealed a differential distribution in the rat kidney.

Brain angiotensin receptor subtypes in the control of physiological and behavioral responses

This review summarizes emerging evidence that supports the notion of a separate brain renin-angiotensin system (RAS) complete with the necessary precursors and enzymes for the formation and degradation of biologically active forms of angiotensins, and several binding subtypes that may mediate their diverse functions. Of these subtypes the most is known about the AT1 site which preferentially binds angiotensin II (AII) and angiotensin III (AIII). The AT1 site appears to mediate the classic angiotensin responses concerned with body water balance and the maintenance of blood pressure. Less is known about the AT2 site which also binds AII and AIII and may play a role in vascular growth. Recently, an AT3 site was discovered in cultured neoblastoma cells, and an AT4 site which preferentially binds AII(3-8), a fragment of AII now referred to as angiotensin IV (AIV). The AT4 site has been implicated in memory acquisition and retrieval, and the regulation of blood flow. In addition to the more well-studied functions of the brain RAS, we review additional less well investigated responses including regulation of cellular function, the modulation of sensory and motor systems, long term potentiation, and stress related mechanisms. Although the receptor subtypes responsible for mediating these physiologies and behaviors have not been definitively identified research efforts are ongoing. We also suggest potential contributions by the RAS to clinically relevant syndromes such as dysfunctions in the regulation of blood flow and ischemia, changes in cognitive affect and memory in clinical depressed and Alzheimer's patients, and angiotensin's contribution to alcohol consumption.

Differential responses to angiotensin-(1-7) in the feline mesenteric and hindquarters vascular beds

Regional vascular responses to angiotensin (Ang)-(1-7), a heptapeptide derivative of Ang II were investigated in the feline hindquarters and mesenteric vascular beds under conditions of controlled flow. In the mesenteric vascular bed, injections of Ang-(1-7) in doses of 1, 3 and 10 micrograms produced dose-dependent decreases in mesenteric perfusion pressure whereas at doses of 30 and 100 micrograms, increases were observed. In contrast, in the hindquarters circulation, low doses produced increases while high doses produced decreases in perfusion pressure. In both vascular beds the degree of vasoconstriction was weak, being less than 1% of that elicited by Ang II. The vasoconstrictor effect of Ang-(1-7) in both the mesenteric and hindquarters vascular bed was blocked by DuP 753 (1 mg/kg i.v.), an Ang receptor subtype 1 (AT1) antagonist. The vasodilator responses in both vascular beds were partially blocked by the nitric oxide synthase inhibitor, NG-nitro-L-arginine methyl ester (100 mg/kg i.v.) but were unaffected by the cyclooxygenase inhibitor, meclofenamate (2.5 mg/kg i.v.). The present results show that in the peripheral vascular bed of the cat, Ang-(1-7) causes vasodilation or modest vasoconstriction, depending on the dose and the regional vascular bed studied. The present data also suggest that the vasodilator effect of the peptide may be mediated in part by the release of endothelium-derived relaxing factor and the vasoconstrictor effect by activation of the AT1 receptor subtype.

Angiotensin-converting enzyme inhibitors have no effect on ovulation and ovarian steroidogenesis in the perfused rat ovary

The null hypothesis of this study was that the angiotensin-converting enzyme inhibitors, captopril and teprotide, would not reduce the number of ovulations in vivo and in vitro in the rat. Captopril (in three regimens) was administered continuously beginning prior to pregnant mare's serum gonadotropin and hCG to trigger ovulation. The number of in vivo ovulations were counted. Ovaries similarly primed with pregnant mare's serum gonadotropin were dissected and perfused in media with hCG and captopril (two regimens) or teprotide (one regimen). The number of in vitro ovulations and steroid production in the perfusions were evaluated. The results were evaluated by the Student's t test. Power calculations gave only a 20% chance of missing a 16% difference in ovulations or steroidogenesis. There was no inhibition of ovulation or change in steroid production in angiotensin-converting enzyme treated rats in vivo or in vitro. While angiotensin II has been shown to be an important mediator in the mechanism of ovulation, angiotensin-converting enzyme inhibition via captopril or teprotide does not result in angiotensin II antagonistic effects. Hypothetical mechanisms to explain this paradox are presented.

Angiotensin II(3-8) (ANG IV) hippocampal binding: potential role in the facilitation of memory

The present research characterizes a newly discovered ANG II(3-8) (ANG IV) binding site localized in structures associated with memory function (hippocampus, neocortex, cerebellum), as well as other brain stem structures (thalamus, inferior olivary nucleus). This site is not the AT1 or AT2 site that binds angiotensins II (ANG II) and III (ANG III) nor does it bind the nonpeptide AT1 or AT2 receptor antagonists DuP753 and PD123177, respectively. The intracerebroventricular (ICV) infusion of ANG IV was ineffective at inducing drinking in rats as compared with equivalent doses of ANG II and III. Although not as effective as ANG II or ANG III, ICV infusion of ANG IV did provoke a pressor response at the highest dose (100 pmol/min), which appeared to be mediated by ANG II (AT1)-type receptors and not the specific AIV binding site described here. By contrast, the ICV infusion of ANG IV resulted in greater effects upon retention and retrieval of a passive avoidance task as compared with ANG II. Specifically, ANG II was not different from the ICV infusion of artificial cerebrospinal fluid, while ANG IV improved retention and retrieval of this task.

Regulatory role of brain angiotensins in the control of physiological and behavioral responses

Considerable evidence now indicates that a separate and distinct renin-angiotensin system (RAS) is present within the brain. The necessary precursors and enzymes required for the formation and degradation of the biologically active forms of angiotensins have been identified in brain tissues as have angiotensin binding sites. Although this brain RAS appears to be regulated independently from the peripheral RAS, circulating angiotensins do exert a portion of their actions via stimulation of brain angiotensin receptors located in circumventricular organs. These circumventricular organs are located in the proximity of brain ventricles, are richly vascularized and possess a reduced blood-brain barrier thus permitting accessibility by peptides. In this way the brain RAS interacts with other neurotransmitter and neuromodulator systems and contributes to the regulation of blood pressure, body fluid homeostasis, cyclicity of reproductive hormones and sexual behavior, and perhaps plays a role in other functions such as memory acquisition and recall, sensory acuity including pain perception and exploratory behavior. An overactive brain RAS has been identified as one of the factors contributing to the pathogenesis and maintenance of hypertension in the spontaneously hypertensive rat (SHR) model of human essential hypertension. Oral treatment with angiotensin-converting enzyme inhibitors, which interfere with the formation of angiotensin II, prevents the development of hypertension in young SHR by acting, at least in part, upon the brain RAS. Delivery of converting enzyme inhibitors or specific angiotensin receptor antagonists into the brain significantly reduces blood pressure in adult SHR. Thus, if the SHR is an appropriate model of human essential hypertension (there is controversy concerning its usefulness), the potential contribution of the brain RAS to this dysfunction must be considered during the development of future antihypertensive compounds.

Discovery of a distinct binding site for angiotensin II (3-8), a putative angiotensin IV receptor

We report here the discovery of a unique and novel angiotensin binding site and peptide system based upon the C-terminal 3-8 hexapeptide fragment of angiotensin II (NH3(+)-Val-Tyr-Ile-His-Pro-Phe-COO-) (AII(3-8) (AIV)). This fragment binds saturably, reversibly, specifically, and with high affinity to membrane-binding sites in a variety of tissues and from many species. The binding site is pharmacologically distinct from the classic angiotensin receptors (AT1 or AT2) displaying low affinity for the known agonists (AII and AIII) and antagonist (Sar1,Ile8-AII). Although a definitive function has not been assigned to this system in many of the tissues in which it resides, AIV's interaction with endothelial cells may involve a role in endothelial cell-dependent vasodilation. Consequent to this action, AIV is a potent stimulator of renal cortical blood flow.

Identification of an AII(3-8) [AIV] binding site in guinea pig hippocampus

A unique angiotensin binding site specific for the hexapeptide, AII(3-8), has been identified in guinea pig hippocampus. This binding site, which is present in the pyramidal cell layer of CA1, CA2, CA3 of the hippocampus and dentate gyrus, binds AII(3-8) with high affinity (KD = 1.29 +/- 0.18 nM) in a saturable manner (Bmax = 449 +/- 62 fmol/mg protein). The N-terminal structure of the binding ligand is paramount in determining the binding affinity. The C-terminal requirements seem less stringent as evidenced by the binding affinity of AII(3-7) (KD = 20.9 +/- 2.1 nM). Neither AII, AIII,Sar1, Ile8-AII, Dup 753 nor CGP42112A appear to bind, indicating that this binding site is neither the AT1 nor AT2 sites described for AII/AIII. Autoradiographic analysis of hippocampus binding confirms the inability of Sar1,Ile8-AII to compete for [125I]AII(3-8) binding. Conversely AII(3-8) was unable to displace [125I]Sar1,Ile8-AII binding.

Roles of peripheral and central angiotensin-converting enzyme (ACE) in hypovolemic thirst induced by compound 48/80 in rats

Subcutaneous (s.c.) injection of Hoe 498, an angiotensin converting enzyme (ACE) inhibitor, at the doses of 0.1, 0.5, 1.0 and 4.0 mg/kg produced a dose-related inhibition of compound 48/80-induced hypovolemic thirst in rats. A significant time-response relationship was observed between the pretreatment time of Hoe 498 at a dose of 4.0 mg/kg and the inhibition of compound 48/80-induced water intake. Nearly 90% of plasma ACE activity was inhibited by Hoe 498 at all doses used, and this inhibition at the dose of 4.0 mg/kg of Hoe 498 continued for more than 4 hr. Intracerebroventricular (i.c.v.) or s.c. injection of Hoe 498 in doses ranging from 0.5 to 20 micrograms comparably inhibited plasma ACE activity in a dose-dependent manner. The compound 48/80-induced water intake was significantly reduced by i.c.v. injection of Hoe 498 (20 micrograms) 30 min after compound 48/80 administration, but not reduced when the drug was given 15 min prior to injection of dipsogen. The inhibition of water intake by Hoe 498 seems to be dependent on the dose and time between administration of Hoe 498 and compound 48/80. The present data suggest that brain ACE is more involved in compound 48/80-induced water intake than peripheral systemic ACE.

Pathways of angiotensin formation and function in the brain

New findings from this laboratory suggest that fragments of angiotensin derived from the amino (N-)terminus are biologically active end products of the renin-angiotensin system. In vitro and in vivo experiments revealed that the heptapeptide angiotensin-(1-7) [Ang-(1-7)] is a major endogenous product of the renin-angiotensin system cascade in the brains of rats and dogs. Additional studies with enzyme inhibitors showed that Ang-(1-7) is produced directly from angiotensin I by an enzyme other than the angiotensin converting enzyme. Immunocytochemical fibers within the hypothalamo-neurohypophyseal vasopressinergic system of the rat. Although Ang-(1-7) is as potent as angiotensin II (Ang II) in stimulating release of vasopressin from superperfused hypothalamo-neurohypophyseal explants, the heptapeptide has no dipsogenic or vasoconstrictor activity. In contrast, Ang-(1-7) mimics the effects of Ang II in augmenting the intrinsic discharge rate of neurons within the vagal-solitary complex and in causing monophasic depressor responses after microinjection into the medial region of the nucleus tractus solitarii. The evidence obtained in these experiments suggests novel mechanisms for the generation of angiotensin peptides in the brain. Additionally, the findings suggest that some of the biological actions ascribed to Ang II might be conveyed by the endogenous production of other angiotensin peptides that are generated by enzymatic pathways alternate to those described in the peripheral circulation.

Increased blood pressure induced by central application of aminopeptidase inhibitors is angiotensinergic-dependent in normotensive and hypertensive rat strains

Two aminopeptidase inhibitors, amastatin (AM) and bestatin (BE), were employed in 3 strains of rats, spontaneously hypertensive (SHR), Wistar-Kyoto (WKY), and Sprague-Dawley (SD), to investigate the central angiotensinergic system. The results indicate that intracerebroventricular (i.c.v.) injections of AM and BE induced pressor elevations in all 3 strains of rats. In order to test for the possibility of spillage into peripheral vasculature, members from all 3 strains were peripherally infused with AM, BE, or 0.15 NaCl via jugular vein catheters. The SHRs were significantly more responsive to the aminopeptidases than the normotensive strains, however their overall pressor responses were only 33% of those to i.c.v. infusion. Next, in order to test the notion that these aminopeptidase inhibitors are having their effect via the central angiotensinergic system, and not some other peptidergic system, the specific angiotensin receptor antagonist, Sar1, Thr8-AII (sarthran) was employed. Intracerebroventricular pretreatment with sarthran prevented subsequent pressor responses to i.c.v. AM and BE in members of all 3 strains, thereby suggesting that these aminopeptidase inhibitors are having their effect via the central angiotensinergic system.

Differential effects of aminopeptidase inhibitors on angiotensin-induced pressor responses

Recent iontophoretic data suggest that conversion of angiotensin II (AII) to angiotensin III (AIII) may be necessary before the peptide can activate central angiotensin-sensitive neurons. Furthermore, this conversion may be inhibited by the aminopeptidase A inhibitor, amastatin. In the present study we investigated the importance of aminopeptidase activity on central angiotensin-induced pressor responses. Intracerebroventricular (i.c.v.) pretreatment with amastatin, suppressed i.c.v. AII-induced pressor responses. Pretreatment with the aminopeptidase B inhibitor, bestatin, increased pressor responses to AIII. Pressor responses induced by the aminopeptidase-resistant analogue, [Sar1]angiotensin II, were not affected by pretreatment with angiotensin inhibitors. These results support the hypothesis that AII must be converted to AIII to be active in the brain.

Comparison of 125I-angiotensin III and 125I-angiotensin II binding to rat brain membranes

The binding of 125I-angiotensin III (125I-ANG III) to rat brain membranes was examined and compared with that of 125I-angiotensin II (125I-ANG II). Degradation of each ligand, as monitored by HPLC, was effectively inhibited using fragments of ANG III and ANG II known to have little affinity for angiotensin binding sites. Three classes of 125I-ANG III-binding sites were observed based on affinity (KD = 0.13, 1.83, and 10.16 nM) and capacity (Bmax = 1.30, 18.41, and 67.2 fmol/mg protein, respectively). Two classes of 125I-ANG II-binding sites of high affinity (KD = 0.11 and 1.76 nM) and low capacity (Bmax = 1.03 and 18.86 fmol/mg protein, respectively) were also identified. Cross-displacement studies confirmed that the two highest-affinity 125I-ANG III-binding sites and the 125I-ANG II-binding sites were the same. On the other hand, the binding of 125I-ANG III to the low-affinity 125I-ANG III-binding site could not be inhibited with ANG II. These data imply that previously measured differences in the biological potency of cerebroventricularly applied ANG III and ANG II probably do not result from differential binding of these peptides to central angiotensin receptors.

A hypothesis regarding the function of angiotensin peptides in the brain

Studies of the in vivo and in vitro metabolism of angiotensin peptide precursors, and of angiotensin II (Ang II) in tissues, has revealed the possibility that some of the fragments formed through specific enzymatic pathways are bioactive. There is evidence that Ang III is as potent as Ang II in stimulating thirst and causing aldosterone secretion. New findings from this laboratory have led us to reevaluate the concept that fragments of angiotensins derived from the amino (N-) terminus are devoid of biological activity. Using in vitro and in vivo techniques, we showed that Ang-(1-7) is processed from Ang I in amounts equal to or greater than Ang II. In addition, Ang-(1-7) generation is not dependent upon Ang I converting enzyme (ACE) activity in homogenates of canine brain stem. This heptapeptide promotes release of vasopressin from perifused hypothalamo-neurohypophysial explant and stimulates neural responses when microinjected into the vagal-solitary complex. The data supporting these findings are discussed below.

The effects of the aminopeptidase inhibitors amastatin and bestatin on angiotensin-evoked neuronal activity in rat brain

During a recent comparison of iontophoretically applied angiotensin II (AII) and angiotensin III (AIII) in the paraventricular nucleus of the rat, we observed that the response latency for AIII was much shorter than that for AII. This suggested that AII may have to be converted to AIII before it becomes active. To test this hypothesis we performed 3 experiments. (1) We examined the effects of bestatin, an aminopeptidase B inhibitor, on the activity of applied AII and AIII. (2) Next, we monitored the effects of amastatin, a specific aminopeptidase A inhibitor, on the action of co-applied AII or AIII. (3) And, finally, we examined the response to the aminopeptidase-resistant analog Sar1-AII, both applied alone and in combination with AII or AIII. Bestatin, while having no activity of its own, dramatically enhanced the actions of both AII and AIII. Amastatin, on the other hand, had little effect on AII's action and diminished or totally blocked AII-dependent activity. Like bestatin, amastatin had no effect alone. Sar1-AII reduced spontaneous activity of angiotensin-sensitive neurons and inhibited the actions of AII and AIII in a reversible manner. The same cells were also blocked by the recognized angiotensin antagonist Sar1, Ile8-AII. In total these results strongly support the notion that AII must be converted to AIII in the brain before it is activated.

Brain angiotensin II and III binding and dipsogenicity in the rabbit

The rabbit brain evidenced low or non-detectable levels of [125I]angiotensin II binding but considerable [125I]angiotensin III specific binding in agreement with distributions reported for the primate brain. The rabbit was dispsogenically responsive to the intracerebroventricular infusions of angiotensin II and III; however, no elevations in blood pressure were measured for either peptide. Thus, members of this species appear to have limited usefulness as a primate model for central angiotensin-induced cardiovascular changes.

Characterization of angiotensin binding in the African green monkey

The observation that there are differences in the characteristics and distribution of angiotensin receptors in the central nervous system of mammalian species led to the analysis of angiotensin binding in a primate model, the African Green monkey. Initial studies using [125I]angiotensin II ([125I]AII) as the radioligand showed binding in peripheral tissues but little binding in the central nervous system. Conversely, binding studies using [125I]AIII as the radioligand indicated more central nervous binding with diminished peripheral binding. Specific binding of [125I]AIII is evident throughout the brain with high binding in the circumventricular organs, striatum, caudate nucleus, olfactory bulb and localized areas of the thalamus and cerebral cortex. This binding was found to possess many of the properties commonly associated with binding to membrane-bound receptors. The specifically bound radioligand extracted from incubations of [125I]AIII and central nervous tissue appears to be a product of the metabolism of [125I]AIII rather than the peptide itself. Binding of [125I]AII does occur in peripheral tissues and to a limited extent in the cerebellum, but to a different receptor from that characterized using [125I]AIII. These results are similar to those seen in the gerbil and raise questions concerning the utilization of the rat as the primary model for studying the biochemistry of the brain-angiotensin system in humans.

Hypertension during chronic peripheral and central infusion of angiotensin III

Recent studies have suggested that the angiotensin II (ANG II) metabolite [Des-Asp]ANG II (ANG III) may be nearly equipotent with the parent compound in causing several acute neural responses known to be stimulated by angiotensin peptides (i.e., drinking, augmentation of sympathetic neurotransmission, and centrally mediated pressor responses). Because neural actions of ANG II are thought to contribute importantly to the ability of this hormone to cause chronic hypertension, the purpose of the present experiments was to explore the cardiovascular effects of chronic administration of ANG III either into the bloodstream or directly into the brain via the cerebral ventricles. The neurogenic component of the pressor response to acute infusion of ANG III also was reinvestigated. In anesthetized pithed rats (n = 6) ANG III had only 10% of the pressor potency of ANG II when given by acute (5-10 min) intravenous infusion. In conscious rats (n = 5) ANG III had 25% of the pressor potency of ANG II when tested using acute intravenous administration. The acute intravenous pressor potency ratio in conscious versus pithed rats was 4.8 for ANG III and 1.1 for ANG II, suggesting that, compared with ANG II, the pressor response to ANG III shows a greater dependence on neurogenic mechanisms at the doses tested. Chronic (5-day) intravenous infusion of ANG III (at 10, 20, and 100 ng/min) caused sustained hypertension without changes in fluid/electrolyte balance, but only at a dose (100 ng/min) estimated to produce blood levels of ANG III well beyond the "physiological" range.(ABSTRACT TRUNCATED AT 250 WORDS)

Factors affecting angiotensin II-induced hypothermia in rats

Systemic administration of angiotensin II (AII) to the rat has previously been shown to induce a dose-dependent, hypothermic response manifested by a fall in colonic temperature (CT), a decrease in heat production and an increase in tail skin temperature (TST). The factors mediating AII-induced hypothermia and their site of action were the subjects of the present investigation. To this end, intracerebroventricular administration of 1 microgram of AII induced a 0.4 degrees C reduction in CT and a 2.4 degrees C increase in TST. In contrast, SC administration of 200 micrograms angiotensin III/kg induced a slight increase in CT but had no affect on TST. Pretreatment with the AII-receptor antagonist, saralasin, at either 1 or 10 micrograms/kg, SC did not affect either the fall in CT or the increase in TST induced by administration of 200 micrograms AII/kg, SC. However, the administration of 100 micrograms saralasin/kg, SC attenuated both the fall in CT and the increase in TST induced by either 100 or 200 micrograms AII/kg. Since both the presynaptic alpha adrenoceptor agonist, clonidine, and the opioid antagonist, naloxone, modulate the pressor and dipsogenic responses to AII, their effects on AII-induced hypothermia were tested. Both clonidine (25 micrograms/kg, SC) and naloxone (1 mg/kg, IP) enhanced the fall in CT. Clonidine lengthened the duration of the increase in TST while naloxone had no effect. Pretreatment with the presynaptic adrenoceptor antagonist, yohimbine (300 micrograms/kg, SC), did not alter the hypothermic response to administration of AII. To determine whether vasodilation of the tail of the rat was mediated by AII-induced prostaglandin release, indomethacin (4 and 6 mg/kg) was administered.(ABSTRACT TRUNCATED AT 250 WORDS)

Characterization of angiotensin binding to gerbil brain membranes using [125I]angiotensin III as the radioligand

The observation that an Angiotensin II (AII)-sensitive species, the gerbil, exhibited little or no [125I]AII binding to brain membranes led to the hypothesis that AII's central action may be mediated by smaller and/or modified fragments of AII. This possibility was assessed, in part, by examining the ability of gerbil brain membranes to specifically bind [125I]desAsp1 AII (AIII), a heptapeptide fragment of AII. Specific binding was evident throughout the gerbil brain with highest binding in the septum (containing the subfornical organ), anterior ventral third ventricular region, hypothalamus (containing the median eminence), and striatum. This binding was found to possess many of the properties commonly associated with binding to membrane bound receptors. The binding within the circumventricular organs had characteristics that set them apart from the other central nervous tissues examined. Both the olfactory bulb and adrenal gland appeared to have two different angiotensin binding sites. It appears that the binding sites within the brain interact with a product of the metabolism of AIII or AII rather than the peptides themselves. The results suggest that [125I]AIII appears to be a better ligand than [125I]AII in the binding assay because it is more readily degraded to another substance.

Central angiotensin III-induced dipsogenicity in rats and gerbils

Previous findings from our laboratory demonstrated [125I]angiotensin II (AII) binding to plasma membranes from rat but not gerbil circumventricular organs (CVOs), the presumed location of brain receptors for angiotensin-induced dipsogenicity. Since members of both species drink to intracranially applied AII, a degradation product of AII was suspected to be the active ligand in gerbils. High specific [125I]angiotensin III (AIII) binding capacity was presently determined in CVOs taken from both rats and gerbils. Nearly identical dose-response curves were obtained for members of each species following the intracerebroventricular injection of AIII; however, rats drank more water than gerbils following the administration of AII. These results were interpreted to suggest that the dipsogenically active ligand in gerbils is AIII or derived from AIII, and that this analogue also contributes to angiotensin-induced drinking in rats. Since the distribution of specific angiotensin binding capacity represented by gerbil closely approximates that seen in non-human primate brain, these findings are of particular relevance and encourage future efforts directed toward understanding the role of AII metabolites in the central control of dipsogenicity.

Depressor activity of intracerebroventricularly administered pepstatin in young spontaneously hypertensive rats

The effect of prolonged intracerebroventricular (i.c.v.) infusion of N-acetyl-pepstatin in young and adult spontaneously hypertensive rats was studied. In young animals, pepstatin infusion resulted in a decrease in blood pressure and heart rate. Water intake and body weight were not affected. The depressor effect was accompanied by a slight increase in plasma renin activity and decreases in plasma vasopressin and plasma catecholamines. The blood pressure of adult rats with already established hypertension was not significantly affected. In addition, changes in plasma renin or catecholamines were not observed in these animals while vasopressin levels were slightly increased. The involvement of a possibly decreased sympathetic activity in the depressor effect of pepstatin is suggested. It is concluded that increased brain renin activity contributes to the development of hypertension of spontaneously hypertensive rats.

Minireview. Peptides and the blood-brain barrier

Most neuropeptides are known to occur both in the central nervous system and in blood. This, as well as the occurrence of central nervous peptide effects after peripheral administration, show the importance of studying the relationships between the peptides in the two compartments. For many peptides, such as the enkephalins, TRH, somatostatin and MIF-1, poor penetration of the blood-brain barrier was shown. In other cases, including beta-endorphin and angiotensin, peptides are rapidly degraded during or just after their entry into brain or cerebrospinal fluid. Some peptides, such as insulin, delta-sleep-inducing peptide, and the lipotropin-derived peptides, enter the cerebrospinal fluid to a slight or moderate extent in the intact form. Many peptide hormones, such as insulin, calcitonin and angiotensin, act directly on receptors in the circumventricular organs, where the blood-brain barrier is absent. Oxytocin, vasopressin, MSH, and an MSH-analog alter the properties of the blood-brain barrier, which may result in altered nutritient supply to the brain. In conclusion, the diffusion of most peptides across the brain vascular endothelium seems to be severely restricted. There are, however, several alternative routes for peripheral peptides to act on the central nervous system. The blood-brain barrier is a major obstacle for the development of pharmaceutically useful peptides, as in the case of synthetic enkephalin-analogs.

Proteolytic conversion of angiotensins in rat brain tissue

The proteolytic conversion of angiotensins in rab brain preparations was studied. Angiotensin I was converted into angiotensin II by enzymes which were associated with a synaptic membrane preparation, while angiotensin II was relatively resistant to proteolysis by these enzymes. Angiotensin II was rapidly metabolized at both pH 7.4 and pH 5.4 by enzymes in the soluble fraction of a synaptosomal preparation. One of the fragments formed at pH 7.4 was characterized as angiotensin III. At pH 5.4 only one fragment was generated which was characterized as angiotensin-(1-7)-heptapeptide. Enzymatically generated angiotensin II and III displayed pronounced biological activity in the brain, whereas angiotensin-(1-7)-heptapeptide was inactive. These data indicate a route for the generation, and the inactivation of biologically active angiotensins in the brain.

Binding of angiotensins to rat brain tissue: structure activity relationship

The binding of 3H-angiotensin II to a synaptosome-enriched fraction of the subcortical part of rat brain was studied. In this fraction specific high-affinity binding sites for angiotensin II were demonstrated. The binding sites were saturated at a ligand concentration of 2 X 10(-9) M. Scatchard analysis revealed a single class of binding sites with an apparent maximal binding capacity of 14 fmoles/mg of protein and an equilibrium dissociation constant, KD, of 0.9 X 10(-9) M. The specific binding at the KD concentration amounted to 59% of the total binding and was reversible. The association and dissociation rate constants (k1 and k-1) were 0.0212 nM-1 min-1 and 0.0196 min-1, respectively. Binding was dependent on both incubation time and tissue concentration in the incubation mixture. Angiotensins with biological activity in the brain, i.e., angiotensins I, II, III, and the fragments (3-8) and (4-8) competed with 3H-angiotensin II for the binding sites with IC50's of 9 X 10(-8) M, 2 X 10(-9) M, 4 X 10(-9) M, 4 X 10(-7) M and 4 X 10(-6), respectively. In the presence of 1 mM of the converting enzyme inhibitor SQ 14,225 the IC50 for angiotensin I was 2 X 10(-7) M. Competition by the biologically active fragment angiotensin (5-8) could not be demonstrated. The latter peptide, however, was highly metabolized during the incubation under the assay conditions used. The binding potency of the various angiotensins paralleled their dipsogenic and pressor potency. The present data indicate the possible physiological involvement of these binding sites as specific receptors in the actions of angiotensins in the brain.