key: cord-1042904-dkuf7bwm
authors: Wong, Marty K.S.
title: Other Angiotensins
date: 2015-09-04
journal: Handbook of Hormones
DOI: 10.1016/b978-0-12-801028-0.00178-1
sha: 471518c20b30cab46b3125b45412591dc2bbae49
doc_id: 1042904
cord_uid: dkuf7bwm

Besides the major role of angiotensin II (Ang II) in the renin-angiotensin system (RAS), other angiotensin peptides with different lengths were recently discovered to be biologically active and they possess individual receptors and signaling pathways. Ang III stimulates AT1 and AT2 receptors and its signaling pathway is similar to that of Ang II but has a specific role on aldosterone stimulation in adrenal cortex. The Ang(1–7)/Mas receptor axis is known to antagonize the effects of the AT1 axis. These include anti-hypertrophic action, anti-thrombotic and anti-fibrotic effect, and vasodilation via stimulation of NO synthesis in endothelium and potentiation of the bradykinin effect. Ang IV stimulates insulin-regulated aminopeptidase (IRAP) or AT4 receptor and is involved in facilitation of memory such as reversing memory deficits caused by alcohol abuse and ischemia. AT4 antagonist decreases renal blood flow and increases urinary sodium excretion, and these effects are independent of the AT1 pathway.

Marty K.S. Wong

Additional names/abbreviations: Angiotensin III or angiotensin (2À8) (Ang III, AIII, Ang(2À8)); angiotensin IV or angiotensin (3À8) (Ang IV, AIV, Ang(3À8)); angiotensin (1À7) (Ang(1À7)) Originally thought to be inactive metabolites of the reninangiotensin system, but these peptides were recently shown to possess different receptors and the functions are often antagonistic to those of Ang II. Drug targets for hypertension and Ang II-induced cardiovascular and renal diseases.

Originally thought to be biological inactive, these angiotensin peptide subtypes were found to have physiological roles and some possess specific receptors and signaling pathways [1] .

Ang III, Ang IV, and Ang(1À7) are linear peptides with no known secondary modification (Table 29C .1).

Ang III is produced by subsequent cleavage of Ang II by aminopeptidase A. Ang IV is produced by cleavage of Ang III by aminopeptidase N. Ang(1À7) is produced by various pathways involving ACE2 (See Chapter 29, Renin-Angiotensin System).

Gene and mRNA See Chapter 29B, Angiotensin II.

See Chapter 29B, Angiotensin II.

Ang III and Ang IV are short-lived peptides, and their concentrations in human plasma are kept at undetectable levels. Plasma Ang(1À7) baseline concentration in humans is 4.7 6 0.9 fmol/ml. In eels, plasma Ang III and Ang IV are present in plasma but their levels are low compared to Ang II (Table 29C. 2) [2] . In trout brain, Ang III is not detectable but Ang IV is present [3] .

The regulation of synthesis and release of Ang III and Ang IV is not clear. Ang(1À7) synthesis and release are regulated by the activity of ACE2 (see Chapter 29, Renin-Angiotensin System).

Ang III binds to AT1 and AT2. Ang IV binds to the angiotensin type-4 receptor (AT4), also known as insulin-regulated aminopeptidase (IRAP). Ang(1À7) binds to the Mas receptor (Mas1).

Ang III stimulates AT1 and AT2 receptors and its signaling pathway is similar to that of Ang II. Ang III has preferential binding on the AT2 receptor. The Mas receptor is activated by Ang(1À7) but the intracellular signaling pathway is not well understood. The receptor function is usually associated with Ang II-dependent effects and is known to counter the AT1dependent signaling. Ang(1À7)/Mas activation inhibits the AT1-dependent activation of MAPK kinase in the epithelial cells of proximal tubules. In cardiovascular epithelium of mammals, Mas receptor activation stimulates phosphorylation of AKT and increases endothelial NO synthesis, leading to vasorelaxation that counters the vasoconstriction effects of Ang II. A combination of angiotensin signaling has been recently noticed, which states that the physiological effect depends not only on a single pathway, but is a result of a specific ratio among various angiotensins, acting through their own receptor pathways. Renal mesangial cell proliferation was stimulated by Ang II and Ang(1À7) independently via AT1 and Mas receptors respectively [4] . However, a combination of stimulatory concentration of Ang II and Ang(1À7) counters the stimulation, indicating the complex interaction within RAS signaling. AT4/IRAP activates intracellular signals including an increase in intracellular Ca concentration, modulation of MAPK kinases, activation of NF-κB signaling, and production of cGMP. However, the effects are largely dependent on the cell types and, in some cases, no classical signaling could be demonstrated despite the presence of AT4 binding sites.

Agonist AVE 0991 is a non-peptide Ang(1À7) agonist and it stimulates the Mas receptor to produce cardiovascular protective effects to counter the pathophysiological effects of AT1 [5] .

[Nle 1 ]-angiotensin IV has been suggested as a specific Ang IV agonist that constitutively activates AT4/IRAP.

A779 is a non-peptide Ang(1À7) agonist and it inhibits the signaling of Mas receptors and attenuates the cardiovascular effects of Ang(1À7) [6] .

Ang III has preferential stimulation to release aldosterone in adrenal cortex, which is partially via AT2 but not AT1 [7] . Intra-arterial injection of Ang III or Ang IV increases blood pressure in teleosts but Ang III has a higher potency than Ang IV. Intracerebroventricular (ICV) injection of Ang III increases the heart rate without affecting the blood pressure and ventilation rate in trout, in contrast to the effect of Ang II, which increases all three parameters [3] . ICV injection of Ang IV does not affect blood pressure, heart rate, and ventilation rate even though it is detected in the brain by immunoassays. This suggested that a specific receptor for Ang III (and Ang II) could be present to elicit the preferential effect of heart rate control in trout [8] . The Mas receptor expresses in brain, testis, ovary, and endothelial cells of blood vessels. Besides AT2, the Ang(1À7)/Mas receptor axis is also known to antagonize the effects of the AT1 axis. These antagonistic effects include anti-hypertrophic action, anti-thrombotic and anti-fibrotic effects, and vasodilation via stimulation of NO synthesis in endothelium and potentiation of the bradykinin effect. The localization and physiological effects of the Mas receptor are not clear in non-mammalian vertebrates. AT4/IRAP is broadly distributed in kidney, aorta, heart, liver, lung, uterus, adrenal gland, and brain, especially in neurons associated with memory function [9] . The Ang IV/AT4 axis is involved in facilitation of memory and can reverse memory deficits caused by alcohol abuse and ischemia. AT4 antagonist decreases renal blood flow and increases urinary sodium excretion, and these effects are independent of the AT1 pathway. The large variation in signaling and function of AT4 poses difficulties for researchers. Ang IV was detected in considerable amounts in the brain of trout, indicating a possible role of memory function as in the case of mammals. There is so far no information on AT4/IRAP in non-mammalian vertebrates.

ACE-deleted human patients exhibit hypertension and this is related to a low plasma Ang(1À7) concentration. Baroreflex bradycardia was lowered but vascular responsiveness to Ang II was enhanced in Mas-knockout mice. Mas-knockout also impaired post-ischemic neovascularization and endothelial NO formation.

Ang(1À7) reduces mechanical stretch-induced cardiac hypertrophy through downregulation of AT1. ACE2 was found to function as a receptor for the coronavirus that caused the infamous severe acute respiratory syndrome (SARS) in 2002À2003. The SARS virus attaches to ACE2 and diminishes the expression and thus the production of Ang(1À7), leading to an intensified activation of AT1. Injection of recombinant ACE2 into mice protected the lung from sepsis and thus ACE can be a target treatment in lung injury associated with SARS.

A low Ang(1À7) is associated with hypertension and cardiac hypertrophy. Agonists for the Mas receptor have been targets to control cardiovascular diseases caused by hyperactive AT1. AngIV/AT4 is involved in memory and is a treatment target of Alzheimer's and Parkinson's diseases. 

Renin-angiotensin system revisited

Changes in plasma angiotensin subtypes in Japanese eel acclimated to various salinities from deionized water to double-strength seawater

Central ventilatory and cardiovascular actions of angiotensin peptides in trout

Counteraction between angiotensin II and angiotensin-(1À7) via activating angiotensin type I and Mas receptor on rat renal mesangial cells

Pharmacological effects of AVE 0991, a nonpeptide angiotensin-(1À7) receptor agonist

Complete blockade of the vasorelaxant effects of angiotensin-(1-7) and bradykinin in murine microvessels by antagonists of the receptor Mas

Angiotensin III stimulates aldosterone secretion from adrenal gland partially via angiotensin II type 2 receptor but not angiotensin II type 1 receptor

Central and peripheral cardiovascular effects of angiotensin III in trout

The angiotensin IV/AT4 receptor

Gene, mRNA, and domain structure of the human Mas-1 receptor. Human Mas-1 oncogene: Mas1, location 6q25.3Àq26

The unrooted phylogenetic tree of the Mas-1 oncogene receptors (Mas1) was constructed with the maximum likelihood method using full-length sequences from representative vertebrate species. The Mas receptor is specific to Ang(1À7) in mammals but specificity has not been demonstrated in non-mammalian species. The numbers on the branches indicate the bootstrap values from 1,000 replicates

3 Gene, mRNA, and domain structure of the human AT4 receptor/IRAP. Human IRAP: lnpep, location 5q15

Phylogenetic tree of the angiotensin type-4 receptors in vertebrates. The phylogenetic tree of the angiotensin type-4 receptors (AT4/IRAP) was constructed with the maximum likelihood method using full-length sequences from representative vertebrate species