Angiotensin, a peptide hormone, causes blood vessels to constrict, and drives blood pressure up. It is part of the renin-angiotensin system, which is a major target for drugs that lower blood pressure. Angiotensin also stimulates the release of aldosterone, another hormone, from the adrenal cortex. Aldosterone promotes sodium retention in the distal nephron, in the kidney, which also drives blood pressure up.
Angiotensin-(1-7) is an endogenous ligand for the G protein-coupled receptor Mas.
Santos RA, et al. Proc Natl Acad Sci U S A. 2003
Jun 26 [Epub ahead of print]
Angiotensin-(1-7) is an endogenous ligand for the G protein-coupled receptor Mas.
The renin-angiotensin system plays a critical role in blood pressure control
and body fluid and electrolyte homeostasis. Besides angiotensin (Ang) II, other
Ang peptides, such as Ang III [Ang-(2-8)], Ang IV [Ang-(3-8)], and Ang-(1-7)
may also have important biological activities. Ang-(1-7) has become an
angiotensin of interest in the past few years, because its cardiovascular and
baroreflex actions counteract those of Ang II. Unique angiotensin-binding sites
specific for this heptapeptide and studies with a selective Ang-(1-7)
antagonist indicated the existence of a distinct Ang-(1-7) receptor. We
demonstrate that genetic deletion of the G protein-coupled receptor encoded by
the Mas protooncogene abolishes the binding of Ang-(1-7) to mouse kidneys.
Accordingly, Mas-deficient mice completely lack the antidiuretic action of
Ang-(1-7) after an acute water load. Ang-(1-7) binds to Mas-transfected cells
and elicits arachidonic acid release. Furthermore, Mas-deficient aortas lose
their Ang-(1-7)-induced relaxation response. Collectively, these findings
identify Mas as a functional receptor for Ang-(1-7) and provide a clear
molecular basis for the physiological actions of this biologically active
peptide.
Santos RA, et al. Proc Natl Acad Sci U S A. 2003
Jun 26 [Epub ahead of print]
Characterization of a new selective antagonist for angiotensin-(1-7),
D-pro7-angiotensin-(1-7)
Characterization of a new selective antagonist for angiotensin-(1-7),
D-pro7-angiotensin-(1-7)
Angiotensin-(1-7) [Ang-(1-7)] has biological actions that can often be
distinguished from those of angiotensin II (Ang II). Recent studies indicate
that the effects of Ang-(1-7) are mediated by specific receptor(s). We now
report the partial characterization of a new antagonist selective for
Ang-(1-7), D-Pro7-Ang-(1-7). D-Pro7-Ang-(1-7) (50 pmol) inhibited the
hypertensive effect induced by microinjection of Ang-(1-7) [41 vs 212 mm Hg, 25
pmol Ang-(1-7) alone] into the rostral ventrolateral medulla without changing
the effect of Ang II (162.5 vs 192.5 mm Hg after 25 pmol Ang II alone). At
10(-7) mol/L concentration, it completely blocked the endothelium-dependent
vasorelaxation produced by Ang-(1-7) (10(-10) to 10(-6) mol/L) in the mouse
aorta. The antidiuresis produced by Ang-(1-7) (40 pmol/100 g body weight) in
water-loaded rats was also blocked by its analog [1 microg/100 g body weight;
3.080.8 vs 1.270.33 mL in Ang-(1-7)-treated rats]. D-Pro7-Ang-(1-7) at a molar
ratio of 40:1 did not change the hypotensive effect of bradykinin. Moreover,
D-Pro7-Ang-(1-7) did not affect the dipsogenic effect produced by
intracerebroventricular administration of Ang II (11.41.15 vs 8.81.2 mL/h after
Ang II) and did not show any demonstrable angiotensin-converting enzyme
inhibitory activity in assays with the synthetic substrate Hip-His-Leu and rat
plasma as a source of enzyme. Autoradiography studies with 125I-Ang-(1-7) in
mouse kidney slices showed that D-Pro7-Ang-(1-7) competed for the binding of
Ang-(1-7) to the cortical supramedullary region. In Chinese hamster ovary cells
stably transfected with the AT1 receptor subtype, D-Pro7-Ang-(1-7) did not compete
for the specific binding of 125I-Ang-II in concentrations up to 10(-6) mol/L.
There was also no significant displacement of Ang II binding to angiotensin
type 2 receptors in membrane preparations of adrenal medulla. These data
indicate that D-Pro7-Ang-(1-7) is a selective antagonist for Ang-(1-7), which
can be useful to clarify the functional role of this heptapeptide.
Angiotensin IV in the central nervous system
Von Bohlen Und Halbach O. Cell Tissue Res
2003 Jan;311(1):1-9
Angiotensin IV in the central nervous system
The mammalian brain harbors a renin-angiotensin system (RAS), which is
independent from the peripheral RAS. Angiotensin II is a well-studied member of
the RAS and exerts most of the known angiotensin-mediated effects on fluid and
electrolyte homeostasis, autonomic activity, neuroendocrine regulation, and
behavior. This review summarizes a mass of compelling new evidence for the
biological role of an active (3-8) fragment of angiotensin II, named
angiotensin IV. Angiotensin IV binds to a widely distributed binding site in
the brain, but which is different from the known angiotensin II receptors AT1
and AT2. Angiotensin IV has been implicated in a number of physiological
actions, including the regulation of blood flow, the modulation of exploratory
behavior, and processes attributed to learning and memory. Furthermore,
angiotensin IV may also be involved in neuronal development. Collectively, the
available evidence suggests that angiotensin IV is a potent neuropeptide,
involved in a broad range of brain functions.
Von Bohlen Und Halbach O. Cell Tissue Res
2003 Jan;311(1):1-9
Isolation and identification of
proangiotensin-12, a possible component of the renin-angiotensin system
Nagata
S., et al. BBR C 350 (2006) 1026-1031
Isolation and identification of
proangiotensin-12, a possible component of the renin-angiotensin system
The renin-angiotensin (RA) system plays an important role in regulating
blood pressure and fluid balance. In the search for bioactive peptides with an
antibody binding to the N-terminal portion of angiotensin II (Ang II), we
isolated a new angiotensinogen-derived peptide from the rat small intestine.
Consisting of 12 amino acids, this peptide was termed proangiotensin-12 based
on its possible role of an Ang II precursor. Proangiotensin-12 constricted
aortic strips and, when infused intravenously, raised blood pressure in rats,
while both the vasoconstrictor and pressor response to proangiotensin-12 were
abolished by captopril and by CV-11974, an Ang II type I receptor blocker.
Proangiotensin-12 is abundant in a wide range of organs and tissues including
the small intestine, spleen, kidneys, and liver of rats. The identification of
proangiotensin-12 suggests a processing cascade of the RA system, different
from the cleavage of angiotensinogen to Ang I by renin.
Vasoconstrictor effects of Ang I, Ang II, and proangiotensin-12
on perfused rat aorta ex vivo. Captopril and CV-11974, an AT1 receptor
antagonist, were used at 10-7 and 10-8 mol/L,
respectively. The results are shown as means ±SE of % of maximum contraction
induced by 60 mmol/L KCl for six to seven samples. *P < 0.05 vs
proangiotensin-12 alone.
(A) Representative blood pressure recording following the
intravenous injection of a 200 pmol/kg bolus of proangiotensin-12 in
anesthetized rats, (B) dose-dependent pressor effects, and (C) attenuation of
the effects of proangiotensin-12 by captopril or CV-11974, an AT1 receptor
blocker. DMBP indicates the maximum rise of mean blood pressure from the
baseline. Either captopril or CV-11974 was intravenously injected at the
indicated dose 2 min before the injection of proangiotensin-12. The results
are shown as means ?SE for five rats examined. *P < 0.05 vs
proangiotensin-12 alone.
Nagata
S., et al. BBR C 350 (2006) 1026-1031
Angiotensin II-induced cardiomyocyte hypertrophy in vitro is TAK1-dependent and Smad2/3-independent
Angiotensin II-induced cardiomyocyte hypertrophy in vitro is TAK1-dependent and Smad2/3-independent
Cardiac hypertrophy occurs as an adaptation to hypertension but a sustained hypertrophic response can ultimately lead to heart failure. Angiotensin-II (Ang II) is released following hemodynamic overload and stimulates a cardiac hypertrophic response. AngII also increases expression of the regulatory cytokine, transforming growth factor-β1 (TGFβ1), which is also implicated in the cardiac hypertrophic response and can stimulate activation of Smad2/3 as well as TGFβ-activated kinase 1 (TAK1) signaling mediators. To better understand the downstream signaling events in cardiac hypertrophy, we therefore investigated activation of Smad2/3 and TAK1 signaling pathways in response to Ang II and TGFβ1 using primary neonatal rat cardiomyocytes to model cardiac hypertrophic responses. Small interfering RNA (siRNA) knockdown of Smad 2/3 or TAK1 protein or addition of the TGFβ type I receptor inhibitor, SB431542, were used to investigate the role of downstream mediators of TGFβ signaling in the hypertrophic response. Our data revealed that TGFβ1 stimulation leads to cardiomyocyte hypertrophic phenotypes that were indistinguishable from those occurring in response to Ang II. In addition, inhibition of the TGFβ1 type receptor abolished Ang II-induced hypertrophic changes. Furthermore, the hypertrophic response was also prevented following siRNA knockdown of TAK1 protein, but was unaffected by knockdown of Smad2/3 proteins. We conclude that Ang II-induced cardiomyocyte hypertrophy in vitro occurs in a TAK1-dependent, but Smad-independent, manner.
Identification and characterization of a functional mitochondrial angiotensin system
The renin-angiotensin (Ang) system regulates multiple physiological functions through Ang II type 1 and type 2 receptors. Prior studies suggest an intracellular pool of Ang II that may be released in an autocrine manner upon stretch to activate surface membrane Ang receptors. Alternatively, an intracellular renin-Ang system has been proposed, with a primary focus on nuclear Ang receptors. A mitochondrial Ang system has not been previously described. Here we report that functional Ang II type 2 receptors are present on mitochondrial inner membranes and are colocalized with endogenous Ang. We demonstrate that activation of the mitochondrial Ang system is coupled to mitochondrial nitric oxide production and can modulate respiration. In addition, we present evidence of age-related changes in mitochondrial Ang receptor expression, i.e., increased mitochondrial Ang II type 1 receptor and decreased type 2 receptor density that is reversed by chronic treatment with the Ang II type 1 receptor blocker losartan. The presence of a functional Ang system in human mitochondria provides a foundation for understanding the interaction between mitochondria and chronic disease states and reveals potential therapeutic targets for optimizing mitochondrial function and decreasing chronic disease burden with aging.
Angiotensin II sustains brain inflammation in mice via TGF-β
The renin-angiotensin-aldosterone system (RAAS) is a key hormonal system regulating blood pressure. However, expression of RAAS components has recently been detected in immune cells, and the RAAS has been implicated in several mouse models of autoimmune disease. Here, we have identified Ang II as a paracrine mediator, sustaining inflammation in the CNS in the EAE mouse model of MS via TGF-β. Ang II type 1 receptors (AT1Rs) were found to be primarily expressed in CNS-resident cells during EAE. In vitro, astrocytes and microglia responded to Ang II treatment by inducing TGF-β expression via a pathway involving the TGF-β–activating protease thrombospondin-1 (TSP-1). TGF-β upregulation in astrocytes and microglia during EAE was blocked with candesartan (CA), an inhibitor of AT1R. Treatment of EAE with CA ameliorated paralysis and blunted lymphocyte infiltration into the CNS, outcomes that were also seen with genetic ablation of AT1Ra and treatment with an inhibitor of TSP-1. These data suggest that AT1R antagonists, frequently prescribed as antihypertensives, may be useful to interrupt this proinflammatory, CNS-specific pathway in individuals with MS.
Cyclophilin A enhances vascular oxidative stress and the development of angiotensin II¨Cinduced aortic aneurysms
Inflammation and oxidative stress are pathogenic mediators of many diseases, but molecules that could be therapeutic targets remain elusive. Inflammation and matrix degradation in the vasculature are crucial for abdominal aortic aneurysm (AAA) formation. Cyclophilin A (CypA, encoded by Ppia) is highly expressed in vascular smooth muscle cells (VSMCs), is secreted in response to reactive oxygen species (ROS) and promotes inflammation. Using the angiotensin II (AngII)-induced AAA model in Apoe-/- mice, we show that Apoe-/-Ppia-/- mice are completely protected from AngII¨Cinduced AAA formation, in contrast to Apoe-/-Ppia+/+ mice. Apoe-/-Ppia-/- mice show decreased inflammatory cytokine expression, elastic lamina degradation and aortic expansion. These features were not altered by reconstitution of bone marrow cells from Ppia+/+ mice. Mechanistic studies showed that VSMC-derived intracellular and extracellular CypA are required for ROS generation and matrix metalloproteinase-2 activation. These data define a previously undescribed role for CypA in AAA formation and suggest CypA as a new target for treating cardiovascular disease.
Angiotensin II-mediated adaptive and maladaptive remodeling of cardiomyocyte excitation-contraction coupling.
Cardiac hypertrophy is associated with alterations in cardiomyocyte excitation-contraction coupling (ECC) and Ca(2+) handling. Chronic elevation of plasma angiotensin II (Ang II) is a major determinant in the pathogenesis of cardiac hypertrophy and congestive heart failure. However, the molecular mechanisms by which the direct actions of Ang II on cardiomyocytes contribute to ECC remodeling are not precisely known. This question was addressed using cardiac myocytes isolated from transgenic (TG1306/1R [TG]) mice exhibiting cardiac specific overexpression of angiotensinogen, which develop Ang II-mediated cardiac hypertrophy in the absence of hemodynamic overload. Electrophysiological techniques, photolysis of caged Ca(2+) and confocal Ca(2+) imaging were used to examine ECC remodeling at early ( approximately 20 weeks of age) and late ( approximately 60 weeks of age) time points during the development of cardiac dysfunction. In young TG mice, increased cardiac Ang II levels induced a hypertrophic response in cardiomyocyte, which was accompanied by an adaptive change of Ca(2+) signaling, specifically an upregulation of the Na(+)/Ca(2+) exchanger-mediated Ca(2+) transport. In contrast, maladaptation was evident in older TG mice, as suggested by reduced sarcoplasmic reticulum Ca(2+) content resulting from a shift in the ratio of plasmalemmal Ca(2+) removal and sarcoplasmic reticulum Ca(2+) uptake. This was associated with a conserved ECC gain, consistent with a state of hypersensitivity in Ca(2+)-induced Ca(2+) release. Together, our data suggest that chronic elevation of cardiac Ang II levels significantly alters cardiomyocyte ECC in the long term, and thereby contractility, independently of hemodynamic overload and arterial hypertension.
Mass-Spectrometric Identification of a Novel Angiotensin Peptide in Human Plasma
Jankowski V, et al. Arterioscler Thromb Vasc Biol. 2006
Nov 30; [Epub ahead of print]
Mass-Spectrometric Identification of a Novel Angiotensin Peptide in Human Plasma
OBJECTIVE: Angiotensin peptides play a central role in cardiovascular
physiology and pathology. Among these peptides, angiotensin II (Ang II) has
been investigated most intensively. However, further angiotensin peptides
such as Ang 1-7, Ang III, and Ang IV also contribute to vascular regulation,
and may elicit additional, different, or even opposite effects to Ang II.
Here, we describe a novel Ang II-related, strong vasoconstrictive substance
in plasma from healthy humans and end-stage renal failure patients. METHODS
AND RESULTS: Chromatographic purification and structural analysis by
matrix-assisted laser desorption/ionisation time-of-flight/time-of-flight
(MALDI-TOF/TOF) revealed an angiotensin octapeptide with the sequence
Ala-Arg-Val-Tyr-Ile-His-Pro-Phe, which differs from Ang II in Ala(1) instead
of Asp(1). Des[Asp(1)]-[Ala(1)]-Ang II, in the following named Angiotensin A
(Ang A), is most likely generated enzymatically. In the presence of mononuclear
leukocytes, Ang II is converted to Ang A by decarboxylation of Asp(1). Ang A
has the same affinity to the AT1 receptor as Ang II, but a higher affinity to
the AT2 receptor. In the isolated perfused rat kidney, Ang A revealed a
smaller vasoconstrictive effect than Ang II, which was not modified in the
presence of the AT2 receptor antagonist PD 123319, suggesting a lower
intrinsic activity at the AT1 receptor. Ang II and Ang A concentrations in
plasma of healthy subjects and end-stage renal failure patients were
determined by matrix-assisted laser desorption/ionisation mass-analysis,
because conventional enzyme immunoassay for Ang II quantification did not
distinguish between Ang II and Ang A. In healthy subjects, Ang A
concentrations were less than 20% of the Ang II concentrations, but the ratio
Ang A / Ang II was higher in end-stage renal failure patients. CONCLUSIONS:
Ang A is a novel human strong vasoconstrictive angiotensin-derived peptide,
most likely generated by enzymatic transformation through mononuclear
leukocyte-derived aspartate decarboxylase. Plasma Ang A concentration is
increased in end-stage renal failure. Because of its stronger agonism at the
AT2 receptor, Ang A may modulate the harmful effects of Ang II.
Jankowski V, et al. Arterioscler Thromb Vasc Biol. 2006
Nov 30; [Epub ahead of print]
Chronic production of angiotensin IV in
the brain leads to hypertension that is reversible with an angiotensin II AT1
receptor antagonist
Circ
Res. 2004 Jun 11;94(11):1451-7. Epub 2004 Apr 29
Chronic production of angiotensin IV in
the brain leads to hypertension that is reversible with an angiotensin II AT1
receptor antagonist
Angiotensin IV (Ang IV) is a metabolite of the potent vasoconstrictor
angiotensin II (Ang II). Because specific binding sites for this peptide have
been reported in numerous tissues including the brain, it has been suggested
that a specific Ang IV receptor (AT4) might exist. Bolus injection of Ang IV in
brain ventricles has been implicated in learning, memory, and localized
vasodilatation. However, the functions of Ang IV in a physiological context are
still unknown. In this study, we generated a transgenic (TG) mouse model that
chronically releases Ang IV peptide specifically in the brain. TG mice were
found to be hypertensive by the tail-cuff method as compared with control
littermates. Treatment with the angiotensin-converting enzyme inhibitor
captopril had no effect on blood pressure, but surprisingly treatment with the
Ang II AT1 receptor antagonist candesartan normalized the blood pressure
despite the fact that the levels of Ang IV in the brains of TG mice were only
4-fold elevated over the normal endogenous level of Ang peptides. Calcium
mobilization assays performed on cultured CHO cells chronically transfected
with the AT1 receptor confirm that low-dose Ang IV can mobilize calcium via the
AT1 receptor only in the presence of Ang II, consistent with an allosteric
mechanism. These results suggest that chronic elevation of Ang IV in the brain
can induce hypertension that can be treated with angiotensin II AT1 receptor
antagonists.
Circ
Res. 2004 Jun 11;94(11):1451-7. Epub 2004 Apr 29
Angiotensin-(1-7) inhibits the
angiotensin II-enhanced norepinephrine release in coarcted hypertensive rats
Gironacci MM, et al. Regul Pept. 2004 Apr 15;118(1-2):45-9
Angiotensin-(1-7) inhibits the
angiotensin II-enhanced norepinephrine release in coarcted hypertensive rats
Since it has been suggested that angiotensin (Ang) (1-7) functions as an
antihypertensive peptide, we studied its effect on the Ang II-enhanced
norepinephrine (NE) release evoked by K+ in hypothalami isolated from aortic
coarcted hypertensive (CH) rats. The endogenous NE stores were labeled by
incubation of the tissues with 3H-NE during 30 min, and after 90 min of washing,
they were incubated in Krebs solution containing 25 mM KCl in the absence or
presence of the peptides. Ang-(1-7) not only diminished the K+-evoked NE
release from hypothalami of CH rats, but also blocked the Ang II-enhanced NE
release induced by K+. Ang-(1-7) blocking action on the Ang II response was
prevented by [D-Ala7]Ang-(1-7), an Ang-(1-7) specific antagonist, by PD 123319,
an AT2-receptor antagonist, and by Hoe 140, a B2 receptor antagonist. Ang-(1-7)
inhibitory effect on the Ang II facilitatory effect on K+-stimulated NE release
disappeared in the presence of Nomega-nitro-L-arginine methylester and was
restored by L-arginine. Our present results suggest that Ang-(1-7) may
contribute to blood pressure regulation by blocking Ang II actions on NE
release at the central level. This inhibitory effect is a nitric oxide-mediated
mechanism involving AT2 receptors and/or Ang-(1-7) specific receptors and local
bradykinin generation.
Gironacci MM, et al. Regul Pept. 2004 Apr 15;118(1-2):45-9
Effect of I.C.V. injection of AT4 receptor ligands,
NLE1-angiotensin IV and LVV-hemorphin 7, on spatial learning in rats
Lee J, et al. Neuroscience. 2004;124(2):341-9
Effect of I.C.V. injection of AT4 receptor ligands,
NLE1-angiotensin IV and LVV-hemorphin 7, on spatial learning in rats
Central administration of angiotensin IV (Ang IV) or its analogues enhance
performance of rats in passive avoidance and spatial memory paradigms. The
purpose of this study was to examine the effect of a single bolus injection of
two distinct AT4 ligands, Nle1-Ang IV or LVV-haemorphin-7, on spatial learning
in the Barnes circular maze. Mean number of days for rats treated with either
Nle1-Ang IV or LVV-haemorphin-7 to achieve learner criterion is significantly
reduced compared with controls (P < 0.001 and P < 0.05 respectively).
This is due to enhanced ability of the peptide-treated rats to adopt a spatial
strategy for finding the escape hatch. In all three measures of learning
performance, (1) the number of errors made, (2) the distance travelled and (3)
the latency in finding the escape hatch, rats treated with either 100 pmol or 1
nmol of Nle1-Ang IV or 100 pmol LVV-haemorphin-7 performed significantly better
than the control groups. As early as the first day of testing, the rats treated
with the lower dose of Nle1-Ang IV or LVV-haemorphin-7 made fewer errors (P
< 0.01 and P< 0.05 respectively) and travelled shorter distances (P <
0.05 for both groups) than the control animals. The enhanced spatial learning
induced by Nle1-Ang IV (100 pmol) was attenuated by the co-administration of
the AT4 receptor antagonist, divalinal-Ang IV (10 nmol). Thus, administration
of AT4 ligands results in an immediate potentiation of learning, which may be
associated with facilitation of synaptic transmission and/or enhancement of
acetylcholine release.
Lee J, et al. Neuroscience. 2004;124(2):341-9
AT(4) receptor is insulin-regulated membrane aminopeptidase: potential
mechanisms of memory enhancement
Albiston AL, et al. Trends Endocrinol Metab 2003 Mar;14(2):72-7
AT(4) receptor is insulin-regulated membrane aminopeptidase: potential
mechanisms of memory enhancement
Although angiotensin IV (Ang IV) was thought initially to be an inactive
product of Ang II degradation, it was subsequently shown that the hexapeptide
markedly enhances learning and memory in normal rodents and reverses the memory
deficits seen in animal models of amnesia. These central nervous system effects
of Ang IV are mediated by binding to a specific site, known as the AT(4)
receptor, which is found in appreciable levels throughout the brain and is
concentrated particularly in regions involved in cognition. This field of
research was redefined by the identification of the AT(4) receptor as the
transmembrane enzyme, insulin-regulated membrane aminopeptidase (IRAP). Here,
we explore the potential mechanisms by which Ang IV binding to IRAP leads to
the facilitation of learning and memory.
Albiston AL, et al. Trends Endocrinol Metab 2003 Mar;14(2):72-7
Neuropeptide conversion to bioactive fragments - an important pathway in
neuromodulation
Hallberg M, Nyberg F. Curr Protein Pept Sci 2003
Feb;4(1):31-44
Neuropeptide conversion to bioactive fragments - an important pathway in
neuromodulation
processes for their inactivation include several enzymatic steps. In addition
to enzymatic processing and degradation, several neuropeptides have been shown
to undergo enzymatic conversion to fragments with retained or modified
biological activity. This has most clearly been demonstrated for e.g. opioid
peptides, tachykinins, calcitonin gene-related peptide (CGRP) as well as for
peptides belonging to the renin-angiotensin system. Sometimes the released
fragment shares the activity of the parent compound. However, in many cases the
conversion reaction is linked to a change in the receptor activation profile,
i.e. the generated fragment acts on and stimulates a receptor not recognized by
the parent peptide. This review will describe the characteristics of certain
neuropeptide fragments having the ability to modify the biological action of
the peptide from which they are derived. Focus will be directed to the
tachykinins, the opioid peptides, angiotensins as well as to CGRP, bradykinin
and nociceptin. The kappa opioid receptor selective opioid peptide, dynorphin,
recognized for its ability to produce dysphoria, is converted to the delta
opioid receptor agonist Leu-enkephalin, with euphoric properties. The
tachykinins, typified by substance P (SP), is converted to the bioactive
fragment SP(1-7), a heptapeptide mimicking some but opposing other effects of
the parent peptide. The bioactive angiotensin II, known to bind to and
stimulate the AT-1 and AT-2 receptors, is converted to angiotensin IV (i.e.
angiotensin 3-8) with preference for the AT-4 sites or to angiotensin (1-7),
not recognized by any of these receptors. Both angiotensin IV and angiotensin
(1-7) are biologically active. For example angiotensin (1-7) retains some of
the actions ascribed for angiotensin II but is shown to counteract others. Thus,
it is obvious that the activity of many neuroactive peptides is modulated by
bioactive fragments, which are formed by the action of a variety of peptidases.
This phenomenon appears to represent an important regulatory mechanism that
modulates many neuropeptide systems but is generally not acknowledged.
Hallberg M, Nyberg F. Curr Protein Pept Sci 2003
Feb;4(1):31-44
Cellular targets for angiotensin II fragments: pharmacological and molecular evidence
Cellular targets for angiotensin II fragments: pharmacological and molecular evidence
Although angiotensin II has long been considered to represent the end product
of the renin-angiotensin system (RAS), there is accumulating evidence that it
encompasses additional effector peptides with diverse functions. In this
respect, angiotensin IV (Ang IV) formed by deletion of the two N terminal amino
acids, has sparked great interest because of its wide range of physiological
effects. Among those, its facilitatory role in memory acquisition and retrieval
is of special therapeutic relevance. High affinity binding sites for this
peptide have been denoted as AT(4)- receptors and, very recently, they have
been proposed to correspond to the membrane-associated OTase/ IRAP
aminopeptidase. This offers new opportunities for examining physiological roles
of Ang IV in the fields of cognition, cardiovascular and renal metabolism and
pathophysiological conditions like diabetes and hypertension. Still new
recognition sites may be unveiled for this and other angiotensin fragments.
Recognition sites for Ang-(1-7) (deletion of the C terminal amino acid) are
still elusive and some of the actions of angiotensin III (deletion of the N
terminal amino acid) in the CNS are hard to explain on the basis of their
interaction with AT(1)-receptors only. A more thorough cross-talk between in
vitro investigations on native and transfected cell lines and in vivo
investigations on healthy, diseased and transgenic animals may prove to be
essential to further unravel the molecular basis of the physiological actions of
these small endogenous angiotensin fragments.
Comparative effects of angiotensin IV and two hemorphins on
angiotensin-converting enzyme activity
Fruitier-Arnaudin I, et al. Peptides 2002 Aug;23(8):1465-70
Comparative effects of angiotensin IV and two hemorphins on
angiotensin-converting enzyme activity
The role of angiotensin IV (AngIV) in the regulation of angiotensin-converting
enzyme (ACE) was studied in vitro. This study demonstrates that this active
fragment appeared as a novel endogenous ACE inhibitor. Inhibitory kinetic
studies revealed that AngIV acts as a purely competitive inhibitor with a K(i)
value of 35 microM. AngIV was found to be quite resistant to ACE hydrolysis
opposite to hemorphins which are both ACE inhibitors and substrates. In order
to confirm a putative role of AngIV and hemorphins in the Renin-Angiotensin system
(RAS) regulation, we studied their influence on AngI conversion. We noticed
that 16.7 microM of both peptides decreased more than 50% of AngI conversion to
AngII in vitro. The capacity of hemorphins, particularly LVVH-7, and AngIV to
inhibit ACE activity here suggests a synergistic relation between these two
peptides and the regulation of RAS.
Fruitier-Arnaudin I, et al. Peptides 2002 Aug;23(8):1465-70
Effects of angiotensins II and IV on blood pressure, renal function, and
PAI-1 expression in the heart and kidney of the rat
Abrahamsen CT, et al.
Pharmacology 2002 Sep;66(1):26-30
Effects of angiotensins II and IV on blood pressure, renal function, and
PAI-1 expression in the heart and kidney of the rat
The role of angiotensin II (AII) and angiotensin IV (AIV) as inducers of PAI-1
expression during hypertension was studied in vivo. A 2-week infusion of AII
(300 ng/kg/min) via an osmotic pump increased systolic blood pressure (171 2
vs. 138 6 mm Hg), urinary protein excretion (32 6 vs. 14 2 mg/day), and renal
(2.2 0.5 vs. 1.0 0.1) and cardiac (1.8 0.3 vs. 1.0 0.1) gene expression of
plasminogen activator inhibitor 1 (PAI-1). AIV infusion did not affect any of
the above with the exception of PAI-1 gene expression which was increased in
the left ventricles (1.7 0.3 vs. 1.0 0.1). AII-infused rats displayed a
decreased creatinine clearance (538 75 vs. 898 96 ml/min) and hypertrophic left
ventricles (0.275 0.006 vs. 0.220 0.011 g/100 g). Our results demonstrate that
AII but not AIV infusion is associated with increased renal PAI-1 gene
expression.
Abrahamsen CT, et al.
Pharmacology 2002 Sep;66(1):26-30
Stimulation of collagen gel contraction by angiotensin II and III in cardiac
fibroblasts
Stimulation of collagen gel contraction by angiotensin II and III in cardiac
fibroblasts
OBJECTIVE: The aim of the present study was to investigate whether angiotensin
II (Ang II), angiotensin III (Ang III) or Ang II (2-8), angiotensin IV (Ang IV)
or Ang II (3-8) and Ang II (1-7), Ang II (4-8), Ang II (5-8) and Ang II (1-4)
can stimulate collagen gel contraction in cardiac fibroblasts in serum-free
conditions.
METHODS: Cardiac fibroblasts (from male adult Wistar rats) from
passage 2 were cultured to confluency and added to a hydrated collagen gel in a
Dulbecco's Modified Eagle's Medium, with or without foetal bovine serum, for
one, two or three days. The area of the collagen gels embedded with cardiac
fibroblasts was determined by a densitometric analysis. Collagen gel
contraction was characterised by a decrease in the gel area.
RESULTS: Ang II
dose-dependently stimulated the contraction of collagen mediated by cardiac
fibroblasts after one, two or three days of incubation in a serum-free medium.
Telmisartan completely blocked the Ang II-induced collagen contraction by
cardiac fibroblasts. PD 123319 and des-Asp(1)-Ile(8)-Ang II had no effect on
the Ang II-induced collagen contraction by cardiac fibroblasts. Ang III also
stimulated the contraction of collagen mediated by cardiac fibroblasts after
one, two or three days of incubation in a serum-free medium. des-Asp(1)-Ile(8)-Ang
II and telmisartan completely blocked the Ang III-induced collagen gel
contraction by cardiac fibroblasts. des-Asp(1)-Ile(8)-Ang II, however, had no
effect on the Ang II-induced collagen gel contraction by cardiac fibroblasts.
Ang IV and Ang II (4-8), (5-8), (1-7) and (1-4), however, had no effect on
collagen gel contraction by cardiac fibroblasts. Addition of telmisartan, PD
123319 or des-Asp(1)-Ile(8)-Ang II alone did not affect collagen gel
contraction by cardiac fibroblasts.
CONCLUSION: Our data demonstrate that the
effects of Ang II on the collagen gel contraction by adult rat cardiac
fibroblasts in serum-free conditions are Ang II type 1(AT(1))-receptor-
mediated, because they are abolished by the specific AT(1)-receptor antagonist,
telmisartan, and not by the AT(2)-receptor antagonist PD 123319 or by the Ang
III antagonist des-Asp(1)-Ile(8)-angiotensin. The Ang III- stimulated
contraction of collagen by cardiac fibroblasts is completely blocked by the Ang
III receptor antagonist, des-Asp(1)-Ile(8)-angiotensin II, and by telmisartan.
Angiotensin IV is a potent agonist for constitutive active human AT1
receptors. Distinct roles of the N-and C-terminal residues of angiotensin II
during AT1 receptor activation
Le MT, et al. J Biol Chem 2002 Jun
28;277(26):23107-10
Angiotensin IV is a potent agonist for constitutive active human AT1
receptors. Distinct roles of the N-and C-terminal residues of angiotensin II
during AT1 receptor activation
The octapeptide hormone, angiotensin II (Ang II), exerts its major
physiological effects by activating AT(1) receptors. In vivo Ang II is degraded
to bioactive peptides, including Ang III (angiotensin-(2-8)) and Ang IV
(angiotensin-(3-8)). These peptides stimulate inositol phosphate generation in
human AT(1) receptor expressing CHO-K1 cells, but the potency of Ang IV is very
low. Substitution of Asn(111) with glycine, which is known to cause
constitutive receptor activation by disrupting its interaction with the seventh
transmembrane helix (TM VII), selectively increased the potency of Ang IV
(900-fold) and angiotensin-(4-8), and leads to partial agonism of
angiotensin-(5-8). Consistent with the need for the interaction between Arg(2)
of Ang II and Ang III with Asp(281), substitution of this residue with alanine
(D281A) decreased the peptide's potency without affecting that of Ang IV. All
effects of the D281A mutation were superseded by the N111G mutation. The
increased affinity of Ang IV to the N111G mutant was also demonstrated by
binding studies. A model is proposed in which the Arg(2)-Asp(281) interaction causes
a conformational change in TM VII of the receptor, which, similar to the N111G
mutation, eliminates the constraining intramolecular interaction between
Asn(111) and TM VII. The receptor adopts a more relaxed conformation, allowing
the binding of the C-terminal five residues of Ang II that switches this
"preactivated" receptor into the fully active conformation.
Le MT, et al. J Biol Chem 2002 Jun
28;277(26):23107-10
New Anti-Angiotensin I/II (1-7)
Antibody for immunohistochemistry
Alia Shatanawi et al., Angiotensin II-induced vascular endothelial dysfunction through RhoA/Rho kinase/p38 mitogen-activated protein kinase/arginase pathway
