Rapamycin induces binding activity to the terminal oligopyrimidine tract of ribosomal protein mRNA in rats

Cathepsin G, elastase, and proteinase 3 are serine proteinases released by activated neutrophils. Cathepsin G can cleave angiotensinogen to release angiotensin II, but this activity has not been previously reported for elastase or proteinase 3. In this study we show that elastase and proteinase 3 can release angiotensin I from angiotensinogen and release angiotensin II from angiotensin I and angiotensinogen. The relative order of potency in releasing angiotensin II by the three proteinases at equivalent concentrations is cathepsin G > elastase > proteinase 3. When all three proteinases are used together, the release of angiotensin II is greater than the sum of the release when each proteinase is used individually. Cathepsin G and elastase can also degrade angiotensin II, reactions which might be important in regulating the activity of angiotensin II. The release and degradation of angiotensin II by the neutrophil proteinases are reactions which could play a role in the local inflammatory response and wound healing.     

Renin-angiotensin system and vascular remodelling

The renin-angiotensin system (RAS) is compartmented between circulating blood and tissue pericellular space. Whereas renin and its substrate diffuse easily from one compartment to another, the angiotensin peptides act in the compartment where there are generated: blood or pericellular space. Renin is trapped in tissues by low and high affinity receptors. In the target cells, angiotensin II/AT1 receptor interaction generates different signals including an immediate functional calcium-dependent response, secondary hypertrophy and a late proinflammatory and procoagulant response. These late pathological effects are mediated by NADPH oxydase-generated free oxygen radicals and NFkappaB activation. In vivo, the tissue binding of renin and the induction of converting enzyme are the main determinants of the involvement of the RAS in vascular remodeling. The target cells of interstitial angiotensin II are mainly the vascular smooth muscle cells and fibroblasts, whereas the endothelial cells and circulating leukocytes are the main targets of circulating angiotensin II. In vivo, angiotensin II participates in the vascular wall hypertrophy associated with hypertension. In diabetes, as in other localized fibrotic cardiovascular diseases, the tissue effects of angiotensin II are mainly dependent on its ability to induce TGF-beta expression. In experimental atherosclerosis, angiotensin II infusion induces aneurysm formation mediated by activation of circulating leucocytes. In these models, the administration of angiotensin II antagonists has beneficial effects on pathological remodeling. Such beneficial effects of angiotensin II antagonists in localized pathological remodeling have not yet been demonstrated in humans.     

Enzymatic formation of angiotensins II and III in the hindlimb circulation of dogs

Experiments were performed in 14 anesthetized dogs to (1) to determine if the reductions in hindlimb blood flow produced by [des-Asp1] angiotensin I were due to its local enzymatic (kininase II) conversion to angiotensin III and (2) to quantitate the extent of conversion of angiotensin I to angiotensin II and of [des-Asp1] angiotensin I to angiotensin III in the hindlimb circulation. Graded doses of these peptides were administered as bolus injections directly into the left external iliac artery while measuring flow in this artery electromagnetically. Dose-response relationships were determined before and during the inhibition of kininase II activity with captopril or antagonism of angiotensin receptor sites with [Ile7] angiotensin III. Captopril inhibited the vasoconstrictor responses to angiotensin I and [des-Asp1] angiotensin I, but did not affect the responses to angiotensins II or III, or norepinephrine. [Ile7] angiotensin III inhibited the vasoconstrictor responses to all four angiotensin peptides but did not alter the responses to norepinephrine. These findings indicate that the hindlimb vasoconstrictor responses to [des-Asp1] angiotensin I were due to the local formation of angiotensin III. The extent of conversion of [des-Asp1] angiotensin I to angiotensin III that occurred in one transit through the hindlimb arterial circulation was estimated to be 36.7%, which was not different from the estimated 36.4% conversion of angiotensin I to angiotensin II. We conclude that angiotensin I and [des-Asp1] angiotensin I are converted to their respective vasoactive forms (angiotensins II and III) to a similar extent in the hindlimb circulation via the action of kininase II.     

Angiotensin receptors: form and function and distribution

The peptide hormone, angiotensin II, acts primarily via type I (AT(1)) and type II (AT(2)) angiotensin receptors. Proteolytic fragments of angiotensin II also have biological activity via these and other receptors, with actions that may mimic or antagonise angiotensin II. Most notably, a high affinity-binding site for angiotensin IV (the Val(3)-Phe(8) fragment of angiotensin II) has recently been identified as the insulin-regulated aminopeptidase (IRAP). While AT(1) and AT(2) receptors are seven transmembrane-spanning, G protein-coupled receptors with some well-established features of relevance to health and disease, the existence of separate receptor systems for angiotensin fragments offers exciting possibilities for new therapeutics to target the diverse actions of the angiotensin peptides.     

Formation of angiotensin III by angiotensin-converting enzyme.

Angiotensin III is formed from des-Asp1 -angiotensin I by angiotensin-converting enzyme. The Km (11 muM) of the reaction is one-third of that for the conversion of angiotensin I into angiotensin II. As suggested by the Km values, bradykinin, peptide BPP9a and angiotensins II and III are better inhibitors of the formation of angiotensin II than of the formation of angiotensin III.     

NMR studies on angiotensin II: Histidine and phenylalanine ring stacking and biological activity

The conformations of angiotensin II and the antagonist [Sar¹, Ile⁸]angiotensin II in dimethylsulfoxide have been examined by high resolution proton magnetic resonance spectroscopy at 400MHz. The chemical shifts for the aromatic protons of the phenylalanine residue in angiotensin II are consistent with shielding and restricted rotation for this side-chain. The chemical shifts for the histidine C₂ and C₄ protons in angiotensin II also indicate shielding, whereas these same protons in the antagonist [Sar¹, Ile⁸]angiotensin II do not demonstrate this shielding influence. These findings suggest a stacking interaction for the histidine and phenylalanine side-chains in angiotensin II which is important for activating angiotensin receptors.     

Effects of angiotensin analogues and angiotensin receptor antagonists on paraventricular neurones.

In a previous study we observed that most neurones in the paraventricular nucleus are excited by angiotensin-(1-7). In comparison with angiotensin III this excitatory action was significantly delayed. The aim of the present microiontophoretic study of angiotensin II-sensitive rat paraventricular neurones was to compare the effect of the angiotensin-analogues angiotensin-(1-7), angiotensin-(2-7), angiotensin II and angiotensin III on the spontaneous activity of these neurones and to test angiotensin receptor subtype 1 antagonists (CGP 46027 or DuP 753) and subtype 2 selective antagonists (CGP 42112A and PD 123177) in order to acquire more evidence of the receptor subtype present. As previously observed angiotensin II, angiotensin III and angiotensin-(1-7) excited most neurones. The effect of angiotensin-(1-7) was usually weaker than that of angiotensin II, and in contrast to angiotensin III the latencies were not significantly different. Angiotensin-(1-7) seemed to be active by itself, because its effect was antagonised by angiotensin receptor antagonists. Angiotensin-(2-7) was mostly inactive, although a few cells were excited. Whereas the excitatory effects of angiotensin-(1-7), angiotensin II and angiotensin III could always be inhibited with both angiotensin receptor subtype antagonists 1 and 2, that produced by angiotensin-(2-7) was only weakly antagonised, if at all. Subtype 1 selective antagonists were effective at lower concentrations than selective subtype 2 antagonists.     

Dehydration and fluid balance: central effects of angiotensin

Central effects of dehydration are stimulated by osmotic stimuli, the reduced input of volume receptors, and angiotensin II. The subfornical organ (SFO) and organum vasculosum laminae terminalis (OVLT) have become accepted as putative receptor sites for angiotensin II in the brain. The exact quantitative relationship between the hours of water deprivation and the amount of angiotensin generated peripherally and whether that amount is sufficient to induce thirst centrally have not been established, but there is no question that when animals are dehydrated their angiotensin levels rise and the animals are thirsty. Attempts to block centrally the contribution of angiotensin II to thirst have been variable and cholinergic inputs have to be blocked at the same time. Various stimuli for thirst interact in a parallel fashion, and when one stimulus is blocked the other stimuli are still effective. Plasma angiotensin II may induce natural thirst, but how it enters the brain still remains to be explained. Although the SFO and OVLT have no blood-brain barrier, the blood supply to these organs acts as a limited perfusion system whereby blood-borne proteins cannot diffuse far from the capillary bed. A second set of receptors is found on the ventricular surface of the OVLT, as shown by fluorescence labeled angiotensin II. The connection between the SFO and OVLT was cut by discrete knife cuts. Drinking to angiotensin II intraventricularly was not significantly altered but the pressor response was reduced by 50%. These results can be explained by a circuit for drinking passing down below the level of the knife cut and a separate pressor pathway passing dorsally through the area that was cut by the knife. Thirst and pressor neural circuits beginning with angiotensin receptors could explain some of the data accumulated with the AV3V syndrome that occurs when the OVLT and nucleus medianas are destroyed.     

Angiotensin receptor type 1 forms a complex with the transient outward potassium channel Kv4.3 and regulates its gating properties and intracellular localization

We report a novel signal transduction complex of the angiotensin receptor type 1. In this complex the angiotensin receptor type 1 associates with the potassium channel alpha-subunit Kv4.3 and regulates its intracellular distribution and gating properties. Co-localization of Kv4.3 with angiotensin receptor type 1 and fluorescent resonance energy transfer between those two proteins labeled with cyan and yellow-green variants of green fluorescent protein revealed that Kv4.3 and angiotensin receptor type I are located in close proximity to each other in the cell. The angiotensin receptor type 1 also co-immunoprecipitates with Kv4.3 from canine ventricle or when co-expressed with Kv4.3 and its beta-subunit KChIP2 in human embryonic kidney 293 cells. Treatment of the cells with angiotensin II results in the internalization of Kv4.3 in a complex with the angiotensin receptor type 1. When stimulated with angiotensin II, angiotensin receptors type 1 modulate gating properties of the remaining Kv4.3 channels on the cell surface by shifting their activation voltage threshold to more positive values. We hypothesize that the angiotensin receptor type 1 provides its internalization molecular scaffold to Kv4.3 and in this way regulates the cell surface representation of the ion channel.     

Characterization of angiotensin II binding sites in African Green monkey uterus

The observation that there are significant differences in the concentration, affinity, and specificity of both central nervous system (CNS) and peripheral angiotensin receptors among several different mammalian species, including the African Green monkey, led to the detailed analysis of 125I-angiotensin II binding in the uterus of the African Green monkey. The Bmax for angiotensin receptors in uterine tissue from this species is 56.6 +/- 8.7 fmole per mg protein. The Kd for angiotensin II is .601 +/- .108 nM. The specificity of the receptor is similar to that reported for the uterus of the rat and dog. These results indicate that the angiotensin II receptors, although nearly absent from the CNS of the African Green monkey, are found in the uterus and are very similar to uterine receptors previously characterized in the rat and dog and support the use of these species as appropriate models for studying the biochemistry of angiotensin binding in the uterus.     

Peptide inhibitors of converting enzyme.

Human plasma and atypical lung converting enzyme, and porcine plasma converting enzyme are substantially inhibited by other components of the renin-angiotensin system, and by angiotensin II and its analogues. Des-Asp¹ angiotensin II (angiotensin III) 0.1 mM and tridecapeptide renin substrate 0.1 mM are both effective inhibitors of human lung, plasma and porcine plasma converting enzymes. Des-Asp¹-Arg² angiotensin II also was an effective inhibitor of plasma enzymes. Bradykininase activity (kininase II) of the converting enzymes was also inhibited by angiotensin I, angiotensin III, tetradecapeptide renin substrate and tridecapeptide renin substrate. The substantial kininase and converting enzyme inhibitory effects of components of the renin-angiotensin system, suggest a potential close physiologic relationship between the kallikrein-kinin system and the renin-angiotensin system.     

Actions of angiotensin on adrenergic nerve endings.

In the perfused vascular bed, vasoconstrictor responses to adrenergic nerve stimulation are augmented to a greater degree by angiotensin II than are the responses to injected norepinephrine. Overflow of adrenergic transmitter is also greater during nerve stimulation in the presence of angiotensin than in its absence. The evidence indicates that facilitation of adrenergic transmitter release rather than uptake blockade accounts for these results. In addition, an increased responsiveness of isolated arterial strips to norepinephrine as well as other agonists appears to contribute to the adrenergic potentiating effect of angiotensin II as well as angiotensin III. This action, which appears to be a cell membrane effect, seems to participate in adrenergic potentiation mainly in the arterial segment of the intact vascular bed. Both of these effects of angiotensin, i.e., facilitation of release and increased smooth muscle responsiveness, appear to be mediated by angiotensin receptors.     

Role of lipoxygenase products in the effects of angiotensin II in the isolated aorta and perfused heart of the rat

The objective of this study was to determine whether arachidonate metabolites are involved in the vasoconstrictive effects of angiotensin II in rats. In the isolated perfused heart, dexamethasone (4 mg/kg) significantly suppressed the maximal decreases in coronary flow induced by angiotensin II and vasopressin (reference drug). In the heart, the nonselective lipoxygenase inhibitor nordihydroguaiaretic acid (NDGA, 1 muM) markedly suppressed the angiotensin II-induced decreases in coronary flow. NDGA (10 muM) inhibited both angiotensin II- and methoxamine- (reference drug) induced contractions in aortic rings with (in the presence of L-NAME) and without endothelium. In the heart, the leukotriene synthesis inhibitor MK-886 (0.3 muM) significantly reduced the maximal effects to angiotensin II, but the leukotriene antagonist FPL 55712 (0.1 and 0.3 muM) had no effect. We conclude that in the isolated perfused rat heart angiotensin II-induced decreases in coronary flow are in part mediated by Hpoxygenase products, which might be derived from the 5-Hpoxygenase pathway, but are probably not leukotrienes. Furthermore, endothelium independent Hpoxygenase products mediate part of the contractile responses to angiotensin II in the isolated rat aorta.     

ACTH-induced inhibition of the action of angiotensin II in bovine zona glomerulosa cells. A modulatory effect of cyclic AMP on the angiotensin II receptor.

Both angiotensin II and adrenocorticotropic hormone (ACTH) are well known to play a crucial role on the regulation of aldosterone production in adrenal glomerulosa cells. Recent observations suggest that the steroidogenic action of ACTH is mediated via the cAMP messenger system, whereas angiotensin II acts mainly through the phosphoinositide pathway. However, there have been no reports concerning the interaction between the cAMP messenger system activated by ACTH and the Ca2+ messenger system induced by angiotensin II. Both ACTH and angiotensin II simultaneously act on adrenal cells for regulating steroidogenesis under physiological conditions. Thus the present experiments were performed to examine the effect of ACTH on the action of angiotensin II by measuring angiotensin II receptor activity, cytosolic Ca2+ movement, and aldosterone production. The major findings of the present study are that short-term exposure to a high dose of ACTH (10(-7) M) inhibited 125I-angiotensin II binding to bovine adrenal glomerulosa cells, decreased the initial spike phase of [Ca2+]i induced by angiotensin II, and inhibition of angiotensin II-induced aldosterone production. Low dose of ACTH (10(-10) M), which did not increase cAMP formation, did not affect angiotensin II receptor activity. These studies have shown that angiotensin II receptors of bovine adrenal glomerulosa cells can be down-regulated by 1 mM dibutyryl cyclic AMP, as well as by effectors which are able to activate cAMP formation (10(-7) M ACTH and 10(-5) M forskolin). The rapid decrease in angiotensin II receptors induced by 10(-7)M ACTH was associated with a decreased steroidogenic responsiveness and a decreased rise in the [Ca2+]i response induced by angiotensin II. These studies show that the cAMP-dependent processes activated by ACTH have the capacity to interfere with signal transduction mechanisms initiated by receptors for angiotensin II.     

Angiotensin 'antipeptides': (-)messenger RNA complementary to human angiotensin II (+)messenger RNA encodes an angiotensin receptor antagonist

(-)mRNA complementary to human angiotensin II (+)mRNA encodes the 'antipeptide' Glu-Gly-Val-Tyr-Val-His-Pro-Val which is structurally related to angiotensin II. Angiotensin II 'antipeptide' (antiANG II) and the desglutamyl heptapeptide (antiANG III) are Type I antagonists which inhibit the contractile action of angiotensin at smooth muscle receptors by binding to a negative modulatory site on the angiotensin receptor which is distinct from the angiotensin binding site. These findings may illustrate that the inhibitory binding site on the angiotensin receptor exists to accomodate a naturally occurring inhibitor(s), which is encoded by the DNA strand complementary to that encoding angiotensin II.     

Regulatory Networks and Complex Interactions between the Insulin and Angiotensin II Signalling Systems: Models and Implications for Hypertension and Diabetes

The cross-talk between insulin and angiotensin II signalling pathways plays a significant role in the co-occurrence of diabetes and hypertension. We developed a mathematical model of the system of interactions among the biomolecules that are involved in the cross-talk between the insulin and angiotensin II signalling pathways. We have identified several feedback structures that regulate the dynamic behavior of the individual signalling pathways and their interactions. Different scenarios are simulated and dominant steady-state, dynamic and stability characteristics are revealed. The proposed mechanistic model describes how angiotensin II inhibits the actions of insulin and impairs the insulin-mediated vasodilation. The model also predicts that poor glycaemic control induced by diabetes contributes to hypertension by activating the renin angiotensin aystem.     

Angiotensin II binding to mammalian brain membranes.

High affinity binding sites for angiotensin II in bovine and rat brain membranes have been identified and characterized using monoiodinated Ile5-angiotensin II of high specific radioactivity. Degradation of labeled and unlabeled peptide by washed brain particulate fractions was prevented by adding glucagon to the final incubation medium and including a proteolytic enzyme inhibitor (phenylmethylsulfonyl fluoride) in preincubation and incubation procedures. 125I-Angiotensin II binding can be studied using either centrifugation or filtration techniques to separate tissue-bound radioactivity. 125I-Angiotensin II binding to calf brain membranes is saturable and reversible, with a dissociation binding constant of 0.2 nM at 37 degrees. A similar binding constant is found in rat brain membranes. Analogues and fragments of angiotensin II compete for these brain binding sites with potencies which correlate with both their in vivo potencies and their binding inhibition protencies at adrenal cortex angiotensin II receptors. Angiotensin I is 1 to 2 orders of magnitude weaker than angiotensin II; the 3-8 hexapeptide and 4-8 pentapeptide are much weaker still. (desAsp1) angiotensin II (angiotensin III) is slightly more potent than angiotensin II, as are several antagonists of angiotensin II with aliphatic amino acids substituted at position 8. In calf brain 125I-angiotensin II binding is restricted almost exclusively to the cerebellum (cortex and deep nuclei). In rat brain, angiotensin II binding is highest in the thalamus-hypothalamus, midbrain, and brainstem, areas which are believed to be involved in mediating angiotensin II-induced central effects. These findings illustrate the presence of high affinity specific binding sites for angiotensin II in rat and bovine brain and suggest a physiological role for angiotensin peptides in the central nervous system.     

α1-Adrenergic Receptor-Mediated Downregulation of Angiotensin II Receptors in Neuronal Cultures

Previous evidence has suggested that brain catecholamine levels are important in the regulation of central angiotensin II receptors. In the present study, the effects of norepinephrine and 3,4-dihydroxyphenylethylamine (dopamine) on angiotensin II receptor regulation in neuronal cultures from rat hypothalamus and brainstem have been examined. Both catecholamines elicit significant decreases in [125I]angiotensin II-specific binding to neuronal cultures prepared from normotensive rats, effects that are dose dependent and that are maximal within 4-8 h of preincubation. Saturation and Scatchard analyses revealed that the norepinephrine-induced decrease in the binding is due to a decrease in the number of angiotensin II receptors in neuronal cultures, with little effect on the receptor affinity. Norepinephrine has no significant actions on [125I]angiotensin II binding in cultures prepared from spontaneously hypertensive rats. The downregulation of angiotensin II receptors by norepinephrine or dopamine is blocked by alpha 1-adrenergic and not by other adrenergic antagonists, a result suggesting that this effect is initiated at the cell surface involving alpha 1-adrenergic receptors. This is further supported by our data indicating a parallel downregulation of specific alpha 1-adrenergic receptors elicited by norepinephrine. In summary, these results show that norepinephrine and dopamine are able to alter the regulation of neuronal angiotensin II receptors by acting at alpha 1-adrenergic receptors, which is a novel finding.     

Blockade of the pre- and postjunctional effects of angiotensin in vivo with a non-peptide angiotensin receptor antagonist

Recent reports indicate that some imidazole-5-acetic acid derivatives are competitive antagonists of angiotensin II receptors. However, to our knowledge, there is no published information regarding: 1) what constant infusion rate of these non-peptide angiotensin receptor blockers is necessary to effectively antagonize angiotensin receptors in vivo, 2) whether imidazole-5-acetic acid derivatives antagonize both prejunctional and postjunctional angiotensin receptors, and 3) whether effective levels of these compounds exert non-specific actions and/or partial agonist activity. To address these issues, either vehicle, 2-butyl-4-chloro-1-(2-nitrobenzyl) imidazole-5-acetic acid (CV-2961; 30 and 100 micrograms/min) or a standard angiotensin receptor blocker, 1Sar8Ile-angiotensin II (100 ng/min), was infused intravenously into captopril-treated rats that were prepared for in situ perfusion of their mesenteric vascular beds. Infusion of CV-2961 for two and one-half hours did not alter arterial blood pressure, mesenteric perfusion pressure, plasma aldosterone level, or mesenteric vascular responses to sympathetic nerve stimulation or exogenous norepinephrine. The higher dose of CV-2961 (100 micrograms/min) completely blocked angiotensin II-induced enhancement of vascular responses to sympathetic nerve stimulation and shifted the angiotensin dose-response curve 10-fold to the right with respect to angiotensin II-induced increases in mesenteric perfusion pressure. The effects of the lower dose of CV-2961 (30 micrograms/min) on these actions of angiotensin II were not statistically significant. 1Sar8Ile-angiotensin II abolished both the prejunctional and postjunctional effects of angiotensin II. We conclude that in intact rats CV-2961, infused at 100 micrograms/min, antagonizes both prejunctional and postjunctional angiotensin II receptors, yet has a somewhat greater effect on the prejunctional actions of angiotensin II. CV-2961 is devoid of partial agonist activity, and no non-specific actions of CV-2961 are evident. Imidazole-5-acetic acid derivatives may find considerable utility as pharmacological probes and as therapeutic agents.     

Cyclic insulin-regulated aminopeptidase (IRAP)/AT4 receptor ligands.

The angiotensin IV receptor (AT4 receptor) is the insulin-regulated aminopeptidase enzyme (IRAP, EC 3.4.11.3). This membrane-spanning enzyme belongs to the M1 family of zinc-dependent metallo-peptidases. It has been proposed that AT4 receptor ligands exert their physiological effects by binding to the active site of IRAP and thereby inhibiting the catalytic activity of the enzyme. The biological activity of a large series of linear angiotensin IV analogs was previously disclosed. Herein, the synthesis and biological evaluation of a series of angiotensin IV analogs, encompassing macrocyclic ring systems of different sizes, are presented. It is demonstrated that disulfide cyclizations of angiotensin IV can deliver ligands with high IRAP/AT4 receptor affinity. One ligand, with an 11-membered ring system (4), inhibited human IRAP and aminopeptidase N (AP-N) activity with similar potency as angiotensin IV but was considerably more stable than angiotensin IV toward enzymatic degradation. The compound provides a promising starting point for further optimization toward more drug-like derivatives. The cyclic constrained analogs allowed us to propose a tentative bioactive conformation of angiotensin IV and it seems that the peptide adopts an inverse gamma-turn at the C-terminal.