Replacement of the transmembrane anchor in angiotensin I-converting enzyme (ACE) with a glycosylphosphatidylinositol tail affects activation of the B2 bradykinin receptor by ACE inhibitors

To investigate further the relationship of angiotensin I-converting enzyme (ACE) inhibitors to activation of the B(2) bradykinin (BK) receptor, we transfected Chinese hamster ovary cells to stably express the human receptor and either wild-type ACE (WT-ACE), an ACE construct with most of the cytosolic portion deleted (Cyt-del-ACE), or ACE with a glycosylphosphatidylinositol (GPI) anchor replacing the transmembrane and cytosolic domains (GPI-ACE). BK or its ACE-resistant analogue were the agonists. All activities (arachidonic acid release and calcium mobilization) were blocked by the B(2) antagonist HOE 140. B(2) was desensitized by repeated administration of BK but resensitized to agonist by ACE inhibitors in the cells expressing both B(2) and either WT-ACE or Cyt-del-ACE. In GPI-ACE expressing cells, the B(2) receptor was still activated by the agonists, but ACE inhibitors did not resensitize. Pretreatment with filipin returned the sensitivity to inhibitors. In immunocytochemistry, GPI-ACE showed patchy, uneven distribution on the plasma membrane that was restored by filipin. Thus, ACE inhibitors were inactive as long as GPI-ACE was sequestered in cholesterol-rich membrane domains. WT-ACE and B(2) receptor in Chinese hamster ovary cells co-immunoprecipitated with antibody to receptor, suggesting an interaction on the cell membrane. ACE inhibitors augment BK effects on receptors indirectly only when enzyme and receptor molecules are sterically close, possibly forming a heterodimer.     

ACE inhibitors as activators of kinin receptors

Angiotensin converting enzyme (ACE) inhibitors are widely used for treatment of cardiovascular diseases. Studies of interaction of ACE inhibitors with bradykinin receptors have shown that ACE inhibitors potentiate bradykinin effects not only by blocking its inactivation but also by activation of its receptors. The mechanism of activation and also structural features of the kinin B₂R and B₁R receptors by ACE inhibitors have been characterized and amino acid residues involved into kinin receptor coupling to G proteins have been identified. Kinins and their receptors are involved into positive therapeutic effect of ACE inhibitors.     

Transient hyperosmolality modulates expression of cardiac aquaporins

Angiotensin-I converting enzyme (ACE) is a zinc dependent peptidase with a major role in regulating vasoactive peptide metabolism. ACE, a transmembrane protein, undergoes proteolysis, or shedding, by an as yet unidentified proteinase to release a catalytically active soluble form of the enzyme. Physiologically, soluble ACE in plasma is derived primarily from endothelial cells. We demonstrate that ACE shedding from confluent endothelial cells is increased in response to bacterial lipopolysaccharide, but not phorbol esters. Characterisation of lipopolysaccharide stimulated shedding showed that there is a lag phase before soluble ACE can be detected which is sensitive to inhibitors of translation, NF-κB, TNFα and TNFR-I/II. The shedding phase is less sensitive to these inhibitors, but is ablated by BB-94, a Matrix Metalloproteinase (MMP)/A Disintegrin and Metalloproteinase (ADAM) inhibitor. Tissue Inhibitor of Metalloproteinase (TIMP) profiling suggested a requirement for ADAM9 in lipopolysaccharide induced ACE shedding, which was confirmed by depletion with siRNA. Transient transfection of ADAM9 and ACE cDNAs into HEK293 cells demonstrated that ADAM9 requires both membrane anchorage and its catalytic domain to shed ACE.     

Kinins, receptors, kininases and inhibitors--where did they lead us?

Based on studies presented here and other published experiments performed with surviving tissue preparations, with transfected cells and with cells that constitutively express the human angiotensin I converting enzyme ACE and B2 receptors, we concluded the following: ACE inhibitors and other endogenous peptides that react with the active site of ACE potentiate the effect of bradykinin and its ACE resistant peptide congeners on the B2 receptor. They also resensitize receptors which had been desensitized by the agonist. ACE and bradykinin receptors have to be sterically close, possibly forming a heterodimer, for the ACE inhibitors to induce an allosteric modification on the receptor. When ACE inhibitors augment bradykinin effects, they reduce the phosphorylation of the B2 receptor. The primary actions of bradykinin on the receptor are not affected by protein kinase C or phosphatase inhibitors, but the potentiation of bradykinin or the resensitization of the receptor by ACE inhibitors are abolished by the same inhibitors. The results with protein kinase C and phosphatase inhibitors indicate that another intermediate protein may be involved in the processes of signaling induced by ACE inhibitors, and that ACE inhibitors affect the signal transduction pathway triggered by bradykinin on the B2 receptor.     

Liquid membrane phenomenon in the actions of digitalis

The liquid membrane phenomenon in the actions of digitalis glycosides (digitoxin, digoxin and ouabain) has been studied. Formation of liquid membranes, in series with a supporting membrane, by digitalis alone and by digitalis in association with lecithin and cholesterol has been demonstrated. The results obtained on the transport of relevant permeants, viz. sodium, potassium and calcium ions and dopamine, adrenaline, noradrenaline and serotonin, in the presence of the liquid membrane generated by digitalis in association with lecithin and cholesterol indicate that the liquid membrane barrier to transport may have a relevance with the biological actions of digitalis.     

Protein processing mechanisms: from angiotensin-converting enzyme to Alzheimer's disease

Angiotensin-converting enzyme (ACE) and the Alzheimer's disease amyloid precursor protein are two examples of membrane-bound proteins that are released in a soluble form by a post-translational proteolytic cleavage event involving a secretase. Site-specific antibodies and matrix-assisted laser desorption ionization-time-of-flight ('MALDI-TOF') MS have been used to map the secretase cleavage site in somatic ACE to Arg-1203/Ser-1204, 24 residues proximal to the membrane-anchoring domain. Trypsin, which can solubilize ACE from the membrane, cleaves the protein at the same site. The use of structurally related hydroxamic acid-based zinc metalloproteinase inhibitors indicate that tumour necrosis factor-alpha convertase, a member of the ADAMs ('a disintegrin and metalloproteinase') family of proteins, is not involved in the proteolytic release of ACE, or in the constitutive or regulated alpha-secretase release of the amyloid precursor protein from a human neuronal cell line.     

血管紧张素转化酶抑制肽的研究进展

血管紧张素转化酶 (angiotensin I convertingenzyme ,ACE)在血压调节方面起着重要的作用 ,当其受到抑制时血压就会降低。许多合成的ACE抑制剂被广泛地应用于临床 ,但会造成多种副作用。近年来 ,对天然ACE抑制肽的研究表明 ,一些来源于蛋白酶解产生的活性肽可以对ACE起到有效的抑制作用。综述了血管紧张素转化酶的抑制肽的降压原理 ,种类和来源以及结构特点等的研究进展 ,并对其应用前景进行了展望。     

Bradykinin,angiotensin-(1-7), and ACE inhibitors: how do they interact?

The beneficial effect of ACE inhibitors in hypertension and heart failure may relate, at least in part, to their capacity to interfere with bradykinin metabolism. In addition, recent studies have provided evidence for bradykinin-potentiating effects of ACE inhibitors that are independent of bradykinin hydrolysis, i.e. ACE-bradykinin type 2 (B(2)) receptor 'cross-talk', resulting in B(2) receptor upregulation and/or more efficient activation of signal transduction pathways, as well as direct activation of bradykinin type 1 receptors by ACE inhibitors. This review critically reviews the current evidence for hydrolysis-independent bradykinin potentiation by ACE inhibitors, evaluating not only the many studies that have been performed with ACE-resistant bradykinin analogues, but also paying attention to angiotensin-(1-7), a metabolite of both angiotensin I and II, that could act as an endogenous ACE inhibitor. The levels of angiotensin-(1-7) are increased during ACE inhibition, and most studies suggest that its hypotensive effects are mediated in a bradykinin-dependent manner.     

Potential of Plant’s Dipeptidyl Peptidase I & II Homologs in Generation of ACE Inhibitory Peptides

Synthetic inhibitors of angiotensin converting enzyme (ACE) are commonly used in the treatment of hypertension and other cardiovascular diseases. But their diverse side effects stipulated nontoxic safer and economic inhibitors which can be accomplished by using peptidyl inhibitors from natural sources or functional food ingradients. Dipeptidyl peptidases cleaved dipeptide moieties from amino terminus of oligopepides so, they may be used to generate effective dipeptidyl ACE inhibitors. In present study, role of purified DPP-I and II in generation of ACE inhibitors have been explored. Results showed that collagen alpha-1(III) from chicken showed highest ACE inhibitory potential. Both dipeptidyl peptidases hydrolysed various potent inhibitory dipeptides from their oligopeptide precursors. In addition, sequential digestion of proteins with trypsin, DPP-I and II released approximate 15 % of total inhibitory peptides. Furthermore, inhibitory peptide concentration can be increased up to 30 % or more by using more proteases in presence of DPP-I and II. Results revealed that both DPP-I and II possesses the ability to generate ACE dipeptide inhibitors from oligopeptides. Still various dipeptidyl inhibitory peptides remained in generating oligopeptides, which required study of other endopeptidases with broad specificities.     

Angiotensin converting enzyme: implications from molecular biology for its physiological functions.

1. The two isozymes of human angiotensin converting enzyme (ACE; EC 3.4.15.1) have recently been cloned and sequenced. 2. The larger, endothelial isozyme has two highly similar internal domains each bearing a putative catalytic site. In contrast the smaller, testicular isozyme has a single catalytic site corresponding to the C-terminal domain of endothelial ACE and represents the ancestral, non-duplicated form of the gene. 3. Both isozymes are anchored in the plasma membrane by a single hydrophobic transmembrane polypeptide located near the C-terminus, and both are extensively N-glycosylated. 4. The testicular isozyme may also be O-glycosylated. 5. The soluble form of ACE in plasma, seminal fluid and other body fluids appears to be derived from the membrane-bound endothelial isozyme by a post-translational modification. 6. ACE has a complex substrate specificity with peptidyl tripeptidase or endopeptidase action on certain peptides, as well as the classical peptidyl dipeptidase activity. 7. Numerous potent inhibitors of the enzyme have been developed and used successfully in the treatment of hypertension, but some of the observed side effects may be due to inhibition of other zinc metalloenzymes. 8. Both endothelial and testicular ACE are highly conserved between species, indicative of the essential role(s) of the enzyme in blood pressure regulation and other physiological processes.     

New potent inhibitors of angiotensin converting enzyme

Using an earlier model of the favoured orientation of binding functions of angiotensin converting enzyme (ACE) inhibitors, it has been possible to postulate a new, 7,6-bicyclic system, based on hexahydropyridazine, which might be expected to have high potency. Some members of this system which have been synthesised have been shown to be very active ACE inhibitors, in vitro and in vivo.     

Liquid membrane phenomenon in the biological actions of benzodiazepines

The liquid membrane phenomenon in benzodiazepines has been studied. Transport of glycine, GA-BA, noradrenaline, dopamine and serotonin in the presence of the liquid membranes generated by the benzodiazepines in association with lecithin and cholesterol has been studied. The data indicate that modification in permeabilities in the presence of the liquid membranes is likely to make a significant contribution to several biological actions of the benzodiazepines.     

Role of liquid membrane phenomenon in the biological actions of prostaglandins: studies on prostaglandin E1 and prostaglandin F2 alpha

Modifications in the transport of relevant permeants to their respective sites of action due to the liquid membranes formed by prostaglandins in association with lecithin and cholesterol have been discussed in the light of biological actions of prostaglandins. It has been shown that the phenomenon of liquid membrane formation is likely to make a significant contribution to the biological actions.     

Monoclonal Antibodies 1G12 and 6A12 to the N-domain of human angiotensin-converting enzyme: fine epitope mapping and antibody-based detection of ACE inhibitors in human blood

Angiotensin I-converting enzyme (ACE), a key enzyme in cardiovascular pathophysiology, consists of two homologous domains (N- and C-), each bearing a Zn-dependent active site. ACE inhibitors are among the most prescribed drugs in the treatment of hypertension and cardiac failure. Fine epitope mapping of two monoclonal antibodies (mAb), 1G12 and 6A12, against the N-domain of human ACE, was developed using the N-domain 3D-structure and 21 single and double N-domain mutants. The binding of both mAbs to their epitopes on the N-domain of ACE is significantly diminished by the presence of the C-domain in the two-domain somatic tissue ACE and further diminished by the presence of sialic acid residues on the surface of blood ACE. The binding of these mAbs to blood ACE, however, increased dramatically (5-10-fold) in the presence of ACE inhibitors or EDTA, whereas the effect of these compounds on the binding of the mAbs to somatic tissue ACE was less pronounced and even less for truncated N-domain. This implies that the binding of ACE inhibitors or removal of Zn2+ from ACE active centers causes conformational adjustments in the mutual arrangement of N- and C-domains in the two-domain ACE molecule. As a result, the regions of the epitopes for mAb 1G12 and 6A12 on the N-domain, shielded in somatic ACE by the C-domain globule and additionally shielded in blood ACE by sialic acid residues in the oligosaccharide chains localized on Asn289 and Asn416, become unmasked. Therefore, we demonstrated a possibility to employ these mAbs (1G12 or 6A12) for detection and quantification of the presence of ACE inhibitors in human blood. This method should find wide application in monitoring clinical trials with ACE inhibitors as well as in the development of the approach for personalized medicine by these effective drugs.     

Angiotensin I-converting enzyme inhibitory peptides isolated from tofuyo fermented soybean food

Angiotensin I-converting enzyme (ACE) inhibitory activity was observed in a tofuyo (fermented soybean food) extract with an IC(50) value of 1.77 mg/ml. Two ACE inhibitors were isolated to homogeneity from the extract by adsorption and gel filtration column chromatography, and by reverse-phase high-performance liquid chromatography (HPLC). The purified substances reacted with 2,4,6-trinitrobenzensulfonic acid sodium salt. The amino acid sequences of these inhibitors determined by Edman degradation were Ile-Phe-Leu (IC(50), 44.8 microM) and Trp-Leu (IC(50), 29.9 microM). The Ile-Phe-Leu sequence is found in the alpha- and beta-subunits of beta-conglycinin, while the Trp-Leu sequence is in the B-, B1A- and BX-subunits of glycinin from soybean. Both of the peptides are non-competitive inhibitors. The inhibitory activity of Trp-Leu was completely preserved after a treatment with pepsin, chymotrypsin or trypsin. Even after successive digestion by these gastrointestinal proteases, the activity remained at 29% of the original value.     

Characterization of new milk-derived inhibitors of angiotensin converting enzyme in vitro and in vivo

Inhibition of angiotensin converting enzyme (ACE) has been observed with a variety of different peptides, and peptide fragments with inhibitory capabilities have been identified within many different proteins, including milk proteins. The purpose of this study therefore was to identify new short peptides with inhibitory properties from the primary structure of milk proteins and to characterize them in vitro and in vivo, since no milk derived ACE inhibitors have previously been evaluated for their ability to inhibit ACE in vivo. In vitro, 8 of 9 dipeptides were found to be competitive inhibitors of ACE. The IC50 was significantly lower when an angiotensin I-like substrate was used, than when a bradykinin-like substrate was used. Using three different in vivo models for ACE inhibition, a very moderate effect was observed for three of the new peptides, but only for up to 6 or 12 minutes. Nothing was observed with two reference compounds that are reported to be hypotensive ACE-inhibitors derived from milk proteins. This raises the question whether the mechanism of hypotensive action is straightforward inhibition of ACE in vivo.     

An overview of the influence of ACE inhibitors on fetal-placental circulation and perinatal development

The renin-angiotensin system is associated with a variety of pathophysiological processes in many organ systems, and is known to be involved in the normal regulation of blood pressure and in the pathogenesis of renovascular hypertension. Angiotensin II is a multifunctional hormone that manifests its properties by interacting with two major subtypes of cell surface receptors (AT1 and AT2). Angiotensin converting enzyme (ACE) inhibitors are able to modify the actions of the renin-angiotensin system, and are indicated for the treatment of hypertension and heart disease. The antihypertensive effects of ACE inhibiting drugs are related to their ability to block the conversion ofthe decapeptide, angiotensin I, to the potent pressor octapeptide, angiotensin II. ACE inhibitors have been implicated in fetopathies in humans and perinatal mortality in rats, rabbits, sheep and baboons. Human fetopathies were seen when ACE inhibitors were given around the 26th week of gestation. The major adverse effects in babies include: oligohydramnios, renal tubular dysgenesis, neonatal anuria, calvarial and pulmonary hypoplasia, mild to severe intrauterine growth retardation, persistent patent ductus arteriosus and fetal or neonatal death. These developmental anomalies are thought to be partly due to a direct action of ACE inhibitors on the fetal renin-angiotensin system and partly due to the ischemia resulting from matemal hypotension and decreases in fetal-placental blood flow and oxygen/nutrient delivery to the fetus. The purpose ofthis review is to briefly discuss the pathophysiological role ofthe reninangiotensin system, the therapeutic uses of ACE inhibitors in pregnant patients and to focus primarily on the major fetotoxic effects of ACE inhibitors encountered in humans and animal models. I will also review our recent data which show that capozide (captopril + hydrochlorothiazide) not only produces oligohydramnios but also disturbs the balance of glucose and NaCl in the maternal plasma and amniotic fluid of the rat.     

Conformational Changes of Blood ACE in Chronic Uremia

Background

The pattern of binding of monoclonal antibodies (mAbs) to 16 epitopes on human angiotensin I-converting enzyme (ACE) comprise a conformational ACE fingerprint and is a sensitive marker of subtle protein conformational changes.

Hypothesis

Toxic substances in the blood of patients with uremia due to End Stage Renal Disease (ESRD) can induce local conformational changes in the ACE protein globule and alter the efficacy of ACE inhibitors.

Methodology/Principal Findings

The recognition of ACE by 16 mAbs to the epitopes on the N and C domains of ACE was estimated using an immune-capture enzymatic plate precipitation assay. The precipitation pattern of blood ACE by a set of mAbs was substantially influenced by the presence of ACE inhibitors with the most dramatic local conformational change noted in the N-domain region recognized by mAb 1G12. The “short” ACE inhibitor enalaprilat (tripeptide analog) and “long” inhibitor teprotide (nonapeptide) produced strikingly different mAb 1G12 binding with enalaprilat strongly increasing mAb 1G12 binding and teprotide decreasing binding. Reduction in S-S bonds via glutathione and dithiothreitol treatment increased 1G12 binding to blood ACE in a manner comparable to enalaprilat. Some patients with uremia due to ESRD exhibited significantly increased mAb 1G12 binding to blood ACE and increased ACE activity towards angiotensin I accompanied by reduced ACE inhibition by inhibitory mAbs and ACE inhibitors.

Conclusions/Significance

The estimation of relative mAb 1G12 binding to blood ACE detects a subpopulation of ESRD patients with conformationally changed ACE, which activity is less suppressible by ACE inhibitors. This parameter may potentially serve as a biomarker for those patients who may need higher concentrations of ACE inhibitors upon anti-hypertensive therapy.     

Angiotensin converting enzyme (kininase II). Molecular and physiological aspects]

The angiotensin I-converting enzyme (kininase II, ECA) is a membrane bound enzyme anchored to the cell membrane through a single transmembrane domain located near its carboxyterminal extremity. Secretion of ACE by the cell occurs most likely as a result of a posttranslational cleavage of the membrane anchor and intracellular region. The ACE molecule is organized into two large highly homologous domains, each bearing consensus sequences for zinc binding in metallopeptidases. Site directed mutagenesis allowed to establish that both domains bear in fact a functional active site, able to convert angiotensin I into angiotensin II and to hydrolyze bradykinin or substance P. The two active sites of ACE, however, do not display the same sensitivity to anion activation (the C terminal active site being more chloride activatable) and also differs in kinetic parameters for peptide hydrolysis. The C terminal active site can hydrolyze faster angiotensin I and substance P and the N terminal active site is able to perform a peculiar endoproteolytic cleavage of an in vitro substrate of ACE, the luteinizing hormone releasing hormone. Both active sites bind with a high affinity, competitive inhibitors but the Kd of the reaction can vary up to 10 between the two active sites. All together, these observations suggest that ACE contains two active sites, whose structure is not exactly identical. They may have a different substrate specificity, however this remains speculative at the present time. Concerning the regulation of ACE gene expression in man, population studies indicated that the large interindividual variability in plasma ACE levels is genetically determined. An insertion/deletion polymorphism located in an intron of ACE gene is associated with differences in the level of ACE in plasma and cells. The physiological and clinical implications of these observations is discussed.