Novel substrates for angiotensin I converting enzyme

Homogenous human angiotensin converting enzyme (EC 3.4.15.1) cleaves dipeptides from the C-terminus of substrates containing a free carboxyl group. In this study we demonstrate that peptides containing a C-terminal nitrobenzylamine are also cleaved by the enzyme. The hydrolysis of these substrates is inhibited by the specific converting enzyme inhibitors captopril and MK421 as well as by anti-converting enzyme antibody. Sodium chloride accelerates the rate of hydrolysis forty-fold. The product of the reaction, an amino acid nitrobenzylamide, was identified by thin layer chromatography and high performance liquid chromatography. These results suggest that the carboxyl group is not an absolute requirement for substrate hydrolysis.     

Activation/inactivation of human angiotensin I converting enzyme following chemical modifications of amino groups near the active site

We have studied the effects of amidination of lysyl residues on the activity of angiotensin I converting enzyme isolated from human kidney. Anion concentration was an important reaction variable. In 4 M chloride or acetate, amidination with methyl acetimidate produced derivatives with up to a 4-fold increase in activity with hippuryl-glycyl-glycine as substrate. Modification with methyl p-hydroxybenzimidate also increased activity while treatment with methyl 4-mercaptobutyrimidate resulted in a 90% loss of activity. The effects of amidination were partially prevented when the reactions were carried out in the presence of the inhibitors, captopril or 5S-benzamido-4-oxo-6-phenyl-hexanoyl-L-proline. These results suggest that lysyl residues are present near the active site while different amino groups have a role in anion activation.     

Purification of angiotensin I converting enzyme from pig lung using concanavalin-A sepharose chromatography

Angiotensin I converting enzyme (ACE) plays a major role in blood pressure regulation, catalyzing the conversion of angiotensin I to the vasoconstrictor angiotensin II. In this report we describe a two-step affinity chromatography method for preparative purification of ACE from pig lung using Concanavalin-A Sepharose 4B and affinity chromatography on Lisinopril Sepharose 6B. The same purification scheme was used to obtain Cobalt-ACE, where zinc ion located at the active site is replaced by cobalt. Cobalt-ACE visible spectrum shows a characteristic broad peak from 500 to 600 nm. The shape and maximum absorptivity of this peak changes in presence of ACE inhibitors that bind at the catalytic site.     

Purification and characterization of angiotensin I converting enzyme inhibitory peptides from the rotifer, Brachionus rotundiformis

Angiotensin I converting enzyme (ACE) inhibitory peptide was isolated from the marine rotifer, Brachionus rotundiformis. ACE inhibitory peptides were separated from rotifer hydrolysate prepared by Alcalase, α-chymotrypsin, Neutrase, papain, and trypsin. The Alcalase hydrolysate had the highest ACE inhibitory activity compared to the other hydrolysates. The IC₅₀ value of Alcalase hydrolysate for ACE inhibitory activity was 0.63 mg/ml. We attempted to isolate ACE inhibitory peptides from Alcalase prepared rotifer hydrolysate using gel filtration on a Sephadex G-25 column and high performance liquid chromatography on an ODS column. The IC₅₀ value of purified ACE inhibitory peptide was 9.64 μM, and Lineweaver–Burk plots suggest that the peptide purified from rotifer protein acts as a competitive inhibitor against ACE. Amino acid sequence of the peptide was identified as Asp-Asp-Thr-Gly-His-Asp-Phe-Glu-Asp-Thr-Gly-Glu-Ala-Met, with a molecular weight 1538 Da. The results of this study suggest that peptides derived from rotifers may be beneficial as anti-hypertension compounds in functional foods resource.     

Induction of angiotensin converting enzyme in human monocytes in culture.

Angiotensin converting enzyme (E.C.3.4.15.1, peptidyl dipeptidase) in circulating human monocytes rose from undetectable or minimal levels $\text{in}\text{vivo}$ to as high as 35.5 nmol/min·mgprotein (>300-fold increase) after 6 or 7 days in culture. Enzyme induction was enhanced by autologous serum and exposure for two days to 0.45 μM dexamethasone. Potent inhibition of enzyme induction by 370 μg/ml of actinomycin D and 1 μM cycloheximide suggested that new messenger RNA and enzyme biosynthesis are involved in the induction. Human monocyte and lung enzyme were similar with respect to EDTA inhibition, CoCl₂ activation and inhibition by an antienzyme antiserum. Human lymphocytes had minimal or undetectable enzyme which was not induced after 4 days in culture.     

A peptide from corn gluten hydrolysate that is inhibitory toward angiotensin I converting enzyme

A peptide (F ₄) that inhibits angiotensin I converting enzyme (ACE) was isolated from corn gluten hydrolysate prepared with Pescalase, a serine protease from Bacillus licheniformis. The N-terminal amino acid sequence of F ₄ was Pro-Ser-Gly-Gln-Tyr-Tyr, having the IC₅₀ value of 0.1 mM. The peptide (F ₄), at 30 mg kg^–1 body weight of rat, antagonized the rat's pressor response to angiotensin I.     

Structure and physiological importance of angiotensin converting enzyme domains

Somatic angiotensin converting enzyme (ACE) consists of two homologous catalytic domains (N- and C-domain), exhibiting different biochemical properties. The catalytically active ACE isoforms consisted of just one domain have been also detected in mammals. Substantial progress in ACE domain research was achieved during the last years, when their crystal structures were determined. The crystal structures of domains in complex with diverse potent ACE inhibitors provided new insights into structure-based differences of the domain active sites. Physiological functions of ACE are not limited by regulation of the cardiovascular system. Recent evidence suggests that the ACE domains may be also involved into control of different physiological functions. The C-terminal catalytic domain plays an important role in the regulation of blood pressure: it catalyzes angiotensin I cleavage in vivo. The N-domain contributes to the processing of other bioactive peptides for which it exhibits high affinity. The role of the N-domain is not ultimately associated with functioning of the rennin-angiotensin system and it contributes processing of other bioactive peptides for which it exhibits high affinity (goralatide, luliberin, enkephalin heptapeptide, beta-amyloid peptide). Domain-selective inhibitors selectively blocking either the N- or C-domain of ACE have been developed.     

Downregulation of angiotensin converting enzyme II is associated with pacing-induced sustained atrial fibrillation

Atrial fibrillation (AF), the most common cardiac arrhythmia, is frequently accompanied by atrial interstitial fibrosis. Angiotensin II (Ang II) dependent signaling pathways have been implicated in interstitial fibrosis during the development of AF. However, Ang II could be further degraded by angiotensin converting enzyme II (ACE2). We examined expression of ACE2 in the fibrillating atria of pigs and its involvement in fibrotic pathogenesis during AF. Nine adult pigs underwent continuous rapid atrial pacing to induce sustained AF and six pigs were sham controls (i.e., sinus rhythm; SR). In the histological examinations, extensive accumulation of extracellular matrix in the interstitial space of the atria, as evidenced by Masson's trichrome stain, were found in fibrillating atria. The relative amount of collagen type I in the atria with AF was significantly increased as compared with that in the SR. Local ACE activity in the fibrillating atria was also markedly higher than that in the SR subjects. ACE2 gene and protein expression in the AF subjects were significantly decreased compared with those in the SR subjects, whereas expression of mitogen-activated/ERK kinase 1/2 (MEK1/2), extracellular signal-regulated protein kinase 2 (ERK2), and activated ERK2 were significantly greater in the AF subjects. We propose that decreasing ACE2 expression during AF may affect the Ang II-dependent signaling pathway. In addition, our results suggest that atrial fibrosis in AF may be induced by antagonistic regulation between ACE and ACE2 expression.     

人源血管紧张素转化酶-C结构域在毕赤酵母中的表达

血管紧张素转化酶 (ACE,EC3.4.15.1) 在调节血压方面具有重要作用,研究证实,ACE-C结构域是体内使血管紧张素I (AngI) 分解的主要活性位点。PCR扩增ACE-C结构域基因片段,克隆至分泌表达载体pPIC9K,转化毕赤酵母GS115,阳性克隆再次电转,用G418筛选高拷贝的酵母菌落进行表达条件优化,获得0.5 g/L的蛋白表达量及7.178 U/mL的酶活力。经Ni+亲和层析纯化,获得纯度大于97％的目的蛋白。Captopril对酶的抑制试验证明ACE-C结构域可望成为新一代抗高血压药物ACE抑制剂筛选的理想酶靶。     

Joseph Rudinger memorial lecture: Unexpected functions of angiotensin converting enzyme,beyond its enzymatic activity

Angiotensin converting enzyme (ACE) is a well‐known enzyme, largely studied for its action on hypertension, as it produces angiotensin II from angiotensin I. This paper describes two original behaviours of ACE. We showed that ACE could hydrolyse gastrin, a neuropeptide from the gastrointestinal tract, releasing the C‐terminal amidated dipeptide H‐Asp‐Phe‐NH₂. This dipeptide is believed to be involved in the gastrin‐induced acid secretion in the stomach. This hypothetic mechanism of action of gastrin resulted in a strategy to rationally design gastrin receptor antagonists. Beyond, we showed that the brain renin angiotensin system (RAS) could be activated by a new characterized peptide named acein, resulting in stimulation of dopamine release within the striatum. This new and original ‘receptor‐like’ activity for brain membrane‐bound ACE is quite significant taking into account the role of dopamine in the brain, particularly in neurodegenerative diseases. Copyright © 2017 European Peptide Society and John Wiley & Sons, Ltd.     

内蒙古地区达斡尔族血管紧张素转换酶基因多态性分布

目的:研究内蒙古地区达斡尔族血管紧张素转换酶基因(ACE)多态性分布。方法:采用聚合酶链反应检测198例北方汉族和198例达斡尔族中血管紧张素转换酶基因插入/缺失(I/D)多态性分布。结果:ACE基因多态性,达斡尔族人群ID、DD基因频率高于北方汉族,II基因频率低于北方汉族,二组间比较均存在明显差异(P<0.05)。结论:北方汉族与达斡尔族间ACE基因多态性和等位基因频率分布存在差异。     

Epitope mapping of novel monoclonal antibodies to human angiotensin I‐converting enzyme

Angiotensin I‐converting enzyme (ACE, CD143) plays a crucial role in blood pressure regulation, vascular remodeling, and immunity. A wide spectrum of mAbs to different epitopes on the N and C domains of human ACE have been generated and used to study different aspects of ACE biology, including establishing a novel approach–conformational fingerprinting. Here we characterized a novel set of 14 mAbs, developed against human seminal fluid ACE. The epitopes for these novel mAbs were defined using recombinant ACE constructs with truncated N and C domains, species cross‐reactivity, ACE mutagenesis, and competition with the previously mapped anti‐ACE mAbs. Nine mAbs recognized regions on the N domain, and 5 mAbs–on the C domain of ACE. The epitopes for most of these novel mAbs partially overlap with epitopes mapped onto ACE by the previously generated mAbs, whereas mAb 8H1 recognized yet unmapped region on the C domain where three ACE mutations associated with Alzheimer''s disease are localized and is a marker for ACE mutation T877M. mAb 2H4 could be considered as a specific marker for ACE in dendritic cells. This novel set of mAbs can identify even subtle changes in human ACE conformation caused by tissue‐specific glycosylation of ACE or mutations, and can detect human somatic and testicular ACE in biological fluids and tissues. Furthermore, the high reactivity of these novel mAbs provides an opportunity to study changes in the pattern of ACE expression or glycosylation in different tissues, cells, and diseases, such as sarcoidosis and Alzheimer''s disease.     

Ouabain-insensitivity of highly active Na+, K+-dependent adenosinetriphosphatase from rat kidney.

Highly purified preparations of Na⁺+K⁺-dependent adenosinetriphosphatase were isolated from rat kidney by two different procedures. The I₅₀ values for ouabain inhibition of the rat kidney enzyme at various stages of purification were determined to be essentially the same for all fractions tested (0.7 to 1.0 × 10^?4M). These results suggest that the marked insensitivity of the rat enzyme to inhibition by cardiac glycosides is due to the primary structure of the enzyme, and not to some other component in the tissue.     

Intestinal intraepithelial lymphocyte derived angiotensin converting enzyme modulates epithelial cell apoptosis

Background & Aims: Intestinal adaptation in short bowel syndrome (SBS) consists of increased epithelial cell (EC) proliferation as well as apoptosis. Previous microarray analyses of intraepithelial lymphocytes (IEL) gene expression after SBS showed an increased expression of angiotensin converting enzyme (ACE). Because ACE has been shown to promote alveolar EC apoptosis, we examined if IEL-derived ACE plays a role in intestinal EC apoptosis. Methods: Mice underwent either a 70% mid-intestinal resection (SBS group) or a transection (Sham group) and were studied at 7 days. ACE expression was measured, and ACE inhibition (ACE-I, enalaprilat) was used to assess ACE function. Results: IEL-derived ACE was significantly elevated in SBS mice. The addition of an ACE-I to SBS mice resulted in a significant decline in EC apoptosis. To address a possible mechanism, tumor necrosis factor alpha (TNF-α) mRNA expression was measured. TNF-α was significantly increased in SBS mice, and decreased with ACE-I. Interestingly, ACE-I was not able to decrease EC apoptosis in TNF-α knockout mice. Conclusions: This study shows a previously undescribed expression of ACE by IEL. SBS was associated with an increase in IEL-derived ACE. ACE appears to be associated with an up-regulation of intestinal EC apoptosis. ACE-I significantly decreased EC apoptosis.     

Characteristics of monoclonal antibody binding with the <Emphasis Type="Italic">C</Emphasis> domain of human angiotensin converting enzyme

Binding of a panel of eight monoclonal antibodies (mAbs) with the C domain of angiotensin converting enzyme (ACE) to human testicular ACE (tACE) (corresponding to the C domain of the somatic enzyme) was studied, and the inhibition of the enzyme by the mAb 4A3 was found. The dissociation constants of complexes of two mAbs, 1B8 and 2H9, with tACE were 2.3 ± 0.4 and 2.5 ± 0.4 nM, respectively, for recombinant tACE and 4.7 ± 0.5 and 1.6 ± 0.3 nM for spermatozoid tACE. Competition parameters of mAb binding with tACE were obtained and analyzed. As a result, the eight mAbs were divided into three groups, whose binding epitopes did not overlap: (1) 1E10, 2B11, 2H9, 3F11, and 4E3; (2) 1B8 and 3F10; and (3) 1B3. A diagram demonstrating mAb competitive binding with tACE was proposed. Comparative analysis of mAb binding to human and chimpanzee ACE was carried out, which resulted in revealing of two amino acid residues, Lys677 and Pro730, responsible for binding of three antibodies, 1E10, 1B8, and 3F10. It was found by mutation of Asp616 located close to Lys677 for Leu that the mAb binding epitope 1E10 contains Asp616 and Lys677, whereas mAbs 1B8 and 3F10 contain Pro730.     

Expression, purification, and physicochemical characterization of the N-terminal active site of human angiotensin-I converting enzyme.

We have cloned, over expressed, and purified one of the two catalytic domains (residues Ala361 to Gly468, ACE-N) of human somatic angiotensin-I converting enzyme in Escherichia coli. This construct represents the N-catalytic domain including the two binding motifs and the 23 amino acid spacers as well as some amino acid residues before and after the motifs that might help in correct conformation. The overexpressed protein was exclusively localized to insoluble inclusion bodies. Inclusion bodies were solubilized in an 8-M urea buffer. Purification was carried out by differential centrifugation and gel filtration chromatography under denaturing conditions. About 12 mg of ACE-N peptide per liter of bacterial culture was obtained. The integrity of recombinant protein domain was confirmed by ESI/MS. Structural analysis using CD spectroscopy has shown that, in the presence of TFE, the ACE-N protein fragment has taken a conformation, which is consistent with the one found in testis ACE by X-ray crystallography. This purification procedure enables the production of an isotopically labeled protein fragment for structural studying in solution by NMR spectroscopy.     

Composition of a Photosystem I chlorophyll protein complex from Anabaena flos-aquae

The use of Triton X-100 to solubilize membrane fragments from Anabaena flos-aquae in conjunction with DEAE cellulose chromatography allows the separation of three green fractions. Fraction 1 is detergent-solubilized chlorophyll, and Fraction 2 contains one polypeptide in the 15 kdalton area. Fraction 3, which contains most of the chlorophyll and shows P-700 and photosystem I activity, shows by SDS gel electrophoresis varying polypeptide profiles which reflect the presence of four fundamental bands as well as varying amounts of other polypeptides which appear to be aggregates containing the 15 kdalton polypeptide. The four fundamental bands are designated Band I at 120, Band II at 52, Band III at 46, and Band IV at 15 kdaltons. Band I obtained using 0.1% SDS contains chlorophyll and P-700 associated with it. When this band is cut out and rerun, the 120 kdalton band is lost, but significant increases occur in the intensities of Bands II, III, and IV as well as other polypeptides in the 20–30 kdalton range.The use of 1% Triton X-100 coupled with sucrose density gradient centrifugation allows the separation of three green bands at 10, 25 and 40% sucrose. The 10% layer contains a major polypeptide which appears to be Band IV. The 25 and 40% layers show essentially similar polypeptide profiles, resembling Fraction 3 in this regard, except that the 40% layer shows a marked decrease in Band III. Treatment of the material layering at the 40% sucrose level with a higher (4%) concentration of Triton X-100 causes a loss (disaggregation) of the polypeptides occurring in the 60–80 kdalton region and an increase in the lower molecular weight polypeptides. Thus, aggregation of the lower molecular weight polypeptides accounts for the variability seen in the electrophoresis patterns. Possible relations of the principal polypeptides to the known photochemical functions in the original membrane are discussed.     

Isolation and characterization of a protein with homology to angiotensin converting enzyme from the periacrosomal plasma membrane of equine spermatozoa

The periacrosomal plasma membrane of spermatozoa is involved in sperm binding to oviductal epithelial cells and to the zona pellucida. A protein of 68–70 kD molecular mass was purified biochemically from the isolated periacrosomal plasma membrane of equine spermatozoa as a possible receptor for adhesion of spermatozoa to oviductal epithelial cells. A polyclonal antibody raised in rabbits against the purified equine sperm membrane protein recognized the 70 kD and an antigenically related 32 kD protein in preparations of isolated periacrosomal sperm plasma membrane and in detergent extracted ejaculated and epididymal spermatozoa. A larger protein (∼110 kD) was detected in equine testis. Two antigenically related proteins (64 and 45 kD) were recognized on the plasma membrane of cynomolgus macaque spermatozoa. In vitro sperm-binding assays were performed in the presence of antigen-binding fragments or IgG purified from the polyclonal antiserum to investigate a possible function of the isolated protein in binding of equine spermatozoa to homologous oviductal epithelial cells or zona pellucida. Incubation with antigen-binding fragments or IgG purified from the antiserum did not inhibit binding of equine spermatozoa either to oviductal epithelial cells or to the zona pellucida. On ultrastructural examination, the antibody bound exclusively to the cytoplasmic side of the periacrosomal plasma membrane of equine and macaque spermatozoa. Microsequence analysis of 13 residues of sequence showed strong homology with a number of angiotensin converting enzymes: An 84% identity was identified with testis specific and somatic forms of human and mouse angiotensin-converting enzyme. Immunocytochemistry and immunoblot analysis established that the protein is specific for the periacrosomal membrane of ejaculated, epididymal, and testicular stallion spermatozoa. Mol. Reprod. Dev. 48:251–260, 1997. © 1997 Wiley-Liss, Inc.     

A monoclonal antibody to human insulin receptor

A murine hybridoma secreting antibody against human insulin receptor was produced by fusing FO myeloma cells with spleen and lymph node cells from a mouse that had been immunized with insulin receptor purified from human placenta. The secreted antibody was an IgG₁ (κ), designated αIR-1. Like the previously described rabbit polyclonal antibody, αIR-1 did not inhibit insulin binding. It specifically immunoprecipitated ¹²⁵I-insulin-receptor complexes as well as unoccupied receptor previously labeled directly with lactoperoxidase. Thus, αIR-1 interacts with the receptor at a site distinct from the insulin binding site. Unlike previously described anti-insulin receptor antibodies, αIR-1 exhibits strong tissue and species specificity.