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.     

Purification of bovine angiotensin converting enzyme

A change has been made in the commonly used lisinopril affinity gel procedure for purifying angiotensin converting enzyme. The new method greatly decreases the time required and greatly increases the yield of pure enzyme. All of the enzyme in various bovine tissues was extracted with 0.5% triton X-100 and applied to the affinity column; 70% was trapped and all of the trapped enzyme was released as the apoenzyme by EDTA. The holoenzyme was recovered by dialysis against zinc containing buffer. The turnover numbers were precisely the same for enzyme from lung, atrium, kidney, striatum and blood. The tissue concentrations of ACE were very different but the final specific activities were the same.     

Triiodothyronine increases serum angiotensin converting enzyme

To determine whether elevated thyroid hormone is responsible for increased serum angiotensin converting enzyme in hyperthyroidism, 5 to 40 micrograms of 3,5,3'-triiodo-L-thyronine was administered orally and subcutaneously to female Swiss-Webster mice. Serum angiotensin converting enzyme was significantly increased in all animals given triiodothyronine compared to controls. Lung and kidney enzymes were moderately reduced in specific activity but unchanged in total activity due to increase in size of these organs. The results indicate that in hyperthyroidism, elevated thyroid hormone per se rather than the disease of the thyroid is responsible for elevated serum angiotensin converting enzyme.     

The angiotensin I converting enzyme.

The angiotensin I converting enzyme (kininase II; peptidyl dipeptidase; EC3.4.15.1) has a dual function: it converts angiotensin I to angiotensin II and it inactivates bradykinin. Lung, kidney, guinea pig plasma and testicles are among the richest sources of the enzyme. Vascular endothelial cells and bursh borders of renal proximal tubular cells contain high concentrations of the enzyme. The availability of synthetic peptide inhibitors was a great help in establishing the function of converting enzyme in normal and pathological conditions.     

Spontaneous change of human plasma angiotensin I converting enzyme isoelectric point

The isoelectric point of angiotensin I converting enzyme (ACE) spontaneously changes from 4.3 to 4.6 during purification from human plasma. The spontaneous change in pI corresponds to that occurring with neuraminidase-treated but not with EDTA-treated samples. There is no detectable difference in the molecular weight of, or lectin binding by, the two forms of ACE with different pI's. These data indicate that ACE in the circulation contains a greater amount of sialic acid than purified ACE. The implication is that purified ACE isoenzymes which differ in sialic acid content may not reflect tissue-specific isoenzymes but rather artifacts of purification.     

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.     

Purification of human kidney angiotensin I converting enzyme using reverse-immunoadsorption chromatography

A rapid and highly efficient procedure for purification of angiotensin I converting enzyme from human kidney has been developed. Following tryptic solubilization, the enzyme was partially purified by DEAE-cellulose and hydroxylapatite chromatography. The final step consisted of “reverse immunoadsorption” on a column prepared by coupling antisera raised against contaminating proteins to CNBr-activated Sepharose CL-6B. Starting with 600 g kidney tissue, 6.1 mg of enzyme was obtained with a specific activity of 108 U/mg using Hip-His-Leu as substrate, a 3400-fold purification with an overall yield of 26%. The preparation gave a single band on 7.5% SDS-urea gels and a single arc against antisera to impure enzyme in crossed immunoelectrophoresis. A single N-terminal amino acid (leucine) was detected by dansylation. This procedure has allowed the initiation of structural studies with the human enzyme. “Reverse immunoadsorption” may be a generally useful method for protein purification.     

Molecular heterogeneity of angiotensin converting enzyme in human cerebrospinal fluid.

Three different molecular forms of angiotensin converting enzyme (ACE) (approximately Mr 150,000, 80,000 and 40,000, respectively), have been recovered from human cerebrospinal fluid. All three enzymes were inhibited by captopril and enalapril and their activity was potentiated by chloride ions. They were capable of degrading Leu-enkephalin-Arg6 and substance -P, but gave no conversion of neurokinin A. In all these aspects, the CSF enzymes were identical with the human pulmonary enzyme. The Mr 40,000 form of ACE is the smallest active form of the enzyme hitherto reported and is likely to represent a fragment of the C-terminal part of native ACE, where its active center is located.     

Downregulation of angiotensin converting enzyme by TNF-alpha in differentiating human macrophages

OBJECTIVE: To investigate regulation of angiotensin converting enzyme (ACE) by tumour necrosis factor alpha (TNF-alpha) in differentiating human peripheral blood monocytes (PBM). METHODS: Human PBM were allowed to differentiate to macrophages for 0-7 days and ACE amount was measured during differentiation. Experiments with TNF-alpha were performed after 2 days of differentiation. Cell cultures were incubated with TNF-alpha (0.5-10ng/ml) without or with SB 202190 (5microM), or PD 98059 (40microM). ACE amounts were measured by an inhibitor binding assay (IBA) and ACE mRNA levels by RNase protection assay (RPA). Activated p44/42 and p38 MAP kinases were measured by Western Blot analysis using phospho-p44/42 and -p38 MAPK antibodies. RESULTS: ACE amount increased by 40-fold along with macrophage differentiation. TNF-alpha caused dose dependent suppression of the amount of ACE and decreased levels of ACE mRNA. TNF-alpha activated p44/42 and p38 MAP kinases, which was inhibited by the specific inhibitors of these kinases, PD98059 or SB202190, respectively. Pretreatment of the cells with SB 202190, or PD 98059 both partly reversed TNF-alpha induced ACE suppression. CONCLUSIONS: TNF-alpha downregulated ACE, which effect was probably mediated by both p44/42 and p38 MAPK pathways. Local downregulation of ACE by TNF-alpha may be a counterbalancing mechanism in inflammatory processes.     

Renin, kallikrein and angiotensin converting enzyme in human physical loading

The authors studied the correlation between the activity of renin, angiotensin-converting enzyme, the activity of prekallikrein and the blood prekallikrein level in men performing veloergometric exercise. At the same time they recorded the hemodynamic parameters (systolic and diastolic arterial pressure, the systolic rate, stroke volume and cardiac index, specific peripheral resistance). The blood samples collected before and immediately after the exercise showed a 41.4%-increase in the activity of renin and a 95%-increase in that of kallikrein, whereas the level of prekallikrein and the activity of the converting enzyme declined by 19 and 13% (P less than 0.05). These changes were accompanied by an increase in the systolic rate (by 107%) and in the systolic arterial pressure (by 36.7%), as well as by a reduction of the specific peripheral resistance (by 41.4%).     

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.     

Metabolism and subcellular localization of angiotensin converting enzyme in cultured human monocytes

The enhancement of monocyte ACE activity during culture by autologous T-lymphocytes was shown to be due to a stimulation of the rate of ACE synthesis. The rate of synthesis increased from 0.020 mU/10(6) monocytes/hr in monocytes cultured alone to 0.063 mU/10(6) monocytes/hr in monocytes co-cultured with T-lymphocytes. The presence of T-lymphocytes during culture did not alter the rate of ACE degradation observed in monocytes cultured alone. The ACE induced in monocytes by T-lymphocytes appears to be an ecto-enzyme. Brief exposure to diazosulfanilic acid (10(-3) M) and papain (250 micrograms/ml) reduced ACE activity 89% and 66%, respectively, without appreciably altering the activity of the cytosolic enzyme, lactate dehydrogenase.     

Assays for angiotensin converting enzyme inhibitory activity

A colorimetric method and a capillary electrophoresis procedure were developed for quantifying histidyl-leucine and hippurate, respectively. The colorimetric method is sensitive (extinction coefficient = 7.5 mM(-1) cm(-1)) and reproducible (CV = 1.7%, n = 5), which is based on a selective chromogenic reaction for histidyl-leucine (lambda(max) = 390 nm) using o-phthalaldehyde. For samples containing unusually high levels of histidine and/or histidyl peptides, the separation-based approach is preferable. The capillary electrophoresis method makes use of an in-capillary microextraction technique; complicated samples can be measured in less than 4 min without pretreatment. Protocols using both methods to measure angiotensin converting enzyme inhibitory activity were proposed.     

Characteristics of monoclonal antibody binding with the C 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 4E3 was found. The dissociation constants of complexes of two mAbs, IB8 and 2H9, with tACE were 2.3 +/- 0.4 and 2.5 +/- 0.4 nM, respectively, for recombinant tACE 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) IB3. 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 that the mAb binding epitope 1E10 contains Asp616 and Lys677, whereas mAbs 1B8 and 3F10 contain Pro730.     

Inactivation of angiotensin converting enzyme by sodium nitroprusside

Angiotensin I converting enzyme is rapidly inactivated by sodium nitroprusside and that inactivation is suppressed in the presence of chloride ion and by the presence of L-alanyl-L-proline or glycyl-L-tryptophan, which are both competitive inhibitors of its catalytic activity. The inactivation by sodium nitroprusside appears to result from the modification of an unusually reactive lysine residue in or near the active site.     

Esterase activity of rabbit pulmonary angiotensin converting enzyme

A series of depsipeptides have been synthesized and used to demonstrate the esterase activity of rabbit pulmonary angiotensin converting enzyme. Among the esters studied, Bz-Phe-OPhe-Ala was found to have the highest $\text{k}{}_{\mathrm{cat}}\text{K}{}_{\mathrm{m}}$ which is about $\text{1}\text{5}$ that of its exact peptide analog, Bz-Phe-Phe-Ala. Esters such as Bz-Gly-OGly-Phe, Bz-Gly-OPhe-Phe and Bz-Gly-OLeu-Ala were also hydrolyzed but at much lower rates. Normal Michaelis-Menten behavior is observed and the kinetic parameters obtained indicate that the esters and their peptide analogs bind to the enzyme equally well, but that peptides are hydrolyzed at much higher rates. Studies on the pH-rate profiles, chloride ion effect, inhibition and chemical modifications detect no mechanistic differences between ester and peptide hydrolysis.