Domain Of Angiotensin-converting Enzyme Research Articles

Aβ42-to-Aβ40- and Angiotensin-converting Activities in Different Domains of Angiotensin-converting Enzyme

Amyloid beta-protein 1-42 (Abeta42) is believed to play a causative role in the development of Alzheimer disease (AD), although it is a minor part of Abeta. In contrast, Abeta40 is the predominant secreted form of Abeta and recent studies have suggested that Abeta40 has neuroprotective effects and inhibits amyloid deposition. We have reported that angiotensin-converting enzyme (ACE) converts Abeta42 to Abeta40, and its inhibition enhances brain Abeta42 deposition (Zou, K., Yamaguchi, H., Akatsu, H., Sakamoto, T., Ko, M., Mizoguchi, K., Gong, J. S., Yu, W., Yamamoto, T., Kosaka, K., Yanagisawa, K., and Michikawa, M. (2007) J. Neurosci. 27, 8628-8635). ACE has two homologous domains, each having a functional active site. In the present study, we identified the domain of ACE, which is responsible for converting Abeta42 to Abeta40. Interestingly, Abeta42-to-Abeta40-converting activity is solely found in the N-domain of ACE and the angiotensin-converting activity is found predominantly in the C-domain of ACE. We also found that the N-linked glycosylation is essential for both Abeta42-to-Abeta40- and angiotensin-converting activities and that unglycosylated ACE rapidly degraded. The domain-specific converting activity of ACE suggests that ACE inhibitors could be designed to specifically target the angiotensin-converting C-domain, without inhibiting the Abeta42-to-Abeta40-converting activity of ACE or increasing neurotoxic Abeta42.

Structure and physiological importance of angiotensin converting enzyme domains

Somatic angiotensin converting enzyme (ACE) consists of two homologous catalytic domains (N- and C-domain), each of which bears an active site exhibiting different biochemical properties. The ACE isoforms consisted of one domain were also detected in mammals. Substantial progress in ACE domain research was achieved during the last years, when crystal their 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 distinct physiological functions. The C-terminal catalytic domain, playing important role in regulation of blood pressure, catalyzes angiotensin I cleavage in vivo. The N-domain contributes to processing of other bioactive peptides for which it exhibits high affinity. Domain-selective inhibitors able to block selectively either the N- or C-domain of ACE have been developed.

Investigating the Domain Specificity of Phosphinic Inhibitors RXPA380 and RXP407 in Angiotensin-Converting Enzyme

Human somatic angiotensin-converting enzyme (ACE) is a membrane-bound dipeptidyl carboxypeptidase that contains two extracellular domains (N and C). Although highly homologous, they exhibit different substrate and inhibition profiles. The phosphinic inhibitors RXPA380 and RXP407 are highly selective for the C- and N-domains, respectively. A number of residues, implicated by structural data, are likely to contribute to this selectivity. However, the extent to which these different interactions are responsible for domain selectivity is unclear. In this study, a series of C- and N-domain mutants containing conversions to corresponding domain residues were used to scrutinize the contribution of these residues to selective inhibitor binding. Enzyme kinetic analyses of the purified mutants indicated that the RXPA380 C-selectivity is particularly reliant on the interaction between the P2 substituent and Phe 391 (testis ACE numbering). Moreover, a C-domain mutant in which Phe 391 has been changed to a Tyr residue, in addition to containing an N-domain S2' pocket (S2'F/Y), displayed the greatest shift toward a more N-domain-like Ki. None of the single mutations within the N-domain caused a large shift in RXP407's affinity for these enzymes. However, the double mutant containing the Tyr 369 to Phe change as well as Arg 381 to Glu displayed a 100-fold decrease in binding affinity, confirming that the S2 pocket plays a major role in RXP407 selectivity. Taken together, these data advance our understanding regarding the molecular basis for the remarkable ACE domain selectivity exhibited by these inhibitors.

The lactotripeptides isoleucine-proline-proline and valine-proline-proline do not inhibit the N-terminal or C-terminal angiotensin converting enzyme active sites in humans

The potential blood pressure lowering effect of fermented milk may involve inhibition of angiotensin-converting enzyme (ACE) by dairy lactotripeptides generated during milk fermentation, such as isoleucine-proline-proline (IPP) and valine-proline-proline (VPP). These peptides are weak ACE inhibitors in vitro but it remains unclear whether they inhibit ACE in vivo in humans. To assess in vivo ACE inhibition in individuals given fermented milk over a 7-day period. Twelve healthy normotensive men were given 330 ml of fermented milk once daily from day 1 to day 7 (IPP: 4.5 mg and VPP: 6.6 mg) and a single dose of 50 mg captopril on day 8. ACE inhibition was assessed in vivo by measuring plasma and urine AcSDKP and plasma active renin and in vitro by measuring plasma ACE activity using hippuryl-histidine-leucine. Plasma IPP/VPP concentrations were measured by LC/MS/MS. Plasma IPP concentrations increased slightly and very transiently after fermented milk administration. Plasma VPP concentrations were below the limit of quantification. Fermented milk had no effect on plasma AcSDKP, ACE activity or active renin concentrations on days 1 or 7. Urine AcSDKP excretion underwent a small transient increase. In contrast, plasma and urine AcSDKP increased 7.7-fold and 70-fold, respectively, and plasma ACE activity decreased by 82.3 +/- 16.1% following captopril administration; plasma active renin concentration increased four-fold. IPP and VPP were poorly absorbed and rapidly eliminated. They did not inhibit plasma or endothelial ACE in vivo at the selected doses and had no specific effect on the N-terminal or C-terminal ACE domains.

Abeta42-to-abeta40- and angiotensin-converting activities in different domains of angiotensin-converting enzyme

Abeta42-to-abeta40- and angiotensin-converting activities in different domains of angiotensin-converting enzyme

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.

Combined use of selective inhibitors and fluorogenic substrates to study the specificity of somatic wild‐type angiotensin‐converting enzyme

Somatic angiotensin-converting enzyme (ACE) contains two homologous domains, each bearing a functional active site. Studies on the selectivity of these ACE domains towards either substrates or inhibitors have mostly relied on the use of mutants or isolated domains of ACE. To determine directly the selectivity properties of each ACE domain, working with wild-type enzyme, we developed an approach based on the combined use of N-domain-selective and C-domain-selective ACE inhibitors and fluorogenic substrates. With this approach, marked differences in substrate selectivity were revealed between rat, mouse and human somatic ACE. In particular, the fluorogenic substrate Mca-Ala-Ser-Asp-Lys-DpaOH was shown to be a strict N-domain-selective substrate of mouse ACE, whereas with rat ACE it displayed marked C-domain selectivity. Similar differences in selectivity between these ACE species were also observed with a new fluorogenic substrate of ACE, Mca-Arg-Pro-Pro-Gly-Phe-Ser-Pro-DpaOH. In support of these results, changes in amino-acid composition in the binding site of these three ACE species were pinpointed. Together these data demonstrate that the substrate selectivity of the N-domain and C-domain depends on the ACE species. These results raise concerns about the interpretation of functional studies performed in animals using N-domain and C-domain substrate selectivity data derived only from human ACE.

Calmodulin Binds to the Cytoplasmic Domain of Angiotensin-converting Enzyme and Regulates Its Phosphorylation and Cleavage Secretion

The rate of cleavage secretion of the enzymatically active ectodomain of angiotensin-converting enzyme (ACE) is regulated by tyrosine phosphorylation of the protein and by the phorbol ester, phorbol 12-myristate 13-acetate (PMA), an activator of protein kinase C. Here, we report that both calmodulin inhibitor (CaMI) and calmodulin kinase inhibitor could also enhance cleavage secretion of ACE. This effect was accompanied by the dissociation of calmodulin from a specific region within the cytoplasmic domain of ACE to which it had been bound. The same domain of ACE was phosphorylated, and both CaMI and PMA caused dephosphorylation of ACE as well. Mass spectrometric and mutational analyses identified Ser730 as the only phosphorylated residue in the cytoplasmic domain of ACE. The Ser730 --> Ala mutant of ACE was not phosphorylated, but it still bound calmodulin, and its cleavage secretion was enhanced by both CaMI and PMA. Similarly, when Ser730 was replaced by the phosphoserine mimetic, Asp, cleavage secretion of the resultant mutant remained susceptible to the enhancing effect of CaMI and PMA. These results demonstrate that, although CaMI and PMA can enhance both cleavage secretion of ACE and its dephosphorylation, the two effects are not mutually interdependent.

Signaling via the Angiotensin-Converting Enzyme Results in the Phosphorylation of the Nonmuscle Myosin Heavy Chain IIA

The phosphorylation of the short C-terminal cytoplasmic domain of the somatic angiotensin-converting enzyme (ACE) is involved in the regulation of enzyme shedding. We determined whether the phosphorylation of the cytoplasmic domain of ACE (ACEct) on Ser1270 regulates the cleavage/secretion of the enzyme by affecting its association with other proteins. ACE was associated with beta-actin and the nonmuscle myosin heavy chain IIA (MYH9) in endothelial cells, as determined by coimmunoprecipitation experiments as well as an ACEct affinity column. The ACE-associated MYH9 immunoprecipitated from (32)P-labeled endothelial cells was basally phosphorylated and cell stimulation with ACE inhibitors, or with bradykinin, increased the phosphorylation of MYH9. Casein kinase 2 (CK2) but not protein kinase C phosphorylated MYH9 in vitro, CK2 coprecipitated with MYH9 from endothelial cells and the phosphorylation of MYH9 in intact cells paralleled the phosphorylation of ACE on Ser1270 by CK2. The CK2 inhibitor 5,6-dichloro-1-beta-d-ribofuranosylbenzimidazole attenuated the phosphorylation of ACE and MYH9, disrupted their association, and enhanced the cleavage/secretion of ACE from the plasma membrane. Cytochalasin D decreased the interaction between ACE and MYH9 and stimulated ACE shedding. Although MYH9 was still able to associate with residual amounts of a nonphosphorylatable S1270A ACE mutant, no ACE inhibitor-induced increase in MYH9 phosphorylation could be detected in S1270A-expressing cells. These data indicate that the interaction of ACE with MYH9 determines ACE shedding and is modulated by phosphorylation processes. Furthermore, because ACE inhibitors affect the phosphorylation of MYH9, the phosphorylation of this class II myosin might contribute to the phenomenon of ACE signaling in endothelial cells.

The N‐terminal active centre of human angiotensin‐converting enzyme degrades Alzheimer amyloid β‐peptide

We reported recently that angiotensin-converting enzyme (ACE) significantly degraded amyloid beta-peptide (A beta) to inhibit aggregation and cytotoxicity of A beta in PC12h cells in vitro. On the other hand, others reported that ACE had two domains with highly homologous active centres, the N-domain and C-domain, but that they differed in their characteristics such as optimum chloride ion concentration, inhibition kinetics for various ACE inhibitors and rate of hydrolysis for many substrates. The aim of this study was to determine the specific ACE domain primarily responsible for degradation of A beta. For this purpose, a series of ACE recombinant proteins, each containing only one intact domain, was constructed and expressed in COS7. Our results showed that all ACE recombinant proteins obtained were enzymatically active in terms of angiotensin I cleavage. However, inhibition of A beta aggregation and cytotoxicity of the N-domain were higher than those of the C-domain. Reverse-phase high-performance liquid chromatography analyses confirmed that the N domain degraded A beta. Our results indicate that the N domain of ACE is primarily responsible for the degradation of A beta.

Role of Tyrosine Phosphorylation in the Regulation of Cleavage Secretion of Angiotensin-converting Enzyme

Both germinal (gACE) and somatic (sACE) isozymes of angiotensin-converting enzyme (ACE) are type I ectoproteins whose enzymatically active ectodomains are cleaved and shed by a membrane-bound protease. Here, we report a role of protein tyrosine phosphorylation in regulating this process. Strong enhancements of ACE cleavage secretion was observed upon enhancing protein Tyr phosphorylation by treating gACE- or sACE-expressing cells with pervanadate, an inhibitor of protein Tyr phosphatases. Secreted gACE, cell-bound mature gACE and its precursors were all Tyr-phosphorylated, as was the endoplasmic reticulum protein, immunoglobulin heavy chain-binding protein, that co-immunoprecipitated with ACE. The enhancement of cleavage secretion by pervanadate did not require the presence of the cytoplasmic domain of ACE, and it was not accomplished by enhancing the rate of intracellular processing of the protein. The observed enhancement of cleavage secretion of ACE in pervanadate-treated cells was specifically blocked by an inhibitor of the p38 mitogen-activated protein (MAP) kinase but not by inhibitors of many other Ser/Thr and Tyr protein kinases, including a specific inhibitor of protein kinase C that, however, could block the enhancement of cleavage secretion elicited by phorbol ester. These results indicate that ACE Tyr phosphorylation, probably in the endoplasmic reticulum, enhances the rate of its cleavage secretion at the plasma membrane using a regulatory pathway that may involve p38 MAP kinase.

Deletion of the cytoplasmic domain increases basal shedding of angiotensin-converting enzyme

Ectodomain shedding generates soluble isoforms of cell-surface proteins, including angiotensin-converting enzyme (ACE). Increasing evidence suggests that the juxtamembrane stalk of ACE, where proteolytic cleavage-release occurs, is not the major site of sheddase recognition. The role of the cytoplasmic domain has not been completely defined. We deleted the cytoplasmic domain of human testis ACE and found that this truncation mutant (ACE-ΔCYT) was shed constitutively from the surface of transfected CHO-K1 cells. Phorbol ester treatment produced only a slight increase in shedding of ACE-ΔCYT, unlike the marked stimulation seen with wild-type ACE. However, for both wild-type ACE and ACE-ΔCYT, shedding was inhibited by the peptide hydroxamate TAPI and the major cleavage site was identical, indicating the involvement of similar or identical sheddases. Cytochalasin D markedly increased the basal shedding of wild-type ACE but had little effect on the shedding of ACE-ΔCYT. These data suggest that the cytoplasmic domain of ACE interacts with the actin cytoskeleton and that this interaction is a negative regulator of ectodomain shedding.

Structure of human ACE gives new insights into inhibitor binding and design

Angiotensin-converting enzyme (ACE) is a primary target of drugs used for controlling hypertension. A new X-ray crystallographic structure of the key catalytic domain of ACE provides detailed information about the structure of its active site, located in a deep channel, and its interactions with an inhibitor. Such information might facilitate the rational design of ACE inhibitors that are more potent and more selective and therefore of clinical use.

Structure-functional features of homologous domains of angiotensin-converting enzyme

Somatic angiotensin-converting enzyme (ACE) consists of two homologous domains, each of them containing an active site. Differences in substrate specificities and affinity to inhibitors of the active sites of the two domains of bovine ACE are described. The ACE domains demonstrate different thermostability, and the reasons for this difference are analyzed. A structural model of the ACE domains is suggested, which allows us to reveal the structural subdomain important for the protein stability and localize the hydrophobic and the carbohydrate-binding sites.

Roles of the juxtamembrane and extracellular domains of angiotensin-converting enzyme in ectodomain shedding.

Angiotensin-converting enzyme (ACE) is one of a growing number of integral membrane proteins that is shed from the cell surface through proteolytic cleavage by a secretase. To investigate the requirements for ectodomain shedding, we replaced the glycosylphosphatidylinositol addition sequence in membrane dipeptidase (MDP) - a membrane protein that is not shed - with the juxtamembrane stalk, transmembrane (TM) and cytosolic domains of ACE. The resulting construct, MDP-STM(ACE), was targeted to the cell surface in a glycosylated and enzymically active form, and was shed into the medium. The site of cleavage in MDP-STM(ACE) was identified by MS as the Arg(374)-Ser(375) bond, corresponding to the Arg(1203)-Ser(1204) secretase cleavage site in somatic ACE. The release of MDP-STM(ACE) and ACE from the cells was inhibited in an identical manner by batimastat and two other hydroxamic acid-based zinc metallosecretase inhibitors. In contrast, a construct lacking the juxtamembrane stalk, MDP-TM(ACE), although expressed at the cell surface in an enzymically active form, was not shed, implying that the juxtamembrane stalk is the critical determinant of shedding. However, an additional construct, ACEDeltaC, in which the N-terminal domain of somatic ACE was fused to the stalk, TM and cytosolic domains, was also not shed, despite the presence of a cleavable stalk, implying that in contrast with the C-terminal domain, the N-terminal domain lacks a signal required for shedding. These data are discussed in the context of two classes of secretases that differ in their requirements for recognition of substrate proteins.

Roles of the juxtamembrane and extracellular domains of angiotensin-converting enzyme in ectodomain shedding

Angiotensin-converting enzyme (ACE) is one of a growing number of integral membrane proteins that is shed from the cell surface through proteolytic cleavage by a secretase. To investigate the requirements for ectodomain shedding, we replaced the glycosylphosphatidylinositol addition sequence in membrane dipeptidase (MDP) - a membrane protein that is not shed - with the juxtamembrane stalk, transmembrane (TM) and cytosolic domains of ACE. The resulting construct, MDP–STMACE, was targeted to the cell surface in a glycosylated and enzymically active form, and was shed into the medium. The site of cleavage in MDP–STMACE was identified by MS as the Arg374-Ser375 bond, corresponding to the Arg1203-Ser1204 secretase cleavage site in somatic ACE. The release of MDP–STMACE and ACE from the cells was inhibited in an identical manner by batimastat and two other hydroxamic acid-based zinc metallosecretase inhibitors. In contrast, a construct lacking the juxtamembrane stalk, MDP–TMACE, although expressed at the cell surface in an enzymically active form, was not shed, implying that the juxtamembrane stalk is the critical determinant of shedding. However, an additional construct, ACEΔC, in which the N-terminal domain of somatic ACE was fused to the stalk, TM and cytosolic domains, was also not shed, despite the presence of a cleavable stalk, implying that in contrast with the C-terminal domain, the N-terminal domain lacks a signal required for shedding. These data are discussed in the context of two classes of secretases that differ in their requirements for recognition of substrate proteins.

Specific Cellular Proteins Associate with Angiotensin-converting Enzyme and Regulate Its Intracellular Transport and Cleavage-Secretion

Angiotensin-converting enzyme (ACE) is an extensively glycosylated type I ectoprotein anchored in the plasma membrane by a hydrophobic transmembrane domain. In tissue culture as well as in vivo, the extracellular domain of ACE is released into the culture medium by a regulated proteolytic cleavage. To identify the cellular proteins that regulate ACE processing and cleavage-secretion, ACE-bound proteins were purified by affinity chromatography and characterized by microsequencing and Western blotting. One protein was identified as ribophorin and another as immunoglobulin-binding protein (BiP), a chaperone. Metabolic labeling and immunoprecipitation of ACE confirmed its interaction with BiP. Overexpression of BiP inhibited ACE secretion, an effect accentuated by the expression of an enzymatically inactive mutant BiP. This inhibition was caused by the retention of ACE precursors by BiP in the endoplasmic reticulum, as revealed by immunoprecipitation and immunofluorescence experiments. However, treatment with a phorbol ester, phorbol 12-myristate 13-acetate, enhanced ACE secretion even from cells overexpressing BiP. Western blot analysis of ACE-associated proteins with antibodies to protein kinase C (PKC) revealed the presence of its specific isozymes. Treatment with phorbol 12-myristate 13-acetate caused marked reduction in ACE association of selective PKC species. Thus, our studies have identified PKC and BiP as two proteins that directly interact with ACE and modulate its cell-surface expression and cleavage-secretion.

Glycosylation of bovine pulmonary angiotensin-converting enzyme modulates its catalytic properties

To study the role of the oligosaccharide moiety in the catalytic properties of angiotensin-converting enzyme (ACE), we obtained asialo- and partially deglycosylated ACE by enzymatic treatment of two-domain somatic enzyme from bovine lung. Treated enzymes demonstrated appreciable, but different changes of catalytic properties in the reaction of the hydrolysis of N-substituted tripeptides, C-terminal analogs of angiotensin I and bradykinin among them, compared to those for native enzyme. Deglycosylation also altered the catalytic properties of a single N domain of bovine ACE. So, various patterns of glycosylation modulate substrate specificity of somatic ACE and may be the reason for functional heterogeneity of the enzyme.

The distal ectodomain of angiotensin-converting enzyme regulates its cleavage-secretion from the cell surface.

Angiotensin-converting enzyme (ACE) is a type I ectoprotein that is cleaved off the cell surface by a plasma membrane-bound metalloprotease. However, CD4, another type I ectoprotein does not undergo such cleavage-secretion. In this study, we investigated the structural determinants of the ACE protein that regulate the cleavage-secretion process. Substitution and deletion mutations revealed that the cytoplasmic domain, the transmembrane domain, and the juxtamembrane region encompassing the major and the minor cleavage sites of ACE do not regulate its cleavage. Moreover, a chimeric protein containing the distal extracellular domain of CD4 and the juxtamembrane, transmembrane, and the cytoplasmic domains of ACE, although transported to the cell surface, was not cleavage-secreted. In contrast, the distal extracellular domain of ACE was shown to be the important determinant: a protein containing the distal extracellular domain of ACE and the juxtamembrane, transmembrane, and cytoplasmic domain of CD4 was efficiently cleaved off the cell surface. The chimeric protein was cleaved within the CD4 sequence and the responsible enzymatic activity was inhibited by Compound 3, a relatively specific inhibitor of the ACE secretase activity. These results demonstrate that, in a chimeric protein, the distal extracellular domain of a cleavable protein, such as ACE, can induce a proteolytic cleavage within the juxtamembrane domain of an uncleaved protein such as CD4.

Differences in the hydrolysis of enkephalin congeners by the two domains of angiotensin converting enzyme

The hydrolysis of enkephalin (Enk) congeners by the isolated N- (N-ACE) and C-domain of angiotensin I converting enzyme (ACE) and by the two-domain somatic ACE was investigated. Both Leu 5- and Met 5-Enk were cleaved faster by the C-domain than by N-ACE; rates with somatic ACE were 1600 and 2500 nmol/min/nmol enzyme with both active sites being involved. Substitution of Gly 2 by d-Ala 2 reduced the rate to 1 3 rd to 1 7 th of that of the Enks. N-ACE cleaved Met 5-Enk-Arg 6-Phe 7 faster than the C-domain, probably with the highest turnover number of any naturally occurring ACE substrate (7600 min −1). This heptapeptide is also hydrolyzed in the absence of Cl −, but the activation by Cl − is unique; Cl − enhances the hydrolysis of the heptapeptide by N-ACE but inhibits it by the C-domain, yielding about a 5-fold difference in the turnover number at physiological pH. This difference may result in the predominant role of the N-domain in converting Met 5-Enk-Arg 6-Phe 7 to Enk in vivo.