Angiotensin converting enzyme (ACE) and neprilysin hydrolyze neuropeptides: a brief history, the beginning and follow-ups to early studies

Our investigations started when synthetic bradykinin became available and we could characterize two enzymes that cleaved it: kininase I or plasma carboxypeptidase N and kininase II, a peptidyl dipeptide hydrolase that we later found to be identical with the angiotensin I converting enzyme (ACE). When we noticed that ACE can cleave peptides without a free C-terminal carboxyl group (e.g., with a C-terminal nitrobenzylamine), we investigated inactivation of substance P, which has a C-terminal Met(11)-NH(2). The studies were extended to the hydrolysis of the neuropeptide, neurotensin and to compare hydrolysis of the same peptides by neprilysin (neutral endopeptidase 24.11, CD10, NEP). Our publication in 1984 dealt with ACE and NEP purified to homogeneity from human kidney. NEP cleaved substance P (SP) at Gln(6)-Phe(7), Phe(7)[see text]-Phe(8), and Gly(9)-Leu(10) and neurotensin (NT) at Pro(10)-Tyr(11) and Tyr(11)-Ile(12). Purified ACE also rapidly inactivated SP as measured in bioassay. HPLC analysis showed that ACE cleaved SP at Phe(8)-Gly(9) and Gly(9)-Leu(10) to release C-terminal tri- and dipeptide (ratio = 4:1). The hydrolysis was Cl(-) dependent and inhibited by captopril. ACE released only dipeptide from SP free acid. ACE hydrolyzed NT at Tyr(11)-Ile(12) to release Ile(12)-Leu(13). Then peptide substrates were used to inhibit ACE hydrolyzing Fa-Phe-Gly-Gly and NEP cleaving Leu(5)-enkephalin. The K(i) values in microM were as follows: for ACE, bradykinin = 0.4, angiotensin I = 4, SP = 25, SP free acid = 2, NT = 14, and Met(5)-enkephalin = 450, and for NEP, bradykinin = 162, angiotensin I = 36, SP = 190, NT = 39, Met(5)-enkephalin = 22. These studies showed that ACE and NEP, two enzymes widely distributed in the body, are involved in the metabolism of SP and NT. Below we briefly survey how NEP and ACE in two decades have gained the reputation as very important factors in health and disease. This is due to the discovery of more endogenous substrates of the enzymes and to the very broad and beneficial therapeutic applications of ACE inhibitors.     

Catabolism of gastrin releasing peptide and substance P by gastric membrane-bound peptidases

The catabolism of two gastric neuropeptides, the C-terminal decapeptide of gastrin releasing peptide-27 (GRP10) and substance P (SP), by membrane-bound peptidases of the porcine gastric corpus and by porcine endopeptidase-24.11 ("enkephalinase") has been investigated. GRP10 was catabolized by gastric muscle peptidases (specific activity 1.8 nmol min-1 mg-1 protein) by hydrolysis of the His8-Leu9 bond and catabolism was inhibited by phosphoramidon (I50 approx. 10(-8) M), a specific inhibitor of endopeptidase-24.11. The same bond in GRP10 was cleaved by purified endopeptidase-24.11, and hydrolysis was equally sensitive to inhibition by phosphoramidon. SP was catabolized by gastric muscle peptidases (specific activity 1.7 nmol min-1 mg-1 protein) by hydrolysis of the Gln6-Phe7, Phe7-Phe8 and Gly9-Leu10 bonds, which is identical to the cleavage of SP by purified endopeptidase-24.11. The C-terminal cleavage of GRP10 and SP would inactivate the peptides. It is concluded that a membrane-bound peptidase in the stomach wall catabolizes and inactivates GRP10 and SP and that, in its specificity and sensitivity to phosphoramidon, this peptidase resembles endopeptidase-24.11.     

The hydrolysis of brain and atrial natriuretic peptides by porcine choroid plexus is attributable to endopeptidase-24.11.

The hydrolysis of the porcine 26-residue brain natriuretic peptide (BNP-26) and its counterpart human 28-residue atrial natriuretic peptide (alpha-hANP) by pig membrane preparations and purified membrane peptidases was studied. When the two peptides were incubated with choroid plexus membranes, the products being analysed by h.p.l.c., alpha-hANP was degraded twice as fast as BNP. The h.p.l.c. profiles of alpha-hANP hydrolysis, in short incubations with choroid plexus membranes, yielded alpha hANP' as the main product, this having been previously shown to be the result of hydrolysis at the Cys7-Phe8 bond. In short incubations this cleavage was inhibited 84% by 1 microM-phosphoramidon, a specific inhibitor of endopeptidase-24.11. BNP-26 was hydrolysed by choroid plexus membranes, kidney microvillar membranes and purified endopeptidase-24.11 in a manner that yielded identical h.p.l.c. profiles. In the presence of phosphoramidon, hydrolysis by the choroid plexus membranes was 94% inhibited. Captopril had no effect and, indeed, no hydrolysis of BNP-26 by peptidyl dipeptidase A (angiotensin-converting enzyme) was observed even after prolonged incubation with the purified enzyme. The stepwise hydrolysis of BNP-26 by endopeptidase-24.11 was investigated by sequencing the peptides produced during incubation. The initial product resulted from hydrolysis at Ser14-Leu15, thereby opening the ring. This product (BNP') was short-lived; further degradation involved hydrolysis at Ile12-Gly13, Arg8-Leu9, Gly17-Leu18, Val22-Leu23, Arg11-Ile12 and Cys4-Phe5. Thus endopeptidase-24.11 is the principal enzyme in renal microvillar and choroid plexus membranes hydrolysing BNP-26 and alpha-hANP.     

Purification of an acid proteinase from Aspergillus saitoi and determination of peptide bond specificity.

The specificity and mode of action of an acid proteinase (EC 3.4.23.6) from Aspergillus saitoi were investigated with oxidized B-chain of insulin, angiotensin II and bradykinin. Further purification of acid proteinase was performed with N,O-dibenzyloxycarbonyl-tyrosine hexamethylene-diamino-Sepharose 4B affinity chromatography and isoelectric focusing. The purified enzyme was free of any other proteolytic activity demonstrated in Asp. saitoi. Acid proteinase from Asp. saitoi hydrolyzed primarily two peptide bonds in the oxidized B-chain of insulin, the Leu(15)-Tyr(16) bond and the Phe(24)-Phe(25) bond. Additional cleavages of the bonds His(10)-Leu(11), Ala(14)-Leu(15) and Tyr(16)-Leu(17) were also noted. Primary splitting sites at Leu(15)-Tyr(16) and Phe(24-)-Phe(25) with acid proteinase from Asp. saitoi were identical with those reported in the work of cathepsin D (EC 3.4.23.5) from human erythrocyte. Hydrolysis of angiotensin II was observed at the Tyr(4)-Ile(5) bond. In conclusion, peptide bonds which have a hydrophobic amino acid such as phenylalanine, tyrosine, leucine and isoleucine in the P'1 position (as defined by Berger and Schechter, [29]) are preferentially cleaved by the trypsinogenactivating acid proteinase from Asp. saitoi.     

Purification, characterization and substrate specificity of a basic proteinase in the venom of habu (Trimeresurus flavoviridis)

A basic proteinase was purified and characterized from the venom of Habu (Trimeresurus flavoviridis). Its molecular weight, isoelectric point and optimum pH were approx. 24,000, 9.2 and 9, respectively. Susceptibility to several reagents was examined. The proteinase had endopeptidase activity cleaving the Gly-Leu bond in synthetic peptides but no exopeptidase activity. It did not hydrolyze a peptide, Z-Gly-Pro-Leu-Gly-Pro, which had been a good substrate for the major proteinase in the venom. The proteinase cleaved oxidized insulin B chain at five positions: His10-Leu11, Ala14-Leu15, Tyr16-Leu17, Gly23-Phe24 and Phe24-Phe25. From the disappearance of intermediate peptides and the peptides accumulated, the order and the intensity of cleavage of these positions were determined, and the substrate specificity was compared with those hitherto described for hemorrhagic and nonhemorrhagic venom proteinases.     

Histamine release by neurotensin in the rat hindquarter: structure-activity studies

Histamine releasing effects of neurotensin (NT) and several NT fragments and structural analogues were measured in the rat perfused hindquarter. The results show that the chemical groups responsible for histamine release are located in the C-terminal sequence Arg9-Pro10-Tyr11-Ile12-Leu13-OH. Both the spatial configuration and positive charge of Arg8 and Arg9 appear to contribute to the histamine releasing effect of NT. Optimization of the histamine releasing effect of NT requires both a free C-terminal carboxyl group and the presence in position 11 of NT of an aromatic residue, with the L-configuration, bearing an heteroatom capable of hydrogen bonding with the receptor. The results indicate that the structural requirements of NT to induce histamine release from the rat perfused hindquarter are similar to those involved in other peripheral biological actions of NT.     

Expression of NEP2, a soluble neprilysin-like endopeptidase, during embryogenesis in Drosophila melanogaster

Members of the neprilysin family of neutral endopeptidases (M13) are typically membrane-bound enzymes known to be involved in the extra-cellular metabolism of signalling peptides and have important roles during mammalian embryogenesis. In this study we show that membranes prepared from embryos of Drosophila melanogaster possess neprilysin-like activity that is inhibited by phosphoramidon and thiorphan, both inhibitors of mammalian neprilysin. Unexpectedly, we also found strong neprilysin-like neutral endopeptidase activity in a soluble embryo fraction, which we identify as NEP2 by Western blot and immunoprecipitation experiments using NEP2 specific antibodies. NEP2 is a soluble secreted member of the neprilysin family that has been shown previously to be expressed in larval and adult Malpighian tubules and in the testes of adult males. In situ hybridization studies reveal expression at stage 10-11 in a pattern similar to that previously described for stellate cell progenitors of the caudal visceral mesoderm. In later stages of embryogenesis, some of these cells appear to migrate into the growing Malpighian tubule. Recombinant NEP2 protein is N-glycosylated and displays optimum endopeptidase activity at neutral pH, consistent with a role as an extracellular peptidase. The recombinant enzyme hydrolyses Drosophila tachykinin peptides (DTK) at peptide bonds N-terminal to hydrophobic residues. DTK2, like Locusta tachykinin-1, was cleaved at the penultimate peptide bond (Gly(7)-Leu(8)), whereas the other Drosophila peptides were cleaved centrally at Xxx-Phe bonds. However, the rates of hydrolysis of the latter substrates were much slower than the hydrolysis rates of DTK2 and Locusta tachykinin-1, suggesting that the interaction of the bulky side-chain of phenylalanine at the S'(1) sub-site is less favorable for peptide bond hydrolysis. The secretion of NEP2 from tissues during embryogenesis suggests a possible developmental role for this endopeptidase in peptide signalling in D. melanogaster.     

Preparation and receptor binding affinities of cyclic C-terminal neurotensin (8-13) and (9-13) analogues.

Cyclic analogues of neurotensin (NT) C-terminal fragments NT(8-13) and NT(9-13) were produced via intramolecular nucleophilic substitution of the Tyr(11) phenoxide anion on a 6-bromohexanoyl side chain substituted at position 8 or 9 and tested for NT receptor binding affinity.     

Specificity of neuropeptide degradation by two calcium-activated neutral proteases from human skeletal muscle

Two calcium-activated neutral proteases (CAPI & II) were purified from human skeletal muscle by anion exchange, gel filtration and affinity (antipain-Sepharose and Blue Ultrogel A4R) chromatography. The enzymes were homogenous as judged by polyacrylamide gel electrophoresis, and have similar properties with the exception of the Ca2+ concentration required for optimum activity (CAP I = 0.1 mM; CAP II = 1 mM). Both enzymes hydrolysed a wide variety of neuropeptides. In six cases, the products were separated and identified by hplc and amino acid analysis. Neurotensin was hydrolysed at Tyr3-Glu4; dynorphin1-13 at Arg8-Arg9; LH-RH at Gly6-Leu7; CCK-8 at Phe8-NH2, substance-P at Met10-NH2; somatostatin at Thr10-Phe11. Although differences in the rates of neuropeptide degradation were noted for the two CAP's the specificity was the same for these six peptides. It is suggested that conformational requirements may be more important than side chains adjacent to the cleavage site in directing the specificity of CAP.     

Proteolytic specificity of hemorrhagic toxin b from Crotalus atrox (western diamondback rattlesnake) venom

In our effort to identify the proteolytic specificity of various hemorrhagic toxins isolated from western diamondback rattlesnake venom, hemorrhagic toxin b was isolated in homogeneous form by previously published methods. Hemorrhagic toxin b hydrolyzed glucagon, producing six fragments. The proteolytic sites were identified as Thr(5)-Phe(6), Thr(10)-Ser(11), Asp(15)-Ser(16), Asp(21)-Phe(22) and Try(25)-Leu(26). When oxidized insulin B chain was used, proteolysis occurred at four sites: Asn(3)-Gln(4), His(10)-Leu(11), Tyr(16)-Leu(17) and Gly(23)-Phe(24). The proteolytic specificity of hemorrhagic toxin b is quite different from those of the nonvenom proteases such as thermomycolin, aspergillopeptidase c, alkaline protease from Aspergillus flavus, elastase, subtilisin and papain.     

Metalloendopeptidase (EC 3.4.24.11) but not angiotensin converting enzyme is involved in the inactivation of substance P by synaptic membranes of the rat substantia nigra

Substance P is a neuropeptide released in vivo from the substantia nigra, the principal substance P nerve terminal region in the rat brain. Its inactivation was investigated in a purified nigral synaptic membrane preparation. The membrane-bound enzyme shares many features with the endopeptidase 24-11 (EC 3.4.24.11): 1) hydrolysis of peptide bonds Gln6-Phe7, Phe7-Phe8 and Gly9-Leu10, 2) sensitivity to the inhibition by phosphoramidon and 3) relative affinity for substance P. Bestatine and captopril inhibit only the hydrolysis of the metabolites. These results suggest that substance P is inactivated in substantia nigra by endopeptidase 24-11 and that a bestatin-sensitive aminopeptidase and angiotensin converting enzyme may play a role in subsequent degradation of the substance P metabolites.     

Catabolism of substance P in the stomach wall of the rat

The aim of this study was to examine the catabolism of substance P (SP) in the stomach wall of the rat. Catabolism in vitro was investigated by incubation of unlabelled and tritiated SP (prolyl 2,4-3,4(n)-3H SP) with membrane bound-peptidases prepared from the rat gastric corpus. Catabolism was studied in vivo by use of a catheter chronically implanted in the stomach wall to deliver tritiated SP to the gastric tissues and implanted dialysis fibers to collect the catabolic products. The products from both experiments were separated by high pressure liquid chromatography and identified by their retention times or amino acid analysis. Membrane-bound peptidases in vitro hydrolyzed both unlabelled and tritiated SP and the products of hydrolysis were consistent with the cleavage of three bonds: Gln6-Phe7, Phe7-Phe8 and Gly9-Leu10. None of the peptide fragments would be expected to be biologically active. Only those fragments with tritiated Pro residues could be detected in vivo. The major identified products were SP(1-2) and SP(3-4), with smaller amounts of SP(1-4), SP(1-6), SP(1-7), SP(1-8) and SP(1-9). The enzymes that may be responsible for these cleavage patterns are discussed.     

Mimicking the membrane-mediated conformation of dynorphin A-(1-13)-peptide: circular dichroism and nuclear magnetic resonance studies in methanolic solution.

The structural requirements for the binding of dynorphin to the kappa-opioid receptor are of profound clinical interest in the search for a powerful nonaddictive analgesic. These requirements are thought to be met by the membrane-mediated conformation of the opioid peptide dynorphin A-(1-13)-peptide, Tyr1-Gly2-Gly3-Phe4-Leu5-Arg6-Arg7-Ile8-Arg9-Pro10- Lys11-Leu12-Lys13. Schwyzer has proposed an essentially alpha-helical membrane-mediated conformation of the 13 amino acid peptide [Schwyzer, R. (1986) Biochemistry 25, 4281-4286]. In the present study, circular dichroism (CD) studies on dynorphin A-(1-13)-peptide bound to an anionic phospholipid signified negligible helical content of the peptide. CD studies also demonstrated that the aqueous-membraneous interphase may be mimicked by methanol. The 500- and 620-MHz 1H nuclear magnetic resonance (NMR) spectra of dynorphin A-(1-13)-peptide in methanolic solution were sequence-specifically assigned with the aid of correlated spectroscopy (COSY), double-quantum filtered phase-sensitive COSY (DQF-COSY), relayed COSY (RELAY), and nuclear Overhauser enhancement spectroscopy (NOESY). 2-D CAMELSPIN/ROESY experiments indicated that at least the part of the molecule from Arg7 to Arg9 was in an extended or beta-strand conformation, which agreed with deuterium-exchange and temperature-dependence studies of the amide protons and analysis of the vicinal spin-spin coupling constants 3JHN alpha. The results clearly demonstrated the absence of extensive alpha-helix formation. chi 1 rotamer analysis of the 3J alpha beta demonstrated no preferred side-chain conformations.     

Tetrazole analogues of cyclolinopeptide A: synthesis, conformation, and biology

Linear and cyclic analogues of cyclolinopeptide A (CLA) with two dipeptide segments (Val(5)-Pro(6) and Pro(6)-Pro(7)) replaced by their tetrazole derivatives were synthesized by the SPPS technique and cyclized using TBTU (O-(benzotriazol-1-yl)-1,1,3,3-tetramethyluronium tetrafluoroborate) reagent. The conformational properties of the c(Leu(1)-Ile(2)-Ile(3)-Leu(4)-Val(5)-Pro(6)-psi[CN(4)]-Ala(7)-Phe(8)-Phe(9)) were investigated by NMR and computational techniques. The overall solution structure of this cyclic peptide resembles that observed for the CLA in the solid state. These studies of cyclic tetrazole CLA analogue confirm that the 1,5-disubstituted tetrazole ring functions as an effective, well-tolerated cis-amide bond mimic in solution. The peptides were examined for their immunosuppressive activity in the humoral response test. For cyclic analogues the immunosuppressive activity, at low doses, is equal in magnitude to the activity presented by cyclosporin A and native CLA. The conformational and biological data seem indicate that the Pro-Pro-Phe-Phe moiety and the preservation of the CLA backbone conformation are important for immunosuppressive activity.     

Substrate specificities and inhibition of two hemorrhagic zinc proteases Ht-c and Ht-d from Crotalus atrox venom

The proteolytic specificities of two zinc hemorrhagic toxins (Ht-c and Ht-d), isolated from Crotalus atrox venom, were investigated by using the oxidized B chain of bovine insulin and synthetic peptide substrates. The enzymes cleaved the Ala14-Leu15 bond of the insulin B chain most rapidly and the Tyr16-Leu17 slightly more slowly. The His5-Leu6, His10-Leu11, and Gly23-Phe24 bonds were also cleaved but at considerably slower rates. In order to assess the substrate length preferences of the enzymes, peptide analogs of the B chain about the Ala14-Leu15 bond were synthesized ranging in length from four to seven residues. The heptapeptide NH2-Leu-Val-Glu-Ala-Leu-Tyr-Leu-COOH was the best peptide substrate tested with the other peptides having decreasing kcat/Km values with decreasing length. The tetrapeptide NH2-Ala-Leu-Tyr-Leu-COOH was not cleaved by the enzymes. Furthermore, this peptide was shown to serve as a competitive inhibitor of the toxins. The N-acetylated pentapeptides and hexapeptides, synthesized to probe the active site environment of the enzymes, were significantly better substrates than their unacetylated counterparts. The toxins had the highest kcat/Km values for the acetylated peptide Ac-Val-Ala-Leu-Leu-Ala-COOH. The data suggest that the toxins may indeed have extended substrate-binding sites, which may accommodate at least six amino acid residues. The best substrate examined thus far for the toxins is the fluorogenic peptide analog 2-aminobenzoyl-Ala-Gly-Leu-Ala-4-nitrobenzylamide, suggestive of similarities between the toxins and mammalian collagenases as well as thermolysin. Mechanisms for inhibition of the enzymes were investigated using amino acid hydroxamates, chloromethyl esters, phosphoramidon and the peptide NH2-Ala-Leu-Tyr-Leu-COOH. All of these inhibitors had Ki values in the 10(-4) M range.     

Human lung post-proline endopeptidase: purification and action on vasoactive peptides

Post-proline endopeptidase (PPE, EC 3.4.21.26) was purified 3,450 times from human lung. PPE was routinely assayed with the artificial substrate, carbobenzoxy-glycyl-L-prolyl-p-nitroanilide (Z-Gly-Pro-pNA). The pH optimum was 7.4, and the Mr was 77,000. Thiol blocking agents were strongly inhibitory but serine blocking agents were not inhibitory. No metal ions were required for activity, but heavy metal ions such as Hg2+, Cu2+, Cd2+, and Zn2+ completely inactivated the enzyme. Both dithiothreitol (DTT) and ethylenediaminetetraacetic acid (EDTA) were required to stabilize PPE activity. Michaelis constant values for Z-Gly-Pro-pNA and carbobenzoxy-glycyl-L-prolyl-2-naphthylamide were 0.36 and 0.10 mmol/l, respectively. PPE cleaved vasoactive peptides including bradykinin (BK) and des-(Arg9)-BK (Pro3-Gly4 and Pro7-Phe8 bonds), angiotensins I and II (Pro7-Phe8 bond), substance P (Pro4-Gln5 bond), and oxytocin (Pro7-Leu8 bond). Each of these peptides inhibited PPE-catalyzed hydrolysis of Z-Gly-Pro-pNA competitively. BK had the lowest Ki value (2.35 mumol/l) and oxytocin had the highest Ki value (84.0 mumol/l). PPE was not inhibited by captopril, a potent inhibitor of angiotensin converting enzyme, which also cleaves the Pro7-Phe8 bond of BK.     

A semicontinuous, high-performance liquid chromatography-based assay for stromelysin

A search for low molecular weight peptide substrates for the metalloendoproteinase, human fibroblast stromelysin, resulted in the discovery that substance P (Arg-Pro-Lys-Pro-Gln-Gln-Phe-Phe-Gly-Leu-Met-NH2) is a substrate for this enzyme and is cleaved exclusively at the Gln6-Phe7 bond. On the basis of this observation, a semicontinuous HPLC-based assay was developed that monitors the production of the hydrolysis product, fragment 7-11 (SP7-11). Steady-state velocities for the production of SP7-11 have been determined as a function of substrate concentration and obey simple, Michaelis-Menten kinetics. For a 1-ml reaction volume, Vmax = (2.4 nmol SP7-11/min)/micrograms protein and Km = 0.38 mM.     

Degradation of brain natriuretic peptide by neutral endopeptidase: species specific sites of proteolysis determined by mass spectrometry

Brain natriuretic peptide (BNP) from 3 different species was cleaved by neutral endopeptidase (NEP) and the products separated by HPLC. The newly formed products were identified by fast atom bombardment or nebulizer-assisted electrospray mass spectrometry to elucidate the sites of proteolysis. Porcine BNP was cleaved at the Arg8-Leu9 and Ser14-Leu15 bonds. Rat BNP was cleaved at the Arg23-Leu24 and Arg30-Leu31 bonds. Human BNP was cleaved at the Pro2-Lys3, Met4-Val5 and Arg17-Leu18 bonds. The Cys-Phe bond which is present in all species of BNP is not cleaved by NEP.     

Species differences in angiotensin II generation and degradation by mast cell chymases

Although chymases are known to exhibit species differences in regard to angiotensin (Ang) II generation and degradation, their properties have never been compared under the same experimental conditions. We analyzed the processing of Ang I by chymases of a variety of species (human chymase, dog chymase, hamster chymase-1, rat mast cell protease-1 [rMCP-1], mouse mast cell protease-4 [mMCP-4]) at physiological ionic strength and under neutral pH conditions. Human chymase generated Ang II from Ang I without further degradation, whereas the chymases of other species generated Ang II, followed by degradation at the Tyr4-Ile5 site in a time-dependent manner. Kinetic analysis showed that in terms of Ang II generating activity (analyzed by cleavage of the Phe8-His9 bond using the model peptide Ang(5-10), Ile5-His6-Pro7-Phe8-His9-Leu10), the chymases ranked as follows: dog > human > hamster > mouse > rat (kcat/Km: 18, 11, 0.69, 0.059, 0.030 microM-1min-1), and that in terms of Ang II degrading activity (i.e., cleavage of the Tyr4-Ile5 bond of Ang II), the order was hamster > rat > mouse > dog (kcat/Km: 5.4, 4.8, 0.39, 0.29 microM-lmin-1). These results suggest species differences in the contribution of chymases to local Ang II generation and degradation.