Inhibition of enkephalin-degrading enzymes from rat brain and of thermolysin by amino acid hydroxamates

Sensitive substrates for neprilysin (neutral endopeptidase) and thermolysin that are highly resistant to serine proteases

Tripeptide derivatives like 3-carboxypropanoylalanyl-alanyl-leucine 4-nitroanilide or 3-carboxypropanoyl-alanyl-alanyl-phenylalanine 4-nitroanilide are very sensitive substrates for neprilysin (k cat > 10(2)s(-1); k cat/Km > or = 10(6) s(-1) x M(-1)) and are widely employed in investigations of the enzyme. However, these compounds are also good substrates for the serine proteases chymotrypsin and subtilisin (k cat approximately 1s(-1)-34s(-1)). By substituting the N-terminal alanine of the substrates with proline, the catalytic efficiency of the enzymic reaction, by the serine proteases, is diminished by 2-3 orders of magnitude, whereas that by neprilysin and theromlysin decreases only slightly. These effects demonstrate that structural alterations in peptide substrates that impair secondary sub-site interactions with one class of peptidases may enhance the selectivity of the substrates towards another class of peptidases.

Inhibitors of enkephalin-degrading enzymes as potential therapeutic agents

A limited number of enzymes such as membrane metalloendopeptidase (enkephalinase) and angiotensin converting enzyme appear to be involved in deactivation and modulation of circulatory regulatory peptides. Peptides such as the enkephalins are also involved in a large number of physiological processes. This multiplicity of physiological roles has made it difficult to establish the therapeutic role of enkephalin-degrading enzyme inhibitors. Other factors such as difficulty in quantification and thus measurement of processes involved in pain and mental illness have also hindered the process of establishing any therapeutic role of enkephalin-degrading enzyme inhibitors in these conditions. However, they have proved to be useful pharmacological 'tools'. The most likely therapeutic role at present appears to be in the treatment of cardiovascular disorders. As a 'profile' of pharmacological actions of enkephalin-degrading enzymes emerges, it is becoming apparent that bioavailability rather than a high degree of specificity or inhibitory potency may be the most important factor. This may be used to an advantage in future developments by the use of less specific or combined inhibitors in the form of prodrugs, designed to be active at specific sites such as the central nervous system.

Detection of neutral endopeptidase-24.11/CD10 by flow cytometry and photomicroscopy using a new fluorescent inhibitor

Neutral endopeptidase (NEP; E.C. 3.4.24.11) is a mammalian ectopeptidase identified as the common acute lymphoblastic leukemia antigen (CALLA or CD10). In order to investigate its cellular processing and its role in B lymphocyte differentiation, a fluorescent derivative of the mercapto NEP inhibitor thiorphan, N-[fluoresceinyl]-N'-[1-(6-(3-mercapto-2-benzyl-1-oxopropyl) amino-1-hexyl]thiocarbamide (FTI), has been synthesized. The fluorescent characteristics of fluorescein were conserved in FTI after linkage with the thiol NEP inhibitor. FTI inhibited NEP with an IC50 value of 10 nM and a good selectivity compared to that of aminopeptidase N (greater than 100 microM) and angiotensin converting enzyme (32 microM). The FTI probe was shown to detect membrane-bound NEP using photomicroscopy on cultured cells or flow cytometry techniques. Using NEP-expressing MDCK cells and episcopic fluorescence microscopy, a specific labeling was obtained with 100 nM FTI which was completely displaced by 10 microM HACBOGly, a specific and potent inhibitor of NEP. Therefore, FTI can be considered a suitable tool for following cellular NEP traffic. In flow cytometry, the fluorescent probe FTI, used at concentrations as low as 1 nM with Reh6 cells, could be very useful for detecting NEP/CALLA on lymphoid cells. In addition, the recognition of FTI is independent of tissues and species, a major advantage of inhibitors over monoclonal antibodies.

Hydrolysis of thymic humoral factor gamma 2 by neutral endopeptidase (EC 3.4.24.11)

A search for the natural substrates for neutral endopeptidase (NEP; EC 3.4.24.11) in the immune system led to investigation of the enzyme's action on thymic humoral factor gamma 2 (THF). The ectoenzyme rapidly and efficiently hydrolyses the Lys6-Phe7 bond of the octapeptide. The site of cleavage was confirmed by h.p.l.c. analysis, amino acid analysis and sequence determination of the products. Phosphoramidon (3.6 microM), a potent inhibitor of the enzyme, prevents this cleavage even during prolonged incubation. The high efficiency of hydrolysis of THF by NEP is similar to that reported for [Leu5]enkephalin, and the dipeptide Phe-Leu is the C-terminal product in the hydrolysis of both peptides. The presence of NEP, reportedly identified as the common acute lymphoblastic leukaemia antigen (CALLA), in bone-marrow cells and other cells of the immune system raises the possibility that it may play a role in modulating the activity of peptides such as THF.

Neutral endopeptidase (EC 3.4.24.11) is highly expressed on osteoblastic cells and other marrow stromal cell types

A series of cultured mouse marrow stromal cell lines of different phenotype characteristics were examined for their neutral endopeptidase (NEP) activity using the highly selective chromophoric substrate of enzyme, 3-carboxypropanoyl-alanyl-alanyl-leucine 4-nitroanilide. All the cell lines tested contained appreciable amounts of NEP activity, but the cells expressing an osteoblastic phenotype, MBA-15, showed the high levels. Other non-stromal osteoblastic cell lines, MC-3T3-E1, ROS 17/2.8 cells derived from mouse long bone explants, were also rich in NEP. A four-fold stimulation of NEP activity was observed when certain MBA-15 clones were cultured in the presence of 1 alpha,25-dihydroxyvitamin D3. Since NEP is an effective cell-surface endopeptidase, it may play a role in the dynamics of bone formation, via interaction with biologically active polypeptides.

Investigation of neutral endopeptidases (EC 3.4.24.11) and of neutral proteinases (EC 3.4.24.4) using a new sensitive two-stage enzymatic reaction

A sensitive two-stage enzymatic reaction for mammalian and bacterial metalloendopeptidases has been developed using the substrate 3-carboxypropanoyl-alanyl-alanyl-leucine-4-nitroanilide supplemented with Streptomyces griseus amino-peptidase. Neutral endopeptidase EC 3.4.24.11 from bovine kidney hydrolyzes the substrate (pH 7.5, 25 degrees C) with a catalytic efficiency (kcat = 1.2 x 10(2) s-1, Km = 0.15 mM) of the highest ever reported for the enzyme acting on synthetic chromophoric and fluorogenic substrates. Thermolysin hydrolyzes the substrate at a faster rate (kcat = 1.2 x 10(3) s-1) but the overall efficiency is diminished by a higher Km (4.2 mM). Suspensions of human neutrophil cells and culture filtrates of Bacillus cereus have been assayed sensitively for their neutral endopeptidases and neutral proteinase activities, respectively. The assay provides a convenient tool for the kinetic investigation of neutral endopeptidases and neutral proteinases and for assessing their function in biological systems.

Inhibitors of the enkephalin degrading enzymes. Modulation of activity of hydroxamate containing compounds by modifications of the C-terminal residue

To further characterize the S'2 subsite of both the neutral endopeptidase (EC 3.4.24.11, NEP) and aminopeptidase N (EC 3.4.11.2, APN), two enzymes physiologically involved in enkephalin metabolism, a new series of hydroxamate inhibitors containing a cyclic amino acid as the P'2 component were synthesized. These amino acids differ by the size of the cycle, the relative position of the functional groups, and their absolute configuration. Highly efficient inhibitors of NEP were obtained whatever the modification on the P'2 component, while for APN inhibition, a cyclic beta-amino acid was preferred. The most active inhibitors contained a trans cyclopentyl beta-amino acid and a cis or a trans cyclohexyl beta-amino acid. When injected intracerebroventricularly in mice, these two latter compounds elicited potent antinociceptive responses on both the jump latency and the fore paw lick times.

Properties of a Leu-Phe-cleaving endopeptidase activity putatively involved in beta-endorphin metabolism in rat brain

Incubation of beta-endorphin with cytosolic and particulate fractions of rat brain resulted in the formation of several peptides, including gamma-endorphin [beta-endorphin-(1-17)] and beta-endorphin-(18-31), indicating the presence of enzyme activity cleaving the Leu17-Phe18 bond of beta-endorphin. An assay for this Leu-Phe cleaving activity, based on the cleavage of the 14C-labeled substrate acetyl-Val-Thr-Leu-Phe-[epsilon-([14C]CH3)2]Lys-NHCH3, was used to examine the properties of this enzyme activity. beta-Endorphin-(1-31) competitively inhibited the Leu-Phe-cleaving enzyme activity on the pentapeptide substrate. Over 90% of activity was recovered in the cytosolic fraction. Leu-Phe-cleaving activity behaved like a thiol endopeptidase because it was inhibited by low concentrations of N-ethylmaleimide, p-chloromercuribenzoate, p-chloromercuribenzoyl sulfate, and low concentrations of Hg2+. Low concentrations of sulfhydryl compounds stimulated Leu-Phe-cleaving activity. The activity was optimal between pH 8.5 and 9.0. The Km of Leu-Phe-cleaving activity in the cytosolic fraction was 35 microM and in the particulate fraction 88 microM with Vmax values of 193 and 15 nmol mg protein-1 h-1, respectively. The apparent molecular mass of the Leu-Phe-cleaving enzyme was estimated by gel filtration to be approximately 200 kilodaltons. These properties of Leu-Phe-cleaving activity indicate that the Leu-Phe-cleaving enzyme is distinct from any known brain endopeptidase.

Enkephalin-degrading enzyme inhibitors. Crucial role of the C-terminal residue on the inhibitory potencies of retro-hydroxamate dipeptides

The retro-inversion of the amide bond in kelatorphan and analogs, the first series of complete inhibitors of enkephalin metabolism, led to compounds highly efficient only against the neutral endopeptidase 24-11 (NEP). In order to increase the recognition of the aminopeptidase N (APN) and dipeptidylaminopeptidase (DAP), without loss of affinity for NEP, the malonyl group of these retro-inhibitors was replaced by diversely substituted succinyl moieties. All the molecules synthesized are highly efficient NEP inhibitors with Ki's in the 0.2-1 nM range, indicating that NEP possesses a relatively large and not very selective S'2 subsite. In contrast, inhibition of DAP activity is crucially dependent on the size and the position of the substituent in the succinyl moiety. Inhibitory potencies in the nanomolar range are obtained with compounds containing a benzyl group in the alpha-position related to the retro amide bond. Finally, a relatively modest inhibition of APN was observed with Ki's in the 0.5-1 microM range for compounds with benzyl or cyclohexyl group in P'2 position. However, these data demonstrate that efficient and complete inhibition of enkephalin degradation can be obtained with hydroxamate dipeptides containing a retro amide bond. The analgesic potency of the most active inhibitors was measured using the hot plate test in mice. Significant antinociceptive responses were obtained but these effects were rather weaker than those expected from the in vitro inhibitory potencies of these compounds on the three enkephalin-degrading enzymes.

Relationship between the inhibitory potencies of thiorphan and retrothiorphan enantiomers on thermolysin and neutral endopeptidase 24.11 and their interactions with the thermolysin active site by computer modelling

The inhibitory potency of separate enantiomers of thiorphan and retrothiorphan has shown that several particularities of the active site of thermolysin are also present in the neutral endopeptidase 24.11, "enkephalinase", such as its ability: i) to recognize a retroamide bond as well as a standard amide bond, ii) to interact similarly with residues in P1' position of either R or S configuration in the thiorphan series but contrastingly to discriminate between the R and S isomers in the retrothiorphan series. These four inhibitors were modellized in the thermolysin active site and their spatial arrangement compared with that of a thiol inhibitor co-crystallized with thermolysin. In all cases, the essential interactions involved in the stabilization of the bound inhibitor were conserved. However, the bound (R) retrothiorphan displayed unfavorable intramolecular contacts, accounting for its lower inhibitory potency for the two metallopeptidases.

Analgesic effect of actinonin, a new potent inhibitor of multiple enkephalin degrading enzymes

Actinonin, previously isolated as an antibiotic and shown to be an inhibitor of aminopeptidase M (EC 3.4.11.2), has now been shown to inhibit three enkephalin-degrading enzymes from guinea-pig striatum. The values of IC50 were 0.39 microM for striatal membrane aminopeptidase ("enkephalin-aminopeptidase") and 5.6 microM striatal membrane neutral endopeptidase ("enkephalinase A"). Furthermore, soluble dipeptidylaminopeptidase in a rat whole brain homogenate was also inhibited by actinonin with the IC50 value of 1.1 microM. Actinonin administered intracisternally (i.cist., 50 micrograms) or intraperitoneally (i.p., 100 mg/kg), potentiated the analgesic action of met-enkephalin (50 micrograms i.cist.). analgesia by a tail-flick test. The potentiating activity of actinonin i.p. to met-enkephalin analgesia was almost the same potency as that of thiorphan, whereas the inhibitory activity of actinonin against enkephalinase A was 1/1000 that of thiorphan. Actinonin alone, administered either i.cist. or i.p., showed an analgesic action as estimated by the tail-flick test.

Composite effects of actinonin when inhibiting enkephalin-degrading enzymes

Actinonin which has been found to be an inhibitor of aminopeptidase M (EC 3.4.11.2) also inhibited enkephalinase A (EC 3.4.24.11) and enkephalin aminopeptidase which were partially purified from the corpus striatum membrane of guinea-pig brain. The IC50 values were 5.6 microM for enkephalinase A and 0.39 microM for enkephalin aminopeptidase. Actinonin also inhibited with an IC50 value of 1.1 microM dipeptidyl aminopeptidase tested on whole brain homogenate of rats in the presence of thiorphan and bestatin. Analgesia was assessed by measuring the tail-flick latency of mice. The analgesic effect of [Met5]enkephalin injected intracisternally (i.cist., 50 micrograms) was potentiated by an intraperitoneal (i.p., 100 and 300 mg/kg) as well as an i.cist. (25 micrograms) injection of actinonin. Actinonin was found to inhibit all three enzymes of enkephalin metabolism and, when given peripherally, to potentiate enkephalin analgesia.

Inhibition of substance P degradation in rat brain preparations by peptide hydroxamic acids

A peptidase activity of rat diencephalon membranes, which acts on the C-terminal hexapeptide sequence of substance P, was characterized using the radiolabeled substrate N alpha-[( 125I]iododesaminotyrosyl)-substance P (6-11)-hexapeptide. This activity presents certain characteristics similar to those of the substance-P-degrading enzyme purified from human brain by Lee et al. [Eur. J. Biochem. 114, 315-327 (1981)]. It is inhibited by metal chelators and some thiol reagents, but is insensitive to inhibitors of serine proteases and aminopeptidases. The activity is different from angiotensin-converting enzyme and enkephalinase, since it is not affected by specific inhibitors of these enzymes. Substance P and substance P C-terminal fragments longer than the pentapeptide inhibited the degradation of the radiolabeled substrate with inhibition constants around 200 microM. Short fragments of the substance P sequence, such as Boc-Phe-Phe-OMe and Boc-Phe-Phe-Gly-OEt, were also found to inhibit the degradation of the substrate. When the metal-chelating hydroxamic acid moiety was attached to the carboxyl terminus of these short peptides, potent inhibitors of the substance-P-degrading activity were obtained, with inhibition constants in the micromolar range. The most potent of these compounds, iododesaminotyrosyl-Phe-Phe-Gly-NHOH (IBH-Phe-Phe-Gly-NHOH), is a competitive inhibitor, with a Ki value of 1.9 microM. The degradation of substance P by rat diencephalon slices was inhibited to the same extent (40-50%) by IBH-Phe-Phe-Gly-NHOH (20 microM) and by phosphoramidon (1 microM). A combination of both reagents reduced the degradation rate by 75-80%, suggesting that both enkephalinase and the substance-P-degrading activity are involved in the metabolism of substance P in this preparation. IBH-Phe-Phe-Gly-NHOH seems to be quite specific for the latter enzyme, since at a high concentration (0.1 mM) it did not affect the degradation of the radiolabeled substrate by alpha-chymotrypsin, papain, or thermolysin.

Enantiomers of [R,S]-thiorphan: dissociation of analgesia from enkephalinase A inhibition

The [R] and [S] enantiomers of the enkephalinase A inhibitor [R,S]-thiorphan have been prepared by asymmetric synthesis. The [S] isomer is principally responsible for the angiotensin converting enzyme inhibitory activity of [R,S]-thiorphan, whereas there were only small differences in the ability of the [R] and [S] isomers to inhibit enkephalinase both in vivo and in vitro. In contrast, the in vivo analgesic activity of [R,S]-thiorphan resided principally in the [R] isomer. These data indicate a surprising dissociation of enkephalinase inhibition from analgesic activity. The fact that the two enantiomers of [R,S]-thiorphan were effective inhibitors of enkephalinase, yet the [R] isomer had substantially greater analgesic activity, indicates that factors other than enkephalinase inhibition may be important for [R, S]-thiorphan's analgesic properties.

Bidentate peptides: highly potent new inhibitors of enkephalin degrading enzymes

Three series of bidentates bearing an hydroxamic or an N-Acyl-N-hydroxy amino group on structures related to Phe-Gly or Phe-Ala exhibit strong inhibitory potency against purified enkephalinase with IC50 values in the 4 to 15 nM range. As with thiol-containing inhibitors, such as thiorphan, the most active compounds are those in which a methylene spacer separates the benzyl P1' moiety from the Zn coordinating residue. Formation of a bidentate complex with the metal enzyme is clearly demonstrated by a loss of potency of three order of magnitude following the removal of one component of the bidentate group. All the compounds studied are unable to interact with angiotensin converting enzyme (IC50 greater than 10,000 nM). Moreover, compounds of the general formula HONHCO-CH2-CH(CH2 phi)-CONH-CH(R)-COOH belonging to the most active series of enkephalinase blockers (IC50 approximately 4 nM) behave also as highly potent and competitive inhibitors (IC50 approximately 10 nM) of a Tyr-Gly releasing dipeptidylaminopeptidase purified from rat brain. The pure steroisomer [(R)-3-(N-hydroxy)carboxamido-2-benzylpropanoyl]-L-alanine designated kelatorphan, exhibits also a relatively good inhibitory potency against aminopeptidases (IC50 approximately 10 microM) and can be considered as the first virtually complete inhibitor of enkephalin metabolism. This very interesting property of inhibiting all three enzymes of enkephalin metabolism could enhance the required selectivity for a possible clinical use of these inhibitors as new analgesic and psychoactive drugs.

Reaction of opioid peptides with neutral endopeptidase ("enkephalinase")

The kinetics of the reactions of nine opioid peptides with the neutral endopeptidase ("enkephalinase") activities of human kidney, rat kidney, and rat brain have been determined. These opioid peptides can be divided into two classes, those that are good inhibitors of Leu5-enkephalin hydrolysis (Ki less than 75 microM) and good substrates for the enzyme, and those that are poor inhibitors (Ki greater than 500 microM) and are not substrates for the enzyme. The former group includes Leu5-enkephalin, Met5-enkephalin, Met5-enkephalin-Arg6-Phe7, beta-lipotropin, and gamma-endorphin, while the nonreactive opioid peptides include alpha-neo-endorphin, beta-neo-endorphin, dynorphin, and beta-endorphin. These results suggest that those peptides containing the Met5-enkephalin sequence are more reactive than those containing the Leu5-enkephalin sequence. The lack of specificity of this neutral endopeptidase indicates that it may function in the degradation of a variety of biologically active peptides.

Fluorogenic substrates for the enkephalin-degrading neutral endopeptidase (Enkephalinase)

Rat brain neutral endopeptidase ("Enkephalinase") was shown to hydrolyze a series of fluorogenic substrates of the general structure 2-aminobenzoyl-(amino acid)n- leucylalanylglycine -4- nitrobenzylamide . The hydrolysis of these substrates was competitively inhibited by Leu5-enkephalin, demonstrating that these are indeed substrates for the rat brain neutral endopeptidase. Cleavage of the fluorogenic substrates yielded leucylalanylglycine -4- nitrobenzylamide as a common product. In addition, a series of inhibitors previously shown to inhibit thermolysin-like enzymes inhibited the hydrolysis of both Leu5-enkephalin and the synthetic substrates. The results of this study (a) demonstrate that the enkephalin-degrading endopeptidase is similar in specificity to thermolysin, (b) provide a continuous sensitive assay system for the enzyme, and (c) point out the potential use of this substrate class for probing the specificity of the enzyme.

Enkephalin degrading enzymes are present in the electric organ of Torpedo californica

Two proteolytic activities that degrade [Leu5]enkephalin were found in Torpedo californica electric organ. One is a soluble aminopeptidase that degrades enkephalin at the Tyr1-Gly2 peptide bond, and the second is an endopeptidase that degrades enkephalin at the Gly3-Phe4 peptide bond. The aminopeptidase is inhibited by low concentrations of puromycin and bestatin. More than 60% of the endopeptidase is associated with the particulate fraction and is almost completely inhibited by low concentrations of captopril (SQ 14225) or SQ 20881 (potent inhibitors of angiotensin converting enzyme). Thiorphan and phosphoramidon (potent enkephalinase inhibitors) are much less effective. The pattern of cleavage and inhibition of the particulate endopeptidase thus resembles that of angiotensin converting enzyme.

Inhibition of metalloendopeptidases by 2-mercaptoacetyl-dipeptides

A series of 2-mercaptoacetyl-dipeptides, a potential group of metalloendopeptidase inhibitors, has been synthesized by coupling the N-hydroxysuccinimide ester of S-acetyl-2-mercaptoacetic acid with hydrophobic dipeptide methyl ester hydrochlorides, followed by hydrolysis with NaOH in aqueous methanol and acidification with HCl. Thus, the 2-mercaptoacetyl derivatives of L-phenylalanyl-L-leucine, L-leucyl-L-phenylalanine and L-leucyl-D-phenylalanine were prepared. The first two compounds inhibit effectively thermolysin from Bacillus thermoproteolyticus and a metalloendopeptidase isolated from Streptomyces griseus, with Ki values in the micromolar range or below. The third compound inhibits the two enzymes only poorly, showing the stereospecificity of the inhibition process. These inhibitors should provide a useful tool for the study of bacterial and mammalian metalloendopeptidases (or dipeptidyl carboxypeptidases) and for the assessment of their physiological role.

Protection of enkephalins from enzymatic degradation utilizing selective metal-chelating inhibitors

Metal ion-chelating agents inhibited enkephalin degradation by a rat striatal membrane-associated endopeptidase termed 'enkephalinase'. The combination of a hydrophobic dipeptidyl moiety and a transition metal-chelating moiety in the same molecule resulted in very efficient and selective inhibitors of enkephalinase. The mercaptoacetyl dipeptides (2-mercaptoacetyl-Leu-Phe and 2-mercaptoacetyl-Phe-Leu) and the N-phosphorylated dipeptides (phosphoryl-Leu-Phe and phosphoramidon) inhibited enkephalinase with IC50 values of 15, 70, 0.3 and 1 nM respectively, but were much less potent against the aminopeptidase and angiotensin converting enzyme, two other metalloenzymes implicated in the degradation of the enkephalins in brain. The inhibition of enkephalinase, using phosphoryl-Leu-Phe as a selective inhibitor, resulted in a 4 fold increase in the amount of enkephalin recovered following K+ depolarization of rat striatal slices.

Endogenous opiates: 1981

This paper is the fourth of an annual series reviewing the research concerning the endogenous opiate peptides. This installment covers only work published during 1981 and attempts to provide a comprehensive, but not exhaustive, survey of the area. Previous papers in the series have dealt with research done before 1981. Topics concerning endogenous opiates reviewed here include a delineation of their receptors, their distribution, their precursors and degradation, behavioral effects resulting from their administration, their possible involvement in physiological responses, and their interactions with other peptides and hormones. Due to the burgeoning literature in this field, the comprehensive nature of this review in the future will be limited to considerations of behavioral phenomena related to the endogenous opiates.

Degradation of enkephalins: the search for an enkephalinase

The opioid peptides methionine-enkephalin and leucine-enkephalin appear to exert their biological effects through a receptor mediated mechanism. There appears to be three potential mechanisms for enkephalin degradation which could serve to control enkephalin levels in the vicinity of enkephalin receptors. These are, 1) cleavage of the tyrosyl-glycine bond by aminopeptidases, 2) cleavage of the glycl-glycine bond by a dipeptidyl aminopeptidase, and 3) cleavage of the glycyl-phenylalanine bond by a dipeptidyl carboxypeptidase. In this review the biochemical properties of these potential enkephalinases are described, and the evidence for each acting as an enkephalinase is reviewed.

Kidney neutral endopeptidase and the hydrolysis of enkephalin by synaptic membranes show similar sensitivity to inhibitors

Neutral endopeptidase (EC 3.4.24.11) from pig kidney hydrolyses [125I]iodo-insulin B-chain and leucine-enkephalin. Both activities were equally sensitive to inhibition by phosphoramidon [N-(alpha-L-rhamnopyranosyloxyhydroxyphosphinyl)-L-leucyl-L-tryptophan] and thiorphan [N-(DL-2-benzyl-3-mercaptopropionyl)glycine]. Thermolysin hydrolysis of insulin B-chain was also sensitive to both inhibitors. The hydrolysis of the Gly3-Phe4 bond of Leu-enkephalin by synaptic membranes prepared from pig brain was partially inhibited by phosphoramidon and thiorphan. Synaptic membranes appear to contain another endopeptidase activity that is insensitive to these reagents. These observations suggest that enzymes similar to the kidney endopeptidase may play a general role in neuropeptide metabolism.