Proline-specific dipeptidyl peptidase from the blue blowfly Calliphora vicina hydrolyzes in vitro the ecdysiostatic peptide trypsin-modulating oostatic factor (Neb-TMOF)

To elucidate the mechanisms of inactivation of the ecdysiostatic peptide trypsin-modulating oostatic factor (Neb-TMOF) in the blue blowfly Calliphora vicina, we investigated its proteolytic degradation. In homogenates and membrane and soluble fractions, this hexapeptide (sequence: NPTNLH) was hydrolyzed into two fragments, NP and TNLH, suggesting the involvement of a proline-specific dipeptidyl peptidase. The dipeptidyl peptidase activity was highest in the late larval stage. It was purified 240-fold from soluble fractions of pupae of mixed age and classified on the basis of several catalytic properties as an invertebrate homologue of mammalian dipeptidyl peptidase IV (EC 3.4.14.5). Fly dipeptidyl peptidase IV has a molecular mass of 200 kDa, showed a pH optimum of 7.5–8.0 with the chromogenic substrate Gly-Pro-4-nitroanilide, and cleaved other chromogenic substrates with penultimate Pro or, with lower activity, Ala. It liberated Xaa-Pro dipeptides from the N-terminus of several bioactive peptides including substance P, neuropeptide Y, and peptide YY but not from bradykinin, indicating that the peptide bond between the two proline residues was resistant to cleavage. Fly dipeptidyl peptidase belongs to the serine class of proteases as the mammalian enzyme does; the fly enzyme, however, is not inhibited by several selective or nonselective inhibitors of its mammalian counterpart. It is suggested that dipeptidyl peptidases exert a regulatory role for the clearance not only of TMOF in flies but for other bioactive peptides in various invertebrates. Arch. Insect Biochem. Physiol. 37:146–157, 1998. © 1998 Wiley-Liss, Inc.     

Characterization of endothelin-converting enzyme-2. Implication for a role in the nonclassical processing of regulatory peptides

Most neuroendocrine peptides are generated by proteolysis of the precursors at basic residue cleavage sites. Prohormone convertases belonging to the subtilisin family of serine proteases are primarily responsible for processing at these "classical sites." In addition to the classical cleavages, a subset of bioactive peptides is generated by processing at "nonclassical" sites. The proteases responsible for these cleavages have not been well explored. Members of several metalloprotease families have been proposed to be involved in nonclassical processing. Among them, endothelin-converting enzyme-2 (ECE-2) is a good candidate because it exhibits a neuroendocrine distribution and an acidic pH optimum. To examine the involvement of this protease in neuropeptide processing, we purified the recombinant enzyme and characterized its catalytic activity. Purified ECE-2 efficiently processes big endothelin-1 to endothelin-1 by cleavage between Trp(21) and Val(22) at acidic pH. To characterize the substrate specificity of ECE-2, we used mass spectrometry with a panel of 42 peptides as substrates to identify the products. Only 10 of these 42 peptides were processed by ECE-2. A comparison of residues around the cleavage site revealed that ECE-2 exhibits a unique cleavage site selectivity that is related to but distinct from that of ECE-1. ECE-2 tolerates a wide range of amino acids in the P1-position and prefers aliphatic/aromatic residues in the P1'-position. However, only a small fraction of the aliphatic/aromatic amino acid-containing sites were cleaved, indicating that there are additional constraints beyond the P1- and P1'-positions. The enzyme is able to generate a number of biologically active peptides from peptide intermediates, suggesting an important role for this enzyme in the biosynthesis of regulatory peptides. Also, ECE-2 processes proenkephalin-derived bovine adrenal medulla peptides, and this processing leads to peptide products known to have differential receptor selectivity. Finally, ECE-2 processes PEN-LEN, an endogenous inhibitor of prohormone convertase 1, into products that do not inhibit the enzyme. Taken together, these results are consistent with an important role for ECE-2 in the processing of regulatory peptides at nonclassical sites.     

Peptidases and proteases of Escherichia coli and Salmonella typhimurium

A number of peptidases and proteases have been identified in Escherichia coli. Although their specific physiological roles are often not known, some of them have been shown to be involved in: the maturation of nascent polypeptide chains; the maturation of protein precursors; the signal peptide processing of exported proteins; the degradation of abnormal proteins; the use of small peptides as nutrients; the degradation of colicins; viral morphogenesis; the inactivation of some regulatory proteins for which a limited lifetime is a physiological necessity. Some of these enzymes act in concert to carry out specific functions. At present, twelve peptidases and seventeen proteases have been characterized. The specificity for only a few of them is known. The possible roles and the properties of these enzymes are discussed in this review.     

A dipeptidyl carboxypeptidase in brain synaptic membranes active in the metabolism of enkephalin containing peptides

A dipeptidyl carboxypeptidase activity has been localized in synaptic plasma membranes which have been prepared from isolated rat brain cortical synaptosomes. The specificity of this proteolytic activity towards various synthetic and biological active peptides is compared to the peptidase activities of intact synaptosomes. In contrast to the synaptosomal peptidases which are capable of cleaving all peptide bonds of Met-enkephalin-Arg6-Phe7 the peptidase activity associated with the synaptic plasma membrane exclusively hydrolyses a dipeptide from the carboxyl terminus of all hepta- and hexapeptides tested. The fact that this dipeptidyl carboxypeptidase does not cleave the Gly3-Phe4 peptide bond of Met-enkephalin suggests that this enzyme is different from "enkephalinase". The synaptic membrane dipeptidyl carboxypeptidase is inhibited by metal chelating agents and thiols but is not affected by compounds known to inhibit serine proteases, thermolysin and "enkephalinase".     

The genetics of lantibiotic biosynthesis

The lantibiotics are a rapidly expanding group of biologically active peptides produced by a variety of Gram-positive bacteria, and are so-called because of their content of the thioether amino acids lanthionine and β-methyllanthionine. These amino acids, and indeed a number of other unusual amino acids found in the lantibiotics, arise following post-translational modification of a ribosomally synthesised precursor peptide. A number of genes involved in the biosynthesis of these highly modified peptides have been identified, including genes encoding the precursor peptide, enzymes responsible for specific amino acid modifications, proteases able to remove the leader peptide, ABC-superfamily transport proteins involved in lantibiotic translocation, regulatory proteins controlling lantibiotic biosynthesis and proteins that protect the producing strain from the action of its own lantibiotic. Analysis of these genes and their products is allowing greater understanding of the complex mechanism(s) of the biosynthesis of these unique peptides.     

Rapid assay to detect possible natural substrates of proteases in living cells

Proteolysis is a regulatory step in many physiological processes, but which proteases in what cellular sites are involved in activation or degradation of which peptides is not well known. We developed a rapid assay consisting of living cells and fluorogenic protease substrates to determine which bioactive peptides are possible natural substrates of a specific protease with the multifunctional or moonlighting protein CD26/dipeptidyl peptidase IV (DPPIV) as a model. CD26/DPPIV catalyzes cleavage of peptides from the amino terminus of peptides with proline at the penultimate position. Many biologically active peptides, such as beta-casomorphin1-5, contain proline in the penultimate position. We incubated living Jurkat cells, which are T cells that lack CD26/DPPIV, and CD26/DPPIV-transfected Jurkat cells in the presence of the fluorogenic substrate [Ala-Pro]2-cresyl violet (Magic Red) and beta-casomorphin1-5. Fluorescent cresyl violet was generated by CD26/DPPIV-transfected Jurkat cells but not by wild-type Jurkat cells with a Km of 3.7 microM. beta-Casomorphin1-5 appeared to be a possible natural substrate of CD26/DPPIV, because it inhibited production of fluorescence competitively (Ki = 60 microM). The assay using living cells and a fluorogenic protease substrate is an efficient system to determine whether specific peptides are possible natural substrates of a particular protease.     

Specific localization of membrane dipeptidase and dipeptidyl peptidase IV in secretion granules of two different pancreatic islet cells.

Endocrine cells require several protein convertases to process the precursors of hormonal peptides that they secrete. In addition to the convertases, which have a crucial role in the maturation of prohormones, many other proteases are present in endocrine cells, the roles of which are less well established. Two of these proteases, dipeptidyl peptidase IV (EC 3.4.14.5) and membrane dipeptidase (EC 3.4.13.19), have been immunocytochemically localized in the endocrine pancreas of the pig. Membrane dipeptidase was present exclusively in cells of the islet of Langerhans that were positive for the pancreatic polypeptide, whereas dipeptidyl peptidase IV was restricted to cells positive for glucagon. Both enzymes were observed in the content of secretory granules and therefore would be released into the interstitial space as the granules undergo exocytosis. At this location they could act on secretions of other islet cells. The relative concentration of dipeptidyl peptidase IV was lower in dense glucagon granules, where the immunoreactivity to glucagon was higher, and vice versa for light granules. This suggests that, in A-cells, dipeptidyl peptidase IV could be sent for degradation in the endosomal/lysosomal compartment during the process of granule maturation or could be removed from granules for continuous release into the interstitial space. The intense proteolytic activity that takes place in the endocrine pancreas could produce many potential dipeptide substrates for membrane dipeptidase. (J Histochem Cytochem 47:489-497, 1999)     

Potential of Plant’s Dipeptidyl Peptidase I & II Homologs in Generation of ACE Inhibitory Peptides

Synthetic inhibitors of angiotensin converting enzyme (ACE) are commonly used in the treatment of hypertension and other cardiovascular diseases. But their diverse side effects stipulated nontoxic safer and economic inhibitors which can be accomplished by using peptidyl inhibitors from natural sources or functional food ingradients. Dipeptidyl peptidases cleaved dipeptide moieties from amino terminus of oligopepides so, they may be used to generate effective dipeptidyl ACE inhibitors. In present study, role of purified DPP-I and II in generation of ACE inhibitors have been explored. Results showed that collagen alpha-1(III) from chicken showed highest ACE inhibitory potential. Both dipeptidyl peptidases hydrolysed various potent inhibitory dipeptides from their oligopeptide precursors. In addition, sequential digestion of proteins with trypsin, DPP-I and II released approximate 15 % of total inhibitory peptides. Furthermore, inhibitory peptide concentration can be increased up to 30 % or more by using more proteases in presence of DPP-I and II. Results revealed that both DPP-I and II possesses the ability to generate ACE dipeptide inhibitors from oligopeptides. Still various dipeptidyl inhibitory peptides remained in generating oligopeptides, which required study of other endopeptidases with broad specificities.     

Cytochemistry of membrane proteases

Summary Membrane proteases that are detectable by cytochemical means are the classified exopeptidases, aminopeptidases A and M (or N), -glutamyl transpeptidase (which also acts as transferase), dipeptidyl peptidase IV and the endopeptidase, enteropeptidase (also known as enterokinase). Not yet classified are the possible expeptidase, tripeptidyl peptidase and endopeptidases I (Ala-endopeptidase) and II (Arg-endopeptidase). All these membrane proteases can be investigated with either chromogenic or fluorogenic procedures using synthetic peptide substrates. The most useful substrates are 4-methoxy-2-naphthylamine amino acids and peptides for cytochemical localizations at the light and electron microscope levels, for cytophotometric quantification and the study of membrane protease isoenzymes after analytical isoelectric focusing. Amino acid or peptide derivatives of naphthylamine AS can be recommended for light microscopical localization and cytofluorometric quantification, and 7-amino-4-methylcoumarin and 7-amino-4-trifluoromethylcoumarin amino acids and peptides for the development of enzyme bands after isoelectric focusing. Cytochemistry reveals the heterogeneity in the distribution and species differences of membrane proteases in adult cells, tissues and organs and during development. It also reveals some common localizations, such as in small intestinal enterocytes and proximal tubule cells. The species and organ differences are substantiated and extended considerably by isoelectric focusing in combination with methods for the cytochemical detection of proteases. In addition, continuous cytophotometry or cytofluorometry (section and cultured cell biochemistry) allows the kinetic characteristics, initial reaction rates and maximum activities of all membrane proteases to be determined.The physiological functions of the endopeptidases and exopeptidases are still a matter of debate. However, from cytochemical inhibition studies with natural peptide substrates, e.g. peptide hormones, there is increasing evidence that the proteases detected with synthetic peptides play a decisive role in many physiological circumstances, e.g. in endocrine regulation mechanisms or the regulation of blood pressure. In this respect, capillary endothelium-linked surface membrane proteases may be especially important.     

Towards the identification of unknown neuropeptide precursor-processing enzymes: Design and synthesis of a new family of dipeptidyl phosphonate activity probes for substrate-based protease identification

Specific proteolytic processing of inactive precursors is an exquisite cellular mechanism that triggers the activation of numerous physiologic peptides and proteins. This process ensures the generation of biologically active peptides, such as many neuropeptides and peptide hormones, in the appropriate cellular compartments at the right time, and its failure leads to several pathological conditions. Identification of the proteases involved in this limited proteolysis is, therefore, an essential step for the subsequent establishment of new therapeutic targets. As a first effort along this line, we synthesized eight new dipeptidyl phosphonate activity-based probes and used them to explore the soluble proteome from mouse brain and pituitary gland for substrate-based protease identification both by in-gel analysis and mass spectrometry.     

S1 pocket fingerprints of human and bacterial methionine aminopeptidases determined using fluorogenic libraries of substrates and phosphorus based inhibitors

Methionyl aminopeptidases (MetAPs) are metallo-dependent proteases responsible for removing of N-terminal methionine residue of peptides and proteins during protein maturation and activation. In this report we use a comprehensive strategy to screen the substrate specificity of three methionyl aminopeptidases: Homo sapiens MetAP-1, Homo sapiens MetAP-2 and Escherichia coli MetAP-1. By utilizing a 65-membered fluorogenic substrate library consisting of natural and unnatural amino acids we established detailed substrate preferences of each enzyme in the S1 pocket. Our results show that this pocket is highly conserved for all investigated MetAPs, very stringent for methionine, and that several unnatural amino acids with methionine-like characteristics were also well hydrolyzed by MetAPs. The substrate-derived results were verified using several phosphonate and phosphinate-based inhibitors.     

Interdependency of sequence and positional specificities for cysteine proteases of the papain family

The specificity of cysteine proteases is characterized by the nature of the amino acid sequence recognized by the enzymes (sequence specificity) as well as by the position of the scissile peptide bond (positional specificity, i.e., endopeptidase, aminopeptidase, or carboxypeptidase). In this paper, the interdependency of sequence and positional specificities for selected members of this class of enzymes has been investigated using fluorogenic substrates where both the position of the cleavable peptide bond and the nature of the sequence of residues in P2-P1 are varied. The results show that cathepsins K and L and papain, typically considered to act strictly as endopeptidases, can also display dipeptidyl carboxypeptidase activity against the substrate Abz-FRF(4NO2)A and dipeptidyl aminopeptidase activity against FR-MCA. In some cases the activity is even equal to or greater than that observed with cathepsin B and DPP-I (dipeptidyl peptidase I), which have been characterized previously as exopeptidases. In contrast, the exopeptidase activities of cathepsins K and L and papain are extremely low when the P2-P1 residues are A-A, indicating that, as observed for the normal endopeptidase activity, the exopeptidase activities rely heavily on interactions in subsite S2 (and possibly S1). However, cathepsin B and DPP-I are able to hydrolyze substrates through the exopeptidase route even in absence of preferred interactions in subsites S2 and S1. This is attributed to the presence in cathepsin B and DPP-I of specific structural elements which serve as an anchor for the C- or N-terminus of a substrate, thereby allowing favorable enzyme-substrate interaction independently of the P2-P1 sequence. As a consequence, the nature of the residue at position P2 of a substrate, which is usually the main factor determining the specificity for cysteine proteases of the papain family, does not have the same contribution for the exopeptidase activities of cathepsin B and DPP-I.     

Substrate specificity of collagenolytic proteases from the hepatopancreas of the of the Kamchatka crab]

The substrate specificity of two isozymes of collagenolytic protease of the crab (Paralithodes camtschatica) was studied. It was found that both proteases can effectively hydrolyze type I and III collagens, as well as gelatin, the set of products yielded by enzymatic hydrolysis being different for isozymes A and C. Hydrolysis of some well-known peptides revealed that isozyme A predominantly cleaves the peptide bonds containing arginine and lysine residues, whereas isozyme C predominantly hydrolyzes bonds containing hydrophobic amino acids. The catalytic constants for the hydrolysis of several low molecular weight substrates in the presence of P. camtschatica proteases were determined, which allowed to attribute isozyme A to trypsin-like, and isozyme C to chymotrypsin-like proteinases. The peptide substrates of collagenase, Pz-Pro-Leu-Gly-Pro-D-Arg and Z-Gly-Pro-Ala-Gly-Pro-Ala are not hydrolyzed isozymes of crab collagenolytic protease.     

Two novel targeting peptide degrading proteases, PrePs, in mitochondria and chloroplasts, so similar and still different

Two novel metalloproteases from Arabidopsis thaliana, termed AtPrePI and AtPrePII, were recently identified and shown to degrade targeting peptides in mitochondria and chloroplasts using an ambiguous targeting peptide. AtPrePI and AtPrePII are classified as dually targeted proteins as they are targeted to both mitochondria and chloroplasts. Both proteases harbour an inverted metal binding motif and belong to the pitrilysin subfamily A. Here we have investigated the subsite specificity of AtPrePI and AtPrePII by studying their proteolytic activity against the mitochondrial F(1)beta pre-sequence, peptides derived from the F(1)beta pre-sequence as well as non-mitochondrial peptides and proteins. The degradation products were analysed, identified by MALDI-TOF spectrometry and superimposed on the 3D structure of the F(1)beta pre-sequence. AtPrePI and AtPrePII cleaved peptides that are in the range of 10 to 65 amino acid residues, whereas folded or longer unfolded peptides and small proteins were not degraded. Both proteases showed preference for basic amino acids in the P(1) position and small, uncharged amino acids or serine residues in the P'(1) position. Interestingly, both AtPrePI and AtPrePII cleaved almost exclusively towards the ends of the alpha-helical elements of the F(1)beta pre-sequence. However, AtPrePI showed a preference for the N-terminal amphiphilic alpha-helix and positively charged amino acid residues and degraded the F(1)beta pre-sequence into 10-16 amino acid fragments, whereas AtPrePII did not show any positional preference and degraded the F(1)beta pre-sequence into 10-23 amino acid fragments. In conclusion, despite the high sequence identity between AtPrePI and AtPrePII and similarities in cleavage specificities, cleavage site recognition differs for both proteases and is context and structure dependent.     

Protease La, the lon gene product, cleaves specific fluorogenic peptides in an ATP-dependent reaction

Protease La is an ATP-dependent protease that catalyzes the rapid degradation of abnormal proteins and certain normal polypeptides in Escherichia coli. In order to learn more about its specificity and the role of ATP, we tested whether small fluorogenic peptides might serve as substrates. In the presence of ATP and Mg2+, protease La hydrolyzes two oligopeptides that are also substrates for chymotrypsin, glutaryl-Ala-Ala-Phe-methoxynaphthylamine (MNA) and succinyl-Phe-Leu-Phe-MNA. Methylation or removal of the acidic blocking group prevented hydrolysis. Closely related peptides (glutaryl-Gly-Gly-Phe-MNA and glutaryl-Ala-Ala-Ala-MNA) are cleaved only slightly, and substrates of trypsin-like proteases are not hydrolyzed. Furthermore, several peptide chloromethyl ketone derivatives that inhibit chymotrypsin and cathepsin G (especially benzyloxycarbonyl-Gly-Leu-Phe-chloro-methyl ketone), inhibited protease La. Thus its active site prefers peptides containing large hydrophobic residues, and amino acids beyond the cleavage site influence rates of hydrolysis. Peptide hydrolysis resembles protein breakdown by protease La in many respects: 1) ADP inhibits this process rapidly, 2) DNA stimulates it, 3) heparin, diisopropyl fluorophosphate, and benzoyl-Arg-Gly-Phe-Phe-Leu-MNA inhibit hydrolysis, 4) the reaction is maximal at pH 9.0-9.5, 5) the protein purified from lon- E. coli or Salmonella typhymurium showed no activity against the peptide, and that from lonR9 inhibited peptide hydrolysis by the wild-type enzyme. With partially purified enzyme, peptide hydrolysis was completely dependent on ATP. The pure protease hydrolyzed the peptide slowly when only Mg2+, Ca2+, or Mn2+ were present, and ATP enhanced this activity 6-15-fold (Km = 3 microM). Since these peptides cannot undergo phosphorylation, adenylylation, modification of amino groups, or denaturation, these mechanisms cannot account for the stimulation by ATP. Most likely, ATP and Mg2+ affect the conformation of the enzyme, rather than that of the substrate.     

Studies on Mold Proteases

The substrate specificity of the crystalline acid protease obtained from Rhizopus chinensis was determined using B-chain of oxidized beef insulin and numerous synthetic peptides, comparing with that of several acid proteases from various sources. The peptide bonds susceptible to the action of Rhiz. acid protease were found to be mainly those involving the amino group of bulky amino acids. The enzyme split the B-chain of oxidized insulin at twelve sites of the peptide linkages and a certain similarity in the specificity was observed among the three acid proteases, Rhiz. protease, rennin and pepsin, all of which were known to show potent milk clotting activities.     

Novel Dipeptidyl Peptidase IV Inhibitory and Antioxidant Peptides Derived from Human Gastrointestinal Endogenous Proteins

Human gastrointestinal endogenous proteins (GEP) include the proteins mucins, serum albumin, digestive enzymes, and proteins from sloughed epithelial and microbial-cells. GEP play a vital role in the digestion of food, but are also simultaneously digested by proteases and peptidases of the gastrointestinal tract (GIT). Recent studies suggest that during gastrointestinal digestion, similar to dietary proteins, GEP may also give rise to bioactive peptides. In the present study, the protein sequences of 11 representative GEP were subjected to simulated in silico GIT (SIGIT) digestion. Following SIGIT digestion, 19 novel GEP-derived peptide sequences were selected using quantitative structure activity relationship rules for chemical synthesis. The peptides were then tested for their in vitro dipeptidyl peptidase IV (DPP-IV) and 2,2-diphenyl-1-picrylhydrazyl (DPPH) inhibition, and for their ferric reducing antioxidant power (FRAP). Two novel DPP-IV inhibitory peptides with the amino acid sequences RPCF (IC₅₀ = 800.51 ± 49.00 µM) and MIM (IC₅₀ = 1056.78 ± 61.11 µM), and five novel antioxidant peptides CCK, RPCF, CRPK, QQCP and DCR were identified. The results of this study indicate that GEP are a significant source of bioactive peptides with potential novel bioactive peptide fragments within their sequences.     

Hydrolyse enzymatique des protéines par les bactéries du rumen

The hydrolysis of proteins in the rumen is a process brought about mainly by bacteria, of which many species produce proteases. The majority of endopeptidases are cysteine proteases, whereas exopeptidases are mainly aminopeptidases. Prevotella ruminicola is distinguished from other bacterial species by its capacity to produce dipeptidases such as type I dipeptidyl aminopeptidase. The mechanisms controlling the synthesis of endo- and exopeptidases have been little studied. Enzyme production seems to depend on the concentrations of peptides, amino acids and carbohydrates. Proteolytic activity varies in relation to pH, and the concentrations of ions and phenolic compounds. Various works have shown that hydrolysis of a protein by enzymes depends on its three-dimensional structure and possible bonding to non-protein structures. These properties determine the peptide and amino acid concentrations that occur in the rumen. The molecular weight, hydrophobic property and primary structure of the peptides are the main factors that affect the hydrolysis and/or uptake of these compounds by rumen bacteria. The methodological problems inherent to assaying these compounds do however lead to current divergences of opinion concerning the physico-chemical characteristics of the peptides that escape rumen fermentation.     

Endogenous regulatory oligopeptides: their structure, functions and localization

A number of problems connected with the study of several hundreds of known endogenous peptide molecules have been considered on the basis of data obtained from EROP-Moscow database. A large number of peptide structures can be reduced to a relatively small number of peptide families formed on the basis of homology of amino acid sequence. The ability of most peptides to participate in different regulatory systems of an organism has been demonstrated and the physical and chemical basis for specificity and ambiguity has been discussed. Most problems of structure, function, and localization of endogenous regulatory peptides are similar both in higher and in lower organisms.     

Extracellular peptidases of imaginal discs of Drosophila melanogaster

The imaginal discs of Drosophila melanogaster give rise to the adult epidermis during metamorphosis. During this developmental period several peptidase genes are expressed in disc cells, but there is a paucity of biochemical information regarding substrate specificity. We have used peptides and peptidyl 7-amino-4-methylcoumarin (AMC) substrates to detect several peptidases either positioned on the surface of wing discs or secreted by the imaginal cells. Using [Leu(5)]enkephalin as a substrate, a captopril sensitive dipeptidyl carboxypeptidase (angiotensin I-converting enzyme) and an amastatin-sensitive aminopeptidase were detected as prominent activities associated with intact discs. The formation of [Leu(5)]enkephalin-derived Phe was attributed to the concerted action of the D. melanogaster angiotensin I-converting enzyme (Ance) and a dipeptidase. The disc Ance also showed endopeptidic activity towards locust tachykinin-1 (LomTK-I) by cleaving the Gly-Val peptide bond, but this enzyme was not the sole endopeptidase activity associated with discs. Complete inhibition of the endopeptidic hydrolysis of the LomTK-1 by a disc homogenate required a combination of captopril and the neprilysin inhibitor, phosphoramidon, providing biochemical evidence for a neprilysin-like peptidase, in addition to Ance, in imaginal discs of D. melanogaster. Peptidyl AMC substrates for furin, prohormone convertase and tryptase provided evidence for trypsin-like serine endopeptidases in addition to the metalloendopeptidases. We conclude that imaginal discs are endowed with a variety of peptidases from different families that together are capable of hydrolyzing a broad range of peptides and proteins. Some of these peptidases might be responsible for the metabolic activation/inactivation of signaling peptides, as well as being involved in the production of dipeptides and free amino acids required for protein synthesis and osmotic balance during adult morphogenesis.