Studies on the specificity of acetylaminoacyl-peptide hydrolase.

In a continuing attempt to explore the types of specificity determinants that may affect protein-protein (peptide) interactions, a number of short (2-5 residues) acetylated peptides have been compared as substrates for the enzyme acetylaminoacyl-peptide hydrolase (EC 3.4.19.1). The reference substrate was Ac-AAAA, and most of the other substrates were derived from this basic structure by single amino acid substitutions. The Km and kcat for the different substrates were determined by standard steady-state kinetics, and the corresponding delta delta GT++ value derived from kcat/Km was used for the comparison, setting delta detal GT++ for Ac-AAAA equal to 0. The best substrates were found to be those containing negative charges (Asp > Glu) or aromatic residues in positions 1', 2', or 3' (delta delta GT++ values of 2-5 kJ); the negative charge provided by the C-terminus of the substrate also appears to be important, since the amide and O-Me ester derivatives caused a change in delta delta GT++ values of -7 to -8 kJ from the reference peptide. The stimulating effect of the negative charges is consistent with the inhibitory effect of positive charges in similar peptides (Krishna RG, Wold F, 1992, Protein Sci 1:582-589), and the proposed active site model incorporates subsites for both charge-charge and hydrophobic interactions. In assessing all the data, it is clear that the properties of the individual substrates reflect the total make-up of each peptide and not only the effect of a single residue in a given position.(ABSTRACT TRUNCATED AT 250 WORDS)     

Sequence requirements for the activity of membrane-active peptides.

Synthetic peptides were constructed with the sequence of the first 20 residues of melittin and terminating with a range of different amino acid amides. These were found to have haemolytic and cytolytic activity similar to that of melittin, provided that certain charge constraints were observed. The nature of the 21st residue was not critical except when the residue introduced a negative charge. The presence of at least two positive charges in the molecule was found to be essential for activity. One of these charges could be the amino-terminal amine. Peptides could be inactivated by the addition of a non-acidic presequence which was acetylated at the N-terminus. Introducing a protease cleavable sequence into an N-terminal extension of the peptides produced analogues with low haemolytic activity that could be activated by proteolytic action. A peptide with extra positive charges introduced on the hydrophilic face of the helix possessed a haemolytic activity that was greater than that of melittin.     

Purification and characterization of an N-acylaminoacyl-peptide hydrolase from rabbit muscle

An N-acylaminoacyl-peptide hydrolase has been purified to homogeneity (7,000-fold with 20% yield) from rabbit muscle. This overall enrichment and its general properties as a soluble protein suggest that it is of cytosolic origin and not a component of ribosomes or other cellular organelles. The enzyme has an Mr of 230,000-245,000 and a subunit Mr of 76,000-80,000. An extensive survey of the substrate specificity of the pure enzyme reveals that our earlier conclusions (Radhakrishna, G., and Wold, F. (1986) J. Biol. Chem. 261, 9572-9575) that the enzyme is specific for Ac-Met-peptides are wrong. The enzyme catalyzes the rapid removal of Ac-Thr, Ac-Ala, Ac-Met, Ac-Ser, and more slowly Ac-Gly from peptides of different lengths. Other acetylated amino acids (Cys, Tyr, Asp, Val, Phe, Ile, Leu) may be removed at 1% or less of the rate of the above good substrates from some peptide substrates. The nature of the amino acid in the second position of the acetylated peptide generally has only a minor effect on the reaction rate; however, with charged amino acids (Arg, Asp) in the second position the reaction is retarded, and with proline it is virtually abolished. Except for slow rate of hydrolysis of acetylated dipeptides, the hydrolase does not appear to be severely affected by the peptide length in the range studied (from 2 to 11 amino acid residues). The hydrolase also cleaves formylamino acids from formylated peptides. The biological function of the enzyme is not clear.     

Structural determinants for activity of glucagon-like peptide-2

Glucagon-like peptide-2 (GLP-2) is a 33 amino acid gastrointestinal hormone that regulates epithelial growth in the intestine. Dipeptidylpeptidase IV cleaves GLP-2 at the position 2 alanine, resulting in the inactivation of peptide activity. To understand the structural basis for GLP-2 action, we studied receptor binding and activation for 56 GLP-2 analogues with either position 2 substitutions or alanine replacements along the length of the peptide. The majority of position 2 substitutions exhibited normal to enhanced GLP-2 receptor (GLP-2R) binding; in contrast, position 2 substitutions were less well tolerated in studies of receptor activation as only Gly, Ile, Pro, alpha-aminobutyric acid, D-Ala, or nor-Val substitutions exhibited enhanced GLP-2R activation. In contrast, alanine replacement at positions 5,6,17, 20, 22, 23, 25, 26, 30, and 31 led to diminished GLP-2R binding. Position 2 substitutions containing Asp, Leu, Lys, Met, Phe, Trp, and Tyr, and Ala substitutions at positions 12 and 21 exhibited normal to enhanced GLP-2R binding but greater than 75% reduction in receptor activation. D-Ala(2), Pro(2) and Gly(2), Ala(16) exhibited significantly lower EC(50)s for receptor activation than the parent peptide (p < 0.01-0.001). Circular dichroism analysis indicated that the enhanced activity of these GLP-2 analogues was independent of the alpha-helical content of the peptide. These results indicate that single amino acid substitutions within GLP-2 can confer structural changes to the ligand-receptor interface, allowing the identification of residues important for GLP-2R binding and receptor activation.     

Investigating the effect of different positioning of lysine residues along the peptide chain of mastoparans for their secondary structures and biological activities

In order to investigate the effect of the different positions of the positive charges generated by the ionization of the side-chain of lysine residues, on the structure–activity relationship of the mastoparans, the peptides Protonectarina-MP (INWKALLDAAKKVL-NH2), Parapolybia-MP (INWKKMAATALKMI-NH2) and Asn-2-Polybia-MP I (INWKKLLDAAKQIL-NH2) and MK-578 (INWLKAKKVAGMIL-NH2) were investigated as models. Thus, the four peptides had their secondary structure studied and were submitted to assays of mast cell degranulation, hemolysis, and antibiosis. The results of the bioassays made clear that those peptides bearing the positive charges positioned at the positions 4/5 and/or from 11 to 13 are the most active ones; meanwhile, the localization of the positive charges in the middle of peptide chain resulted in a poorly active peptide. Thus, Protonectarina-MP, Parapolybia-MP, and Asn-2-Polybia-MP I presented physiologically important hemolysis and antibiosis, while MK-578 presented only a reduced antibiotic activity. Circular dichroism analysis were carried-out in different environments revealing that the anionic environment of a mixture of phosphatidylcholine and phosphatidylglycerol (70:30) liposomes favored the higher helical content of the four peptides in this study in relation to the zwiterionic environment of 100% phosphatidylcholine liposomes. The positioning of the lysine residues at the strategic positions (4/5 and 11–13), flanking and maintaining stable α-helix which extends from the 4th to the 13th residue along the peptide chain, seems to contribute to maximal lytic efficiency of the mastoparans, which in turn results in a more homogeneous hydrophobic surface in the amphipathic structure.     

Influence of dietary acetylated peptides on fermentation and peptidase activities in the sheep rumen

The predominant mechanism of peptide breakdown by rumen micro-organisms is aminopeptidase. Thus acetylation of the N-terminus of peptides inhibits their degradation by rumen micro-organisms in short-term incubations with rumen fluid in vitro . An experiment was undertaken to determine if adaptation of the rumen microbial population would take place when acetylated peptides were fed for a prolonged period, which would enable the microbial population to break down the protected peptides and thus decrease their nutritive value. Three adult sheep, fitted with permanent rumen cannulae, received a maintenance hay/concentrate diet to which was added, at each meal, 20 g of casein enzymic hydrolysate ('peptides') or 20 g of peptides previously treated with acetic anhydride. The diets were fed for 28 d in a 3 × 3 latin square and samples were taken during the last 7 d. Fermentation products and NH₃ concentrations indicated that acetylated peptides remained less degradable than untreated peptides. There was a trend towards increased proteolytic activity with acetylated peptides, and dipeptidase activity increased by 18% and 28%, respectively, compared with untreated peptides and control treatments. Activity against N-acetyl-Ala₂ also increased when acetylated peptides were fed, but it remained only 13% of the rate of Ala₂ hydrolysis. No increase was found in the rate of ammonia production from acetylated peptides in animals receiving acetylated peptides–this rate was 26% of that found with untreated peptides–and acetylated peptides continued to persist for longer in the rumen than untreated peptides after feeding. Thus it was concluded that the rumen microbial population did not adapt to utilize acetylated peptides.     

N-Terminal sequences of α-crystallin

The amino acid sequences at the N-terminal ends of the chains of the lens protein, alpha-crystallin, were studied. Both the main kinds of chain in bovine alpha-crystallin (A chains and B chains) have an N-terminal methionine residue, and the amino group is acetylated. Selective purification of the peptides in a tryptic digest of bovine alpha-crystallin gave a preparation consisting largely of the N-terminal peptide from the A chains, and the sequence of this peptide was elucidated. Subsequently, the N-terminal peptides were prepared from separated A and B chains. The proposed sequences are: A chain, acetyl-Met-Asp-Ile-Ala-Ile-Gln-His-Pro-Trp-Phe-Lys; B chain, acetyl-Met-Asp-Ile-Ala-Ile-His-(Pro,Trp)-Ile-Arg. The similarity between the sequences supports the hypothesis that the A and B chains are derived evolutionarily from a common precursor.     

Antibacterial and haemolytic peptides containing D-alloisoleucine from the skin of Bombina variegata.

A family of bombinin-related peptides is present in the skin of Bombina variegata. These peptides contain 27 residues with Gly as N-terminus and display antimicrobial activity. From sequence analysis of the cDNAs encoding for the corresponding peptide precursors, the presence of a novel 20-residue peptide with Ile as N-terminus was predicted. We have now purified a family of hydrophobic peptides named H1-H5, whose sequences correspond to the predicted peptide with some variability in positions 1, 2 and 8. In particular, H3-H5 contain a D-alloisoleucine residue in the second position. All these peptides display antibacterial and haemolytic activity.     

New indolicidin analogues with potent antibacterial activity.

Indolicidin is a 13-residue antimicrobial peptide amide, ILPWKWPWWPWRR-NH2, isolated from the cytoplasmic granules of bovine neutrophils. Indolicidin is active against a wide range of microorganisms and has also been shown to be haemolytic and cytotoxic towards erythrocytes and human T lymphocytes. The aim of the present paper is two-fold. First, we examine the importance of tryptophan in the antibacterial activity of indolicidin. We prepared five peptide analogues with the format ILPXKXPXXPXRR-NH2 in which Trp-residues 4,6,8,9,11 were replaced in all positions with X = a single non-natural building block; N-substituted glycine residue or nonproteinogenic amino acid. The analogues were tested for antibacterial activity against both Staphylococcus aureus American type culture collection (ATCC) 25923 and Escherichia coli ATCC 25922. We found that tryptophan is not essential in the antibacterial activity of indolicidin, and even more active analogues were obtained by replacing tryptophan with non-natural aromatic amino acids. Using this knowledge, we then investigated a new principle for improving the antibacterial activity of small peptides. Our approach involves changing the hydrophobicity of the peptide by modifying the N-terminus with a hydrophobic non-natural building block. We prepared 22 analogues of indolicidin and [Phe(4,6,8,9,11)] indolicidin, 11 of each, carrying a hydrophobic non-natural building block attached to the N-terminus. Several active antibacterial analogues were identified. Finally, the cytotoxicity of the analogues against sheep erythrocytes was assessed in a haemolytic activity assay. The results presented here suggest that modified analogues of antibacterial peptides, containing non-natural building blocks, are promising lead structures for developing future therapeutics.     

Solid-phase synthesis and applications of N-(S-acetylmercaptoacetyl) peptides

The reagent pentafluorophenyl S-acetylmercaptoacetate was used to modify the N-terminus of resin-bound side-chain-protected peptides. The modification was carried out in an automated cycle in the final stage of fluorenylmethoxycarbonyl (Fmoc)/polyamide-mediated solid-phase synthesis. Side-chain deprotection and cleavage from the resin with aqueous trifluoroacetic acid gave the N-(S-acetylmercaptoacetyl) peptides. The S-acetylmercaptoacetyl peptides were transformed into reactive thiol-containing peptides by incubation with hydroxylamine at neutral pH. The S-deacetylation was performed in the presence of a sulfhydryl-reactive compound (or intramolecular group) to enable immediate capture of the sensitive thiol. Three applications were investigated. An S-acetylmercaptoacetyl peptide, containing a sequence of a meningococcal membrane protein, was incubated with hydroxylamine in the presence of 5-(iodoacetamido)fluorescein to give the corresponding fluorescein-labeled peptide in 62% yield. The same peptide was also S-deacetylated in the presence of bromoacetylated poly-L-lysine to afford a peptide/polylysine conjugate. Finally, a peptide corresponding to a sequence of herpes simplex virus glycoprotein D was prepared. This peptide, containing an N-terminal-S-acetylmercaptoacetyl group and an additional C-terminal S-(3-nitro-2-pyridinesulfenyl)cysteine residue, was converted into a cyclic disulfide peptide (20%).     

Acylpeptide hydrolase activity from erythrocytes

Acylpeptide hydrolase, which cleaves the NH2-terminal acetylated or formylated amino acid from a blocked peptide, has been purified to apparent homogeneity from human erythrocytes. The enzyme catalyzes the hydrolysis of a diverse number of peptides and displays different pH optima for certain substrates in doing so. Zinc inhibits to the same extent the hydrolysis of both the most efficient and the least efficient substrates. This enzyme may play a pivotal role in the processing of polypeptide chains during biosynthesis.     

Enzyme-mediated peptide synthesis using acylpeptide hydrolase.

Acylpeptide hydrolase is shown to catalyse the specific addition of a single amino acid to the N-terminus of a peptide. The stabilised Sepharose-coupled form of the enzyme is used to couple a carboxy-methylated N-formyl (or N-acetyl) amino acid to a short pre-existing peptide. The yield is improved by optimal timing of the reaction and the presence of moderate concentrations (5%) of N,N-dimethylformamide. Two tripeptides, Ac-Ala-Ala-Ala and fMet-Leu-Phe (f, formyl) were synthesized by this technique (in yields of 2% and 0.064% respectively). The products were characterised by HPLC, amino acid analysis, mass spectroscopy and protein sequencing. The synthetic fMet-Leu-Phe also had biological activity, in that it stimulated superoxide generation by granulocytes. Acylpeptide hydrolase could therefore be a very useful tool for the synthesis and modification of peptides.     

Characterisation of rhodococci using peptide hydrolase substrates based on 7-amino-4-methylcoumarin

Enzyme activity profiles of 105 rhodococci and related actinomycetes were obtained using peptide hydrolase substrates based on 7-amino-4-methylcoumarin. All of the test strains produced l-alanyl-, l-lysyl-, l-methionyl, l-seryl-, l-tyrosyl, S-Bz-l-cysteinyl and l-alanyl-l-alanyl-l-phenyl-alanyl-peptidases but the distribution of the remaining enzymes gave results of differential value. Fluorogenic probes prepared from 7-amino-4-methylcoumarin provide a simple and rapid means of detecting specific exo- and endopeptidases in small amounts of whole rhodococci.     

Block of Brain Sodium Channels by Peptide Mimetics of the Isoleucine,Phenylalanine, and Methionine (IFM) Motif from the Inactivation Gate

Inactivation of sodium channels is thought to be mediated by an inactivation gate formed by the intracellular loop connecting domains III and IV. A hydrophobic motif containing the amino acid sequence isoleucine, phenylalanine, and methionine (IFM) is required for the inactivation process. Peptides containing the IFM motif, when applied to the cytoplasmic side of these channels, produce two types of block: fast block, which resembles the inactivation process, and slow, use-dependent block stimulated by strong depolarizing pulses. Fast block by the peptide ac-KIFMK-NH₂, measured on sodium channels whose inactivation was slowed by the α-scorpion toxin from Leiurus quinquestriatus (LqTx), was reversed with a time constant of 0.9 ms upon repolarization. In contrast, control and LqTx-modified sodium channels were slower to recover from use-dependent block. For fast block, linear peptides of three to six amino acid residues containing the IFM motif and two positive charges were more effective than peptides with one positive charge, whereas uncharged IFM peptides were ineffective. Substitution of the IFM residues in the peptide ac-KIFMK-NH₂ with smaller, less hydrophobic residues prevented fast block. The positively charged tripeptide IFM-NH₂ did not cause appreciable fast block, but the divalent cation IFM-NH(CH₂)₂NH₂ was as effective as the pentapeptide ac-KIFMK-NH₂. The constrained peptide cyclic KIFMK containing two positive charges did not cause fast block. These results indicate that the position of the positive charges is unimportant, but flexibility or conformation of the IFM-containing peptide is important to allow fast block. Slow, use-dependent block was observed with IFM-containing peptides of three to six residues having one or two positive charges, but not with dipeptides or phenylalanine-amide. In contrast to its lack of fast block, cyclic KIFMK was an effective use-dependent blocker. Substitutions of amino acid residues in the tripeptide IFM-NH₂ showed that large hydrophobic residues are preferred in all three positions for slow, use-dependent block. However, substitution of the large hydrophobic residue diphenylalanine or the constrained residues phenylglycine or tetrahydroisoquinoline for phe decreased potency, suggesting that this phe residue must be able to enter a restricted hydrophobic pocket during the binding of IFM peptides. Together, the results on fast block and slow, use-dependent block indicate that IFM peptides form two distinct complexes of different stability and structural specificity with receptor site(s) on the sodium channel. It is proposed that fast block represents binding of these peptides to the inactivation gate receptor, while slow, use-dependent block represents deeper binding of the IFM peptides in the pore.     

Rabbit muscle extracts catalyze the specific removal of N-acetylmethionine from acetylated peptides

Rabbit muscle has been found to contain an activity that catalyzes the specific removal of Ac-Met from acetylated peptides. The activity is associated with free ribosomes and microsomes in the rabbit muscle extract but can be removed from these subcellular fractions by exposure to 0.5 M NaCl in the presence of 2 mM MgCl2; only partial removal was achieved with microsomes, but complete removal with ribosomes. A nearly 200-fold enrichment of the activity was achieved by this simple succession of differential centrifugation and salt extraction. Eighteen 14C-acetylpeptides have been tested as substrates for the partially purified activity assaying for the production of free 14C-acetylamino acid by high performance liquid chromatography. None of the peptides containing N-terminal acetylated Ala, Asp, Ser, or Gly were cleaved at a significant rate. Six of a total of eight peptides containing N-terminal Ac-Met were cleaved by the ribosomal extract at different rates. The active substrates varied in length from tri- to undecapeptides. The activity is inhibited by high concentrations of the protease inhibitor phenylmethylsulfonyl fluoride. Based on these observations, we tentatively conclude that the activity satisfy the criteria of a general N-terminal protein processing enzyme: it can remove Ac-Met from most, but not all, N-terminal sequences and appears to be inactive toward the N-terminal acetylamino acids most commonly found in eukaryotic proteins.     

Protease profiling using a fluorescent domino peptide cocktail

Five hexapeptides were prepared containing, in a domino-type arrangement, all 25 possible dipeptides between (1) aromatic, (2) hydrophobic, (3) positively charged, (4) negatively charged, and (5) small and polar amino acids. The peptides were fluorescence labeled at the N-terminus with a (7-coumaryl)oxyacetyl group, allowing the selective detection of N-terminal cleavage products. The five peptides were used as a cocktail reagent in an HPLC analysis. The cocktail produced specific cleavage patterns, or fingerprints, for a variety of proteases. This domino peptide cocktail can be used as a general reagent for protease identification and functional profiling.     

Surprisingly high stability of barley lipid transfer protein, LTP1, towards denaturant, heat and proteases

Tripeptidyl peptidase-I (TPP-I) is a lysosomal peptidase which cleaves tripeptides from the N-terminus of peptides. The function of the enzyme is unclear but its importance is demonstrated by the fact that mutations in TPP-I are responsible for late infantile neuronal ceroid lipofuscinosis, a lethal lysosomal storage disease. As a step towards identifying its natural substrates, we have used a series of synthetic peptides, based on angiotensin-II, to explore the effects of peptide chain length and the effects of amino acid substitutions at the P₁ and P₁′ positions on the rate of catalysis. With the exception of angiotensin-(1–8) (angiotensin-II), which is a relatively poor substrate for TPP-I, the rate of catalysis increases with increasing chain length. K_cat/K_m values increase 50-fold between angiotensin-(1–5) and angiotensin-(1–14). TPP-I shows little specificity for the nature of the amino acids in the P₁ and P₁′ positions, K_cat/K_m values varying only 5-fold for a range of substitutions. However, Pro or Lys in the P₁ position and Pro in the P₁′ positions are incompatible with TPP-I activity. These observations suggest that TPP-I is a non-specific, but essential, peptidase involved in the latter stages of lysosomal protein degradation.     

Conformational Properties of Seven Toac-Labeled Angiotensin I Analogues Correlate with Their Muscle Contraction Activity and Their Ability to Act as ACE Substrates

Conformational properties of the angiotensin II precursor, angiotensin I (AngI) and analogues containing the paramagnetic amino acid TOAC (2,2,6,6-tetramethylpiperidine-1-oxyl-4-amino-4-carboxylic acid) at positions 0, 1, 3, 5, 8, 9, and 10, were examined by EPR, CD, and fluorescence. The conformational data were correlated to their activity in muscle contraction experiments and to their properties as substrates of the angiotensin I-converting enzyme (ACE). Biological activity studies indicated that TOAC⁰-AngI and TOAC¹-AngI maintained partial potency in guinea pig ileum and rat uterus. Kinetic parameters revealed that only derivatives labeled closer to the N-terminus (positions 0, 1, 3, and 5) were hydrolyzed by ACE, indicating that peptides bearing the TOAC moiety far from the ACE cleavage site (Phe⁸-His⁹ peptide bond) were susceptible to hydrolysis, albeit less effectively than the parent compound. CD spectra indicated that AngI exhibited a flexible structure resulting from equilibrium between different conformers. While the conformation of N-terminally-labeled derivatives was similar to that of the native peptide, a greater propensity to acquire folded structures was observed for internally-labeled, as well as C-terminally labeled, analogues. These structures were stabilized in secondary structure-inducing agent, TFE. Different analogues gave rise to different β-turns. EPR spectra in aqueous solution also distinguished between N-terminally, internally-, and C-terminally labeled peptides, yielding narrower lines, indicative of greater mobility for the former. Interestingly, the spectra of peptides labeled at, or close, to the C-terminus, showed that the motion in this part of the peptides was intermediate between that of N-terminally and internally-labeled peptides, in agreement with the suggestion of turn formation provided by the CD spectra. Quenching of the Tyr⁴ fluorescence by the differently positioned TOAC residues corroborated the data obtained by the other spectroscopic techniques. Lastly, we demonstrated the feasibility of monitoring the progress of ACE-catalyzed hydrolysis of TOAC-labeled peptides by following time-dependent changes in their EPR spectra.     

Removal of N-acetyl groups from blocked peptides with acylpeptide hydrolase. Stabilization of the enzyme and its application to protein sequencing

Acylpeptide hydrolase, an enzyme that removes the modified residue from N-terminally acetylated peptides, has been purified from ovine liver and developed as a tool in sequencing blocked peptides and proteins. Its instability imposes a major limitation on the use of the mammalian enzyme in protein chemistry. Coupling to Sepharose followed by intramolecular cross-linking with dimethyl-suberimidate increased its thermostability and rendered it more resistant to inactivation by either SDS or N,N-dimethylformamide. The resulting enzyme preparation is reusable and more effective at cleaving longer acetylated peptides. It is therefore useful for unblocking acetylated proteins prior to protein sequence analysis. Intact proteins and many isolated peptides are still too large to be cleaved directly, but in this paper we describe a procedure for overcoming this difficulty. The protein is fragmented and non-acetylated peptides are then absorbed out with isothiocyanato-glass. The N-terminal peptide remains in solution and is unblocked with stabilised acylpeptide hydrolase. No chromatographic separation are required. The N-terminal sequence can then be obtained by automated Edman degradation. This procedure has been successfully demonstrated on a large synthetic peptide.     

Development of a potent bombesin receptor antagonist with prolonged in vivo inhibitory activity on bombesin-stimulated amylase and protein release in the rat.

Of the various types of potent bombesin(Bn)/gastrin releasing peptide receptor antagonists that have been discovered, the desMet14-methyl ester peptides are devoid of residual agonist activity and are among the most potent in terms of in vitro receptor blockade and also in terms of their prolonged inhibition of bombesin-stimulated amylase and protein release in the rat. We have now examined the in vitro and in vivo properties of a new series of methyl ester analogues, [D-Phe6]Bn(6-13)OMe, [D-Phe6,D-Ala11]Bn(6-13)OMe, N alpha-propionyl-[D-Ala24]GRP(20-26)OMe, and [D-pentafluoro-Phe6,D-Ala11]Bn(6-13)OMe, which have an additional D-amino acid substituent and some highly lipophilic moieties at the N-terminus. All analogues were able to potently antagonize the ability of Bn to stimulate amylase release from rat acinar cells, with IC50 values of 2.4, 2.5, 0.6, and 1.3 nM, respectively. The four peptides were found to have binding affinities for these cells comparable to Bn itself, with K(i)s of 10.3, 2.8, 5.5, and 3.6 nM, respectively, but all had little or no affinity for neuromedin B receptors on murine C6 cells. Single bolus IV injections of these peptides were found to potently inhibit amylase and protein release caused by IV infusion of bombesin into the rat. Generally the peptides containing the D-Ala substituent were longer acting than [D-Phe6]Bn(6-13)OMe, so that [D-Phe6,D-Ala11]Bn(6-13)OMe and N alpha-propionyl-[D-Ala24]GRP(20-26)OMe displayed significant inhibitory effects for up to 1.5 h after administration.(ABSTRACT TRUNCATED AT 250 WORDS)