Des-Met14]bombesin analogues function as small cell lung cancer bombesin receptor antagonists.

A series of bombesin (BN) analogues lacking the C-terminal methionine at the 14 position were evaluated as BN receptor antagonists. [D-Phe6]BN(6-13)amide inhibited specific 125I-GRP binding to lung cancer cell line NCI-H720 with an IC50 value of 12 nM. In contrast, [D-Phe6]BN(6-13)propylamide, butylamide and methylester were more potent with IC50 values of 3, 5 and 5 nM whereas [D-Phe6,Sta13]BN(6-13)amide was less potent with an IC50 value of 180 nM. [D-Phe6]BN(6-13)propylamide antagonized the ability of BN to elevate cytosolic Ca2+, whereas [D-Phe6]BN(6-13)butylamide was a partial agonist. In a small cell lung cancer (SCLC) growth assay, [D-Phe6]BN(6-13)propylamide inhibited colony formation. In summary, BN analogues which lack a C-terminal methionine may function as useful SCLC BN receptor antagonists.     

Desmethionine alkylamide bombesin analogues: a new class of bombesin receptor antagonists with potent antisecretory activity in pancreatic acini and antimitotic activity in Swiss 3T3 cells.

Bombesin-related peptides have a large number of physiological functions as well as having an autocrine growth mechanism for the regulation of small cell lung cancer cells. In the present study we have synthesized 21 des-Met amide or alkylamide analogues of bombesin and compared their abilities to function as bombesin receptor antagonists in guinea pig pancreatic acini and Swiss 3T3 cells with those of the previously most potent antagonist described, [Leu13 psi(CH2NH)Leu14]bombesin (analogue I). All des-Met analogues functioned as antagonists. Bn(1-13)NH2 was approximately equipotent to I (Ki = 60-80 nM) whereas Bn(6-13)NH2 was 30-fold less potent (Ki = 1800 nM). Formation of an ethylamide, Bn(6-13)ethylamide, increased the potency 30-fold such that this octapeptide was equipotent to I. The addition of a D-Phe6 moiety to I did not change potency but caused a 30-fold increase in potency of Bn(6-13)NH2 and a 8-fold increase in the potency of Bn(6-13)ethylamide (Ki = 16 nM). Additional studies of both NH2- and COOH-terminal alterations in Bn(6-13)NH2 demonstrated that the most potent antagonist was [D-Phe6]Bn(6-13)propylamide (PA), having IC50's of 1.6 nM and 0.8 nM for bombesin-stimulated amylase release and Swiss 3T3 cell growth, respectively. Detailed studies of the most potent amide analogue, [D-Phe6]Bn(6-13)NH2, and alkylamide analogue, [D-Phe6]Bn(6-13)PA, demonstrated that these analogues functioned as competitive antagonists and that their action was selective for the bombesin receptor. These results demonstrate that, as with CCK- and gastrin-related peptides, the C-terminal amino acid is important for initiating a biologic response but not essential for determining receptor affinity.(ABSTRACT TRUNCATED AT 250 WORDS)     

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)     

des-Met carboxyl-terminally modified analogues of bombesin function as potent bombesin receptor antagonists, partial agonists, or agonists.

In the present study we examined the effect of carboxyl-terminal modifications of des-Met14-bombesin (Bn) on Bn receptor affinity in murine 3T3 cells, rat and guinea pig pancreatic acini, and the ability to initiate biologic responses by synthesizing 18 des-Met14-Bn(6-13) analogues. With guinea pig acini and 3T3 cells, affinity was affected by the chain length of the alkyl moiety (R) added to [D-Phe6]Bn(6-13)NH2R with relative potencies: propyl greater than ethyl greater than butyl = hexyl greater than heptyl greater than free amide, whereas in rat acini affinity was not increased by the chain length. In each cell system the affinity of the alkylamide was not increased by insertion of a phenyl group in the alkyl side chain, by making the analogue more neuromedin B-like or by addition of a reduced peptide bond. The affinity in each cell system was increased by additions of other electron releasing groups to the COOH-terminal carboxyl group such as [D-Phe6]Bn(6-13)ethyl or methyl ester, or hydrazide. In guinea pig pancreas and 3T3 cells, 12 analogues were antagonists, 1 a full and 5 partial agonists. In rat pancreas, 8 were antagonists, 5 full agonists, and 5 partial agonists. Potent antagonists in each cell system were the methyl and ethyl ester, hydrazide, and ethylamide analogues. In 3T3 cells or guinea pig pancreas, agonist activity of the alkylamide was critically dependent on the chain length, whereas with rat pancreatic Bn receptors any alkylamide longer than the ethylamide had agonist activity. In all three cell systems any alteration that made the alkylamide more neuromedin B-like caused agonist activity. These results demonstrate that the nature of the substitution on the carboxyl terminus of des-Met14-Bn analogues is critically important, not only for determining Bn receptor affinity, but also for determining the ability to initiate a biologic response. In contrast to previous studies, the present results demonstrate that the presence of the COOH-terminal amino acid in position 14 of Bn is not essential for initiating a biologic response. Several des-Met14-Bn analogues were potent partial agonists, whereas others such as the hydrazide or ethyl ester are very potent antagonists.     

Short-chain pseudopeptide bombesin receptor antagonists with enhanced binding affinities for pancreatic acinar and Swiss 3T3 cells display strong antimitotic activity

The high inhibitory potency of the previously developed bombesin antagonist [Leu13, psi CH2NHLeu14]bombesin (analogue I) (IC50 values of 30 and 18 nM for inhibition of bombesin-stimulated amylase secretion from guinea pig acinar cells and Swiss 3T3 cell growth, respectively) diminished considerably when shorter chain lengths were examined. For instance, [Leu13, psi CH2NHLeu14]bombesin-(5-14),[Leu13, psi CH2NHLeu14] bombesin-(6-14), and [Leu9, psi CH2NHLeu10]neuromedin C had IC50 values of 150, 150, and 280 nM, respectively. Incorporation of a D-Phe residue at position 6 of [Leu13, psi CH2NHLeu14] bombesin did not significantly change the various biological parameters. However, its presence in [Leu13, psi CH2NHLeu14]bombesin-(6-14) and at position 2 of psi-neuromedin C-(2-10) resulted in about 10-fold increases in potency up to and above that of the original antagonist. For instance, [D-Phe6,Leu13,psi CH2NHLeu14]bombesin-(6-14) and des-Gly1-[D-Phe2,Leu9,psi CH2NHLeu10]neuromedin C exhibited IC50 values of 5 and 28 nM, respectively. Analogues based on the litorin sequence which contains an NH2-terminal pyroglutamic acid residue at the bombesin position 6 equivalent were also quite potent. The ability of various analogues to interact with bombesin receptors on pancreatic acini correlated reasonably well with potencies derived from inhibition of bombesin-stimulated growth of Swiss 3T3 cells. Additional studies of NH2- and COOH-terminal structure-activity relationships resulted in the synthesis of [D-Phe6,Leu13,psi CH2NHPhe14]bombesin-(6-14), which was particularly effective in inhibiting 3T3 cell growth at high picomolar concentrations (IC50 = 0.72 nM and Ki = 3.1 nM for 3T3 cells; IC50 = 7.5 nM and Ki = 9.9 nM for acini). Detailed investigations with one of the most potent antagonists, [D-Phe6,Leu13,psi CH2NHLeu14]bombesin-(6-14) (Ki = 14 nM for acini cells and 7.1 for 3T3 cells), demonstrated that this analogue was a competitive inhibitor of bombesin and that this activity was specific for the bombesin receptor. Thus, inhibitory potencies have been improved generally up to 25 times over previously reported structures; and, given that bombesin itself has a Ki of 1.2 nM for 3T3 cell binding, some of these analogues are extraordinarily high affinity receptor antagonists. They can also be synthesized more readily and offer fewer proteolytic degradation sites than the original pseudopeptide and should be excellent candidates for in vivo studies aimed at inhibition of bombesin-dependent human small cell lung carcinoma growth.     

Effects of potent bombesin antagonist on exocrine pancreatic secretion in rats.

Recent synthesis of specific, potent bombesin receptor antagonists allows examination of the role of bombesin-like peptides in physiological processes in vivo. We characterized effects of [D-Phe6]bombesin(6-13)-methyl-ester (BME) on pancreatic enzyme secretion stimulated by the C-terminal decapeptide of gastrin releasing peptide (GRP-10), food intake, and diversion of bile-pancreatic juice in rats. In isolated pancreatic acini, BME had no agonistic effects on amylase secretion but competitively inhibited responses to GRP-10, yielding a pA2 value of 8.89 +/- 0.19. In conscious rats with gastric, jugular vein, bile-pancreatic, and duodenal cannulas, basal enzyme secretion (bile-pancreatic juice recirculated) was not affected by the antagonist. Maximal amylase response to GRP-10 (0.5 nmol/kg/h) was inhibited dose dependently by BME, reaching 97% inhibition at a dose of 400 nmol/kg/h. The dose response curve of amylase secretion stimulated by GRP-10 was shifted to the right by 40 nmol/kg/h BME, but maximal amylase response was unaltered, suggesting competitive inhibition in vivo. Liquid food intake and bile-pancreatic juice diversion caused substantial increases in amylase secretion; neither response was altered during administration of 400 pmol/kg/h BME. These results demonstrate that BME is a potent, competitive antagonist of pancreatic responses to bombesin-like peptides in vitro and in vivo. Lack of effect of BME on basal pancreatic secretion or responses to liquid food intake or diversion of bile-pancreatic juice in rats suggests that endogenous bombesin-like peptides do not act either directly or indirectly to mediate these responses.     

Systematic optimization of a lead-structure identities for a selective short peptide agonist for the human orphan receptor BRS-3.

The orphan receptor, human bombesin receptor subtype 3 (BRS-3) was assigned to the G-protein coupled bombesin receptor family because of its high sequence homology with the neuromedin B receptor (NMB-R) and gastrin-releasing peptide receptor (GRP-R). Since its pharmacology is stiIl unknown, new highly potent and selective tool-substances are needed, that may be able to elucidate its possible role in obesity and cancer. We have performed structure activity relationship studies on the high affinity peptide agonists [D-Phe6,beta-Ala11,Phe13,Nle14]Bn(6-14) and [D-Phe6,Phe13]Bn(6-13)propylamide, using their ability to mobilize intracellular calcium in BRS-3 transfected CHOGa-16 cells combined with receptor binding studies. It was demonstrated that for [D-Phe,beta-Ala11,Phe13,Nle14]Bn(6-14) the side chains of the residues Trp8 and Phe13, and to a smaller extent beta-Ala11, are the important amino acid side chains for receptor activation and binding, however for [D-Phe6,Phe13]Bn(6-13) propylamide His12 seems to be more important than Phe13. C-and N-terminal deletions and amino acid substitutions allowed further understanding. It was demonstrated that substitution of His 12 by Tyr leads to a high selectivity towards GRP-R. Using the acquired information, a small tetrapeptide library was designed with compounds presenting Trp and Phe at varying stereochemistry and distances, which led to the discovery of the lead-structure H-D-Phe-Gln-D-Trp-Phe-NH2. Systematic SAR revealed the important structural features of this peptide, C-terminal optimization resulted in the highly active and selective BRS-3 agonist H-D-Phe-Gln-D-Trp-1-(2-phenylethyl)amide. In summary, the size of the peptide was reduced from 8 or 9 amino acids to a tripeptide for BRS-3.     

Bombesin-modified 6-14 C-terminal fragments adsorption on silver surfaces: influence of a surface substrate

Surface-enhanced Raman scattering (SERS) spectroscopy has been applied to investigate the interaction with a silver colloidal surface of following seven 6-14 fragments of bombesin (BN) C-terminus: cyclo[D-Phe(6),His(7),Leu(14)]BN(6-14), [D-Phe(6),Leu-NHEt(13),des-Met(14)]BN(6-14), [D-Phe(6),Leu(13)-(R)-p-chloro-Phe(14)]BN(6-14), [D-Phe(6),beta-Ala(11),Phe(13),Nle(14)]BN(6-14), [D-Tyr(6),beta-Ala(11),Phe(13),Nle(14)]BN(6-14), [D-Tyr(6),beta-Phe(11),Phe(13),Nle(14)OH]BN(6-14), and [D-Cys(6),Asn(7),D-Ala(11),Cys(14)]BN(6-14), potent r-GRP-R receptor antagonists used in chemotherapy and potential effective drugs in cancer treatment. The adsorption active sites and molecular orientations on the colloidal silver surface have been determined on the basis of SERS "surface selection rules" subsequent to a detailed SERS analysis. In addition, the similarities and differences of these spectra with the SERS spectra of the peptides immobilized on a roughened silver electrode surface have been examined. From the data, suggestion has been made about structural properties of these peptides on the colloidal surface. (c) 2008 Wiley Periodicals, Inc. Biopolymers 89: 941-950, 2008.This article was originally published online as an accepted preprint. The "Published Online" date corresponds to the preprint version. You can request a copy of the preprint by emailing the Biopolymers editorial office at biopolymers@wiley.com.     

A novel bombesin receptor antagonist (2258U89), potently inhibits bombesin evoked release of gastrointestinal hormones from rats and dogs, in vitro and in vivo.

Several bombesin-receptor antagonists are available that inhibit secretory and growth effects of bombesin, in vitro. In the present study, we examined the effects of a new class of bombesin receptor antagonists (modified GRP(15-27) peptides, with D-Pro26 and D-Ala24 moieties), on bombesin mediated effects, in vivo and in vitro. Of the 10 different compounds tested, BW-10 or 2258U89 ([de-NH2)Phe19,D-Ala24,D-Pro26 psi(CH2NH)Phe27]-GRP(19-27)) was most potent towards inhibiting bombesin binding to rat pancreatic acinar cancer cells with an ID50 of 0.5 nM. BW-10 (1 and 10 nM) significantly inhibited the gastrin response to 1 nM bombesin, from isolated rat stomach, in vitro, in a dose-dependent fashion. BW-10 (10-100 nmol/kg) was equally effective at significantly inhibiting bombesin evoked gastrin release in anesthetized rats, in vivo. [D-Phe6]Bombesin(6-13)-propylamide (BIM), a member of another class of antagonists, reported previously to be the most potent antagonist, in vitro, on the other hand, enhanced bombesin provoked gastrin release in rats. The antagonistic effects of BIM, in vivo, may thus be more selective. Intravenous infusion of BW-10 (10 nmol/kg/h) partially depressed gastrin and pancreatic polypeptide and completely abolished insulin released in response to bombesin, in conscious dogs. These results suggest that BW-10 functions as one of the most potent bombesin receptor antagonists, in vitro and in vivo, which could potentially be used as a therapeutic compound in treatment of some human diseases.     

Proadrenomedullin N-terminal 20 peptide (PAMP) inhibits food intake and gastric emptying in mice

We found that proadrenomedullin N-terminal 20 peptide (PAMP) decreased dose-dependently (3-30 nmol/mouse) food intake after intra-third cerebroventricular administration in fasted ddY mice. Gastric emptying also was delayed after central injection of PAMP. In our previous study, PAMP was demonstrated to elicit hyperglycemia via bombesin (BN) receptor. Then, we examined whether the effects of PAMP on feeding and gastric emptying were induced through BN receptor. Surprisingly, PAMP-induced reductions in feeding and gastric emptying rate were not blocked by a BN antagonist, [D-Phe(6), Leu-NHEt(13), des-Met(14)]-BN (6-14). PAMP suppressed feeding in mice lacking gastrin-releasing peptide receptor or BN receptor subtype-3. These results indicate that centrally administered PAMP inhibits food intake, involving the delayed gastric emptying, not through BN receptors but through selective PAMP receptor.     

Parellel inhibition of LH-RH-induced cyclic AMP accumulation and LH and FSH release by LH-RH antagonists in vitro.

The relative potencies of seven antagonists of LH-RH to inhibit LH-RH-induced cyclic AMP accumulation and LH and FSH release were measured using rat hemipituitaries in vitro. At appropriate concentrations, [Des-His2, D-Ala6] LH-RH, [Des-His2, D-Ala6, des-Gly-NH210] LH-RH ethylamide, [Des-His2, D-Leu6] LH-RH, [D-Phe2] LH-RH, [Des-His2, Des-Gly-NH210] LH-RH propylamide, [D-Phe2, D-Leu6] LH-RH and [D-Phe2, D-Phe6] LH-RH led to parallel inhibition of cyclic AMP accumulation and LH and FSH release. [D-Phe2, D-Leu6] LH-RH and [D-Phe2, D-Phe6] LH-RH can inhibit 50% of LH-RH action at molar ratios of 100 and 30, respectively. These findings of parallel changes of cyclic AMP levels and LH and FSH release add strong support to the already obtained evidence for a mediator role of the adenylate cyclase system in the action of LH-RH in the anterior pituitary gland.     

Biological effects and receptor binding affinities of new pseudononapeptide bombesin/GRP receptor antagonists with N-terminal D-Trp or D-Tpi.

In an attempt to produce more powerful (effective) bombesin/GRP receptor antagonists, the D forms of Trp or Trp analog (Tpi) were introduced at position 6 in two pseudononapeptides, Leu13 psi (CH2NH)Leu14-bombesin(6-14) and Leu13 psi(CH2NH)Phe14-bombesin (6-14). These antagonists were tested for their ability to inhibit basal and gastrin releasing peptide (GRP) (14-27)-induced amylase release from rat pancreatic acini in a superfusion assay. They were also assessed for the inhibition of 125I-Tyr4-bombesin binding to Swiss 3T3 and small cell lung carcinoma cell line H-345 and the mitogenic response of Swiss 3T3 cells induced by GRP(14-27). The peptides, when given alone, did not stimulate amylase secretion, but were able to inhibit gastrin releasing peptide (14-27)-induced amylase release. All of the antagonists showed strong binding affinities for Swiss 3T3 and H-345 cells and suppressed the GRP(14-27)-induced increase of [3H]thymidine incorporation into DNA of Swiss 3T3 cells at nanomolar concentrations. Antagonist D-Tpi6,Leu13 psi (CH2NH)Leu14-bombesin (6-14)(RC-3095) was slightly more potent in these assays than D-Trp6,Leu13 psi (CH2NH)Leu14-bombesin (6-14)(RC-3125). Nevertheless, D-Trp6,Leu13 psi (CH2NH)Phe14-bombesin (6-14) showed the highest binding affinity for Swiss 3T3 and H345 cells and it was the most potent inhibitor of GRP(14-27)-induced amylase secretion. This antagonist RC-3420 was particularly effective in inhibiting the growth of Swiss 3T3 cells, exhibiting an IC50 value less than 1 nM.(ABSTRACT TRUNCATED AT 250 WORDS)     

Covalently cyclized agonist and antagonist analogues of bombesin and related peptides.

During a search for possible cyclization points in shortened, potent bombesin agonists and antagonists, it was found that the joining of amino acid residues in positions 6 and 14 by various means resulted in retention of significant binding affinity for rat pancreatic acini and murine Swiss 3T3 cells. In one series of analogues, Cys residues in these positions were used for bridging via a disulfide bond. (D)-C-Q-W-A-V-G-H-L-C-NH2 retained significant binding affinity for rat pancreatic acini cells and was a full amylase releasing agonist (EC50 187 nM). Potency was markedly increased by substituting D-Ala for Gly (EC50 67 nM compared to 10 nM for its linear counterpart) and was decreased by substituting L-Cys for D-Cys in this analogue (EC50 214 nM), thus strongly suggesting stabilization of peptide folding by the D residues. Elimination of the COOH-terminal amino acid produces competitive antagonists in the linear analogues; however, (D)-C-Q-W-A-V-G-H-C-NH2 was devoid of activity. Likewise, cyclization to position 13 with the 14 amino acids intact to give (D)-C-Q-W-A-V-G-H-C-L-NH2 resulted in an almost inactive peptide. On the other hand, as in the linear series, the reduced peptide bond analogue, (D)-C-Q-W-A-V-(D)-A-H-L-psi (CH2NH)-C-NH2, was a receptor antagonist (IC50 5.7 mM), albeit much weaker than the corresponding linear analogues, but with no residual agonist activity. Direct head-to-tail cyclization was also tried. Both cyclo[(D)-F-Q-W-A-V-G-H-L-L] (EC50 346 nM) and the shorter cyclo [Q-W-A-V-G-H-L-L] (EC50 1236 nM) were full agonists. Elimination of the COOH-terminal residue in cyclo[(D)-p-Cl-F-Q-W-A-V-(D)-A-H-L] produced an agonist (EC50 716 nM) rather than an antagonist. These results provide support for the proposal that both bombesin agonists and antagonists adopt a folded conformation at their receptor(s). Furthermore, the retention of appreciable potencies using several cyclization strategies and chain lengths suggests that further optimization of these structures both in terms of potency and ring size is possible. Since these peptides have increased conformational restriction, they should begin to serve as useful substrates for NMR and molecular modeling studies aimed at comparing the obviously subtle differences between agonist and antagonist structures.     

C-terminal peptides of calcitonin gene-related peptide act as agonists at the cholecystokinin receptor

We have previously described that [Tyr⁰]CGRP(28–37) acts as a receptor antagonist of rat CGRP in guinea pig pancreatic acini. We therefore examined other C-terminal peptides of CGRP for such activity. CGRP-acetyl(28–37) acetate did act as a rat CGRP antagonist. However, C-terminal CGRP peptides of 4 to 8 amino acid residues did not antagonize the actions of rat CGRP but stimulated amylase secretion. In pancreatic acini, a maximally effective concentration of rat CGRP (100 nM) caused a 2.1-fold increase in amylase secretion. When the C-terminal peptides of CGRP were tested in at 100 μM, CGRP(34–37) caused a 1.8-fold increase in amylase secretion, CGRP(33–37) a 2.8-fold increase, CGRP(32–37) a 9.2-fold increase, CGRP(31–37) a 4.1-fold increase, and CGRP(30–37) a 5.1-fold increase. Further studies with the most effective peptide, CGRP(32–37), demonstrated that it did not cause release of lactate dehydrogenase, and thus did not cause amylase release by cell damage. Unlike rat CGRP, CGRP(32–37) did not increase cellular cyclic AMP, but did stimulate outflux of ⁴⁵Ca. CGRP(32–37)-stimulated amylase release was not inhibited by the substance P receptor antagonist, spantide, by the bombesin receptor antagonist, [D-Phe⁶]bombesin(6–13) propylamide, or by the muscarinic receptor antagonist, atropine, but was inhibited by the CCK receptor antagonist L364,718. C-terminal peptides of CGRP inhibited binding of ¹²⁵I-BH-CCK-8, with the relative potencies of the peptides being the same as their relative potencies for stimulating amylase secretion. The present data demonstrate that C-terminal peptides of CGRP, although they have only 2 amino acid residues in common with CCK(26–33), act exclusively at CCK receptors on pancreatic acini to stimulate amylase secretion.     

Investigation of molecular structure of bombesin and its modified analogues nonadsorbed and adsorbed on electrochemically roughened silver surface

This work describes the molecular structure of bombesin (BN) and its analogs on the basis of the absorption infrared and Raman results described below. In these analogues is replaced one ([D-Phe12]BN, [Tyr4]BN, and [Lys3]BN) or two ([Tyr4,D-Phe12]BN, [D-Phe12,Leu14]BN, and [Leu13-(R)-Leu14]BN) amino acid residues within the peptide chain with a synthetic amino acid, creating antagonists to bombesin, which are useful in the treatment of cancer. It is also used surface enhanced Raman scattering (SERS) to study the differences and changes in the vibrational spectra of BN and its analogs, which were attached to an electrochemically roughened silver surface as these peptides interacted with target proteins. This work explores the use of SERS for molecules anchored to a macroscopic silver surface to interrogate the interaction of these peptides with protein receptors. The results presented here show that all peptides coordinate to the macroscopic silver surface through an indole ring and the methylene group of Trp8, the C==O fragment, and an amide bond; however, the orientation of these fragments on the electrochemically roughened silver surface and the strength of the interactions with this surface is slightly different for each peptide. For example, the interaction of --CH2-- of [D-Phe12]BN, [Tyr4,D-Phe12]BN, [D-Phe12,Leu14]BN, [Leu13-(R)-Leu14]BN, and [Lys3]BN with the silver surface perturbed the vertical orientation of the Trp8 indole ring on this surface. Hence, the indole ring adopted a close to perpendicular orientation on the silver surface for BN and [Tyr4]BN, only.     

Reduced peptide bond pseudopeptide analogues of substance P. A new class of substance P receptor antagonists with enhanced specificity

Each of the last 6 peptide bonds in the COOH terminus of [Leu11]substance P [( Leu11]SP) and [Nle11]spantide were replaced with [CH2NH], and each analogue was tested for SP agonist or antagonist activity by determining its ability to interact with SP receptors on dispersed acini from guinea pig pancreas. Each of the 6 spantide and 5 of the 6 SP analogues had no agonist activity, whereas [psi 9-10]SP was an agonist. For the spantide pseudopeptides, the psi 10-11 analogue (Ki,2.8 microM) was equipotent as an antagonist to spantide itself, whereas the psi 9-10, psi 8-9, psi 7-8, and psi 6-7 analogues were 2.5, 7, 5, and 3 times less potent. For the SP pseudopeptides, the psi 10-11 analogue was the most potent antagonist (Ki, 6.2 microM), whereas the psi 8-9, psi 7-8, and psi 6-7 analogues were 7-, 36-, and 39-fold less potent. There was a close correlation between the ability of each pseudopeptide to inhibit binding of 125I-Bolton-Hunter-SP and to affect amylase secretion. [psi 10-11]SP inhibited SP-stimulated amylase release in a competitive manner, and its inhibitory ability was specific for the SP receptor. Despite [psi 10-11]SP, spantide, and [psi 10-11]spantide having similar affinities for the SP receptor (Ki, 2-6 microM), for inhibition of binding of 125I-[Tyr4]bombesin, the analogues differed with [psi 10-11]SP having a 50-fold lower affinity than for the SP receptor, whereas [psi 10-11]spantide had a 4-fold lower affinity and spantide a 1.5-fold lower affinity for the SP receptor. These results demonstrate that SP pseudopeptides represent a new class of SP receptor antagonists and, in contrast to the currently described SP receptor antagonists, are more specific for SP receptors.     

Proadrenomedullin N-terminal 20 peptide (PAMP) elevates blood glucose levels via bombesin receptor in mice

We found a potent hyperglycemic effect of proadrenomedullin N-terminal 20 peptide (PAMP) after intra-third cerebroventricular administration at a dose of 10 nmol in fasted mice. PAMP has four homologous residues with bombesin (BN), a hyperglycemic peptide. PAMP showed affinity for gastrin-releasing peptide preferring receptor (GRP-R) and neuromedin B preferring receptor. The PAMP-induced hyperglycemic effect was inhibited by [D-Phe(6), Leu-NHEt(13), des-Met(14)]-BN (6-14), GRP-R specific antagonist, indicating that the hyperglycemic effect is mediated at least in part via GRP-R. Furthermore, pretreatment of alpha-adrenergic blocker inhibited the PAMP-induced hyperglycemia and hyperglucagonemia, suggesting that the increase of glucagon secretion through alpha-adrenergic activation is involved in this hyperglycemic effect of PAMP.     

Plasma extravasation mediated by lipopolysaccharide-induction of kinin B1 receptors in rat tissues.

The present study was performed to: (a) evaluate the effects of kinin B1 (Sar[D-Phe8]-des-Arg9-BK; 10 nmol/kg) and B2 (bradykinin (BK); 10 nmol/kg) receptor agonists on plasma extravasation in selected rat tissues; (b) determine the contribution of a lipopolysaccharide (LPS) (100 microg/kg) to the effects triggered by B1 and B2 agonists; and (c) characterize the selectivity of B1 ([Leu8]desArg9-BK; 10 nmol/kg) and B2 (HOE 140; 10 nmol/kg) antagonists as inhibitors of this kinin-induced phenomenon. B1 and B2 agonists were shown to increase plasma extravasation in the duodenum, ileum and also in the urinary bladder of the rat. LPS pretreatment enhanced the plasma extravasation mediated only by the B1 agonist in the duodenum, ileum, trachea, main and segmentar bronchi. These effects were prevented by the B1. but not the B2 antagonist. In normal rats, the B2 antagonist inhibited the effect of B2 agonist in all the tissues analyzed. However, in LPS-treated rats, the B2 antagonist was ineffective in the urinary bladder. These results indicate that kinins induce plasma extravasation in selected rat tissues through activation of B1 and B2 receptors, and that LPS selectively enhances the kinin effect on the B1 receptor in the duodenum, ileum, trachea and main and segmentar bronchi, and may increase B1 receptor expression in these tissues.     

New antagonists of LHRH. II. Inhibition and potentiation of LHRH by closely related analogues

Modifications of the previously described LHRH antagonists, [Ac-D-Nal(2)1, D-Phe(4Cl)2, D-Trp3, D-Cit6, D-Ala10]LHRH and the corresponding D-Hci6 analogue, have been made to alter the hydrophobicity of the N-terminal acetyl-tripeptide portion. Substitution of D-Trp3 with the less hydrophobic D-Pal(3) had only marginal effects on the antagonistic activities and receptor binding potencies of the D-Cit/D-Hci6 analogues, but it appeared to further improve the toxicity lowering effect of D-Cit/D-Hci6 substitution. Antagonists containing D-Pal(3)3 and D-Cit/D-Hci6 residues, i.e. [Ac-D-Nal(2)1, D-Phe(4Cl)2, D-Pal(3)3, D-Cit6, D-Ala10]LHRH (SB-75) and [Ac-D-Nal(2)1, D-Phe(4Cl)2, D-Pal(3)3, D-Hci6, D-Ala10]LHRH (SB-88), were completely free of the toxic effects, such as cyanosis and respiratory depression leading to death, which have been observed in rats with the D-Trp3, D-Arg6 antagonist and related antagonists. Replacement of the N-acetyl group with the hydrophilic carbamoyl group caused a slight decrease in antagonistic activities, particularly in vitro. Introduction of urethane type acyl group such as methoxycarbonyl (Moc) or t-butoxycarbonyl (Boc) led to analogues that showed LHRH-potentiating effect. The increase in potency induced by these analogues, e.g. [Moc-D-Nal(2)1, D-Phe(4Cl)2, D-Trp3, D-Cit6, D-Ala10]LHRH and [Boc-D-Phe1, D-Phe(4Cl)2, D-Pal(3)3, D-Cit6, D-Ala10]LHRH, was 170-260% and persisted for more than 2 h when studied in a superfused rat pituitary system.