CCK2R antagonists: from SAR to clinical trials.

The widespread involvement of the cholecystokinin-2/gastrin receptor (CCK2R) in multiple (patho)physiological processes has propelled extensive searches for nonpeptide small-molecule CCK2R antagonists. For the past three decades, considerable research has yielded numerous chemically heterogeneous compounds. None of these entered into the clinic, mainly because of inadequate biological effects. However, it appears that the ultimate goal of a clinically useful CCK2R antagonist is now just around the corner, with the most promising compounds, netazepide and nastorazepide, now in Phase II clinical trials. Here, we illustrate the structure-activity relationships (SARs) of stablished CCK2R antagonists of various structural classes, and the most recent proof-of-concept studies where new applicabilities of CCK2R antagonists as visualizing agents are presented.

A two-step strategy to enhance activity of low potency peptides.

Novel strategies are needed to expedite the generation and optimization of peptide probes targeting G protein-coupled receptors (GPCRs). We have previously shown that membrane tethered ligands (MTLs), recombinant proteins comprised of a membrane anchor, an extracellular linker, and a peptide ligand can be used to identify targeted receptor modulators. Although MTLs provide a useful tool to identify and/or modify functionally active peptides, a major limitation of this strategy is the reliance on recombinant protein expression. We now report the generation and pharmacological characterization of prototype peptide-linker-lipid conjugates, synthetic membrane anchored ligands (SMALs), which are designed as mimics of corresponding MTLs. In this study, we systematically compare the activity of selected peptides as MTLs versus SMALs. As prototypes, we focused on the precursor proteins of mature Substance P (SubP) and Cholecystokinin 4 (CCK4), specifically non-amidated SubP (SubP-COOH) and glycine extended CCK4 (CCK4-Gly-COOH). As low affinity soluble peptides these ligands each presented a challenging test case for assessment of MTL/SMAL technology. For each ligand, MTLs and corresponding SMALs showed agonist activity and comparable subtype selectivity. In addition, our results illustrate that membrane anchoring increases ligand potency. Furthermore, both MTL and SMAL induced signaling can be blocked by specific non-peptide antagonists suggesting that the anchored constructs may be orthosteric agonists. In conclusion, MTLs offer a streamlined approach for identifying low activity peptides which can be readily converted to higher potency SMALs. The ability to recapitulate MTL activity with SMALs extends the utility of anchored peptides as probes of GPCR function.

[The study of biologically active conformation of cholecystokinin-4 dipeptide analog GB-115].

The conformational analysis with 1H NMR spectroscopy method in solution and the structure-activity relationship study of a series sterically restricted analogs allowed to detect the possible biologically active conformation of N-(6-phenylhexanoyl)glycyl-tryptophan amide (GB-115), a highly active dipeptide cholecystokinin-4 analog with anxiolytic activity. The structure-activity relationship study of GB-115 and the series of its' glycine- and proline-containing analogs with different C-terminal substitute detected the anxiolytic activity of compounds with beta-turn like conformation and inactivity of compounds with gamma-turn like conformation. So, the GB-115 biologically active conformation is beta-turn. The results of nuclear Overhauser effect study permitted to qualify the betaII-turn conformation as GB-115 biologically active conformation. The following synthesis of sterically restricted GB-115 analogs (2S)-2-{(3R)-3-[(6-phenylhexanoyl)amino]-2-oxopyrrolidin-1-yl}-3-(1H-indol-3-yl)propionic acid ethyl ester, N-(6-phenylhexanoyl)glycyl-N(alpha)(methyl)-tryptophan ethyl ester, (2S)-2-[10,11-dihydro-5H-dibenzo[b,f] azepin-5-carbonyl)-amino]-3-(1H-indol-3-yl)propionic acid methyl ester and (2S)-2-[({3-[(ethoxycarbonyl)amino]-10,11-dihydro-5H-dibenzo[b,f]azepin-5-yl}carbonyl)amino]-3-(1H-indol-3-yl)propionic acid methyl ester confirmed the estimated type of GB-115 biologically active conformation.

A sucrose-derived scaffold for multimerization of bioactive peptides.

A spherical molecular scaffold bearing eight terminal alkyne groups was synthesized in one step from sucrose. One or more copies of a tetrapeptide azide, either N(3)(CH(2))(5)(CO)-His-DPhe-Arg-Trp-NH(2) (MSH4) or N(3)(CH(2))(5)(CO)-Trp-Met-Asp-Phe-NH(2) (CCK4), were attached to the scaffold via the copper(I)-catalyzed azide-alkyne cycloaddition (CuAAC) reaction. Competitive binding assays using Eu-labeled probes based on the superpotent ligands Ser-Tyr-Ser-Nle-Glu-His-DPhe-Arg-Trp-Gly-Lys-Pro-Val-NH(2) (NDP-α-MSH) and Asp-Tyr-Met-Gly-Trp-Met-Asp-Phe-NH(2) (CCK8) were used to study the interactions of monovalent and multivalent MSH4 and CCK4 constructs with Hek293 cells engineered to overexpress MC4R and CCK2R. All of the monovalent and multivalent MSH4 constructs exhibited binding comparable to that of the parental ligand, suggesting that either the ligand spacing was inappropriate for multivalent binding, or MSH4 is too weak a binder for a second 'anchoring' binding event to occur before the monovalently-bound construct is released from the cell surface. In contrast with this behavior, monovalent CCK4 constructs were significantly less potent than the parental ligand, while multivalent CCK4 constructs were as or more potent than the parental ligand. These results are suggestive of multivalent binding, which may be due to increased residence times for monovalently bound CCK4 constructs on the cell surface relative to MSH4 constructs, the greater residence time being necessary for the establishment of multivalent binding.

Solid-state stability studies of cholecystokinin (CCK-4) peptide under nonisothermal conditions using thermal analysis, chromatography and mass spectrometry.

The solid-state stability of cholecystokinin (CCK-4) peptide under nonisothermal conditions was studied by differential scanning calorimetry (DSC), chromatography and mass spectrometry, identifying and schematizing the degradation products. To model the degradation mechanism of the peptide using the combined Kissinger and direct-differential methods, the observed degradation process was characterized by decomposition temperature (T(m)), reacted fraction (alpha(m)), activation energy (E(a)), and pre-exponential factor (A). Results obtained by the two calculation methods were similar. The cleavage reaction on both N- and C-terminal sides of aspartic acid was the principal degradation pathway, although the reaction can occur consecutively and/or in parallel. Therefore to determine the relative importance of the different degradation pathways, a system of differential equations relevant to each degradation reaction was analysed using the R((R)) statistical program. The results obtained show that the consecutive reaction was the less plausible, whereas a slightly better fit was obtained for the reaction with both processes than for the in-parallel reaction. In this situation, the F-test was applied to discriminate between the models, indicating that the simpler model is the most probable. In conclusion, the results demonstrate for the first time that, in solid-state, n-1 cleavage occurs in parallel to n+1 cleavage at aspartic acid residues and not consecutively.

Synthesis, characterization and in vitro evaluation of new oxorhenium- and oxotechnetium-CCK4 derivatives as molecular imaging agents for CCK2-receptor targeting.

The goal of this study is to design new (99m)Tc-radiolabelled shortened CCK derivatives that might be suitable for the molecular imaging of cholecystokinin-2 receptors (CCK2-R), these receptors being over-expressed in a number of neuroendocrine tumors such as medullary thyroid cancer and small-cell lung cancer. For this purpose, we designed several modified CCK4 analogs bearing an ON(2)S tetradentate chelating agent at the N-terminus, the CCK4 sequence representing the minimal peptide sequence that presents nanomolar affinity and activity towards the CCK2-R. Four peptide conjugates of general formula (Trt)SN(2)OPh-(X)(n)-CCK4 (X=beta-alanine or 6-aminohexanoic acid spacers; n=0, 2, 4) and their oxorhenium peptide conjugates have been synthesized and characterized. In vitro evaluation of these compounds showed a close relationship between the nature and the length of the spacer and the corresponding binding affinity values. The most promising oxorhenium complex 5-Re exhibited potent CCK2-receptor agonist properties in promoting the production of inositol phosphate in COS-7 cells (EC(50)=5.17nM). Preliminary (99m)Tc-radiolabelling studies with peptide conjugates 3 or 5 led exclusively to the corresponding (99m)TcO-complexes 3-Tc and 5-Tc, which exhibited high resistance towards an excess of cysteine and satisfactory stabilities in human serum. To conclude, the promising in vitro characteristics of compounds 5-Re, 5-Tc illustrate the feasibility to develop stable radiolabelled shortened CCK4 derivatives with a nanomolar CCK2-R affinity.

Hydrolysis of various bioactive peptides by goat brain dipeptidylpeptidase-III homologue.

DPP-III from goat brain was purified to apparent electrophoretic homogeneity which showed several characteristics similar to other reported DPP-IIIs although it possesses dissimilar molecular weight and different inhibition behavior. Thin layer chromatographic studies with goat brain DPP-III revealed that it hydrolyses Leu-enkephalin (Tyr-Gly-Gly-Phe-Leu) at the Gly-Gly bond producing Tyr-Gly and Gly-Phe-Leu with no further degradation of liberated tripeptide. (Ala)(4) is hydrolyzed to dialanine whereas trialanine is not cleaved. ACTH, angiotensin II and III were also hydrolyzed whereas angiotensin I was not. It was concluded that the enzyme requires at least a tetrapeptide to act and that it removes a dipeptidyl moiety from the NH(2)-terminus of the studied peptides. Goat brain DPP-III may be involved in the metabolism of very important bioactive peptides such as enkephalins and angiotensins.

[Design and synthesis of cholecystokinin-4 dipeptide analogues with anxiolytic and anxiogenic activities].

A new series of dipeptide analogues of the general formula Ph(CH2)nCO-NH(CH2)mCO-Trp-NH2 (n = 1, 3-5; m = 1-3) was designed based on the structure of the endogenous tetrapeptide cholecystokinin-4 (CCK-4) and the topochemical Shemyakin-Ovchinnikov-Ivanov principle. The L-tryptophan derivatives exhibited anxiolytic properties and the D-tryptophan derivatives, anxiogenic properties. The dipeptide Ph(CH2)5CO-Gly-L-Trp-NH2 (GB-115) with the activity in rats of 0.05-0.2 mg/kg after oral and intraperitoneal administration was chosen for further studies as a promising anxiolytic agent.

Data analysis of kinetic modelling used in drug stability studies: isothermal versus nonisothermal assays.

PURPOSE: Kinetic modelling was applied to predict the stability of cholecystokinin fragment CCK-4 in aqueous solution, which was analyzed by isothermal and nonisothermal methods using a validated stability indicating HPLC method. METHODS: The isothermal studies were performed in the temperature range 40 to 80 degrees C at pH 12 and ionic strength 0.01 M as constants, whereas nonisothermal stability studies were performed using a linear increasing temperature program, heating rate 0.25 degrees C/h and a temperature interval 40-82 degrees C. The isothermal studies require two-step linear regression to estimate the parameters, resulting in a well-defined confidence interval. Nonisothermal kinetic studies require nonlinear or linear regression by previous transformation of data to estimate the parameters. In this case, the two most popular approaches, derivative and integral, were used and compared. RESULTS: Under isothermal conditions, an apparent first-order degradation process was observed at all temperatures. The linear Arrhenius plot suggested that the CCK-4 degradation mechanism was the same within the studied temperature range, with quite large uncertainties due to the small number of degrees of freedom based only on the scatter in the plot, and giving an estimated shelf life at 25 degrees C of 35.2 days. The derivative approach yields high variability in the Arrhenius parameters, since they are dependent on the number of polynomial terms chosen, so several statistical criteria were applied to select the best model. The integral approach allows activation parameters to be calculated directly from experimental data, and provides results in good agreement with those of the traditional method, but have the advantage that the uncertainty in the final result directly reflects the goodness of fit of the experimental data to the chosen kinetic model. The application of the bootstrap technique to estimating confidence limits for the Arrhenius parameters and shelf life is also illustrated, and shows there is no difference between the asymptotic and bootstrap confidence intervals. CONCLUSIONS: Nonisothermal studies give us fast and valuable information about drug stability, although their potential for predicting isothermal behaviour is conditioned by the data analysis method applied.

Conformationally constrained CCK4 analogues incorporating IBTM and BTD beta-turn mimetics.

To test whether a turnlike arrangement is involved in the bioactive conformation of CCK4 analogues upon CCK1 receptor recognition, we describe the preparation of two series of CCK4 derivatives, in which the central dipeptide Met-Asp has been replaced by recognized beta-turn mimetics {(2S,5S,11bR)- and (2R,5R,11bS)-2-amino-5-carboxy-3-oxo-2,3,5,6,11,11b-hexahydro-1H-indolizino[8,7-b]indole (IBTM) and beta-turn dipeptide, 2-oxo-7-thio-1-azabicyclo[4.3.0]nonane (BTD)}. The incorporation of the indolizinoindole IBTM type II beta-turn mimetic is preferred over its type II' counterpart for efficient CCK1 receptor recognition, while BTD derivatives were completely inactive. The structure-conformation-activity relationship study in the IBTM series has shown some essential requirement of these CCK4 derivatives to favorably interact with CCK1 receptors: (a) the adoption of turnlike conformations, (b) the presence of an L-Phe residue and a C-terminal carboxamide moiety, and (c) the indole ring of the IBTM skeleton. Moreover, the existence of pi-pi interactions between the phenyl ring of d-Phe residues and the indole ring of IBTM framework is detrimental for binding affinity. A series of potent and selective CCK1 receptor antagonists, exemplified by compounds 8a and 8b, emerges among these IBTM-containing derivatives.

Differential spatial approximation between cholecystokinin residue 30 and receptor residues in active and inactive conformations.

Understanding the structures of active and inactive agonist- and antagonist-bound receptor complexes is of great interest. In this work, we focus on position 30 of cholecystokinin (CCK) and its spatial approximation with the type A CCK receptor. For this, we developed two photoaffinity labeling probes, replacing the naturally occurring tryptophan with p-benzoyl-l-phenylalanine (Bpa) or p-nitro-phenylalanine (NO(2)-Phe). The Bpa probe was shown to represent an antagonist, whereas the NO(2)-Phe probe stimulated intracellular calcium as a fully efficacious agonist (EC(50) = 81 +/- 15 nM). Both ligands bound to the receptor specifically, although with lower affinity than CCK (K(i) values: Bpa probe, 270 +/- 72 nM; NO(2)-Phe probe, 180 +/- 40 nM). Both probes covalently labeled the receptor in an efficient manner. The Bpa antagonist labeled the receptor in two distinct regions as identified by cyanogen bromide cleavage, with labeled bands migrating at M(r) = 25,000 and 4500. The former represented the glycosylated amino-terminal fragment, with the site of attachment further localized by endoproteinase Lys-C cleavage to the region between Asn(10) and Lys(37). The latter was shown to represent the first extracellular loop using further cleavage and sequencing of the wild-type and a mutant receptor. Following the same approach, the NO(2)-Phe agonist probe was shown to also label the first extracellular loop region. Radiochemical sequencing identified that the Bpa antagonist probe labeled receptor residue Lys(105), whereas the NO(2)-Phe agonist probe labeled residue Leu(99). These data extend our understanding of the molecular basis of binding and the conformational states of this important receptor.

Enzymatic synthesis of a CCK-4 tripeptide fragment.

OBJECTIVE: To synthesize a tripeptide derivative Phac-Met-Asp(OMe)-Phe -NH2, which is a fragment of the gastrin C-terminal tetrapeptide CCK-4, by enzymatic reaction. METHODS: Three free enzymes, alpha-chymotrypsin, papain and thermolysin from acyl donor Phac-Met-OCam was involved in three steps. The choice of appropriate enzymes and solvents was selected. RESULTS: All enzymatic reactions were obtained in reasonable yields(63%-92%). FAB-MS and FD-MS verified the correct molecular mass of the peptides. CONCLUSION: Studies on the alpha-chymotrypsin catalyzed coupling reaction between Phac-Met-OCam and H-Asp(OMe)2 have focused on the low water content media. By papain catalyzed saponification of Phac-Met-Asp(OMe)2, alpha-methyl ester of aspartic acid is selectively hydrolyzed to retain beta-methyl ester, and Phac-Met-Asp(OMe)-OH and H-Phe-NH2 can be coupled efficiently by thermolysin.

Possible degradative process of cholecystokinin analogs in rabbit jejunum brush-border membrane vesicles.

Our recent work on the intestinal metabolism and absorption of cholecystokinin analogs, sulfated C-terminal octapeptide (CCK8; Asp-Tyr(SO(3)H)-Met-Gly-Trp-Met-Asp-Phe(NH(2)) = DY(SO(3)H)MGWMDF(NH(2))) and tetrapeptide (CCK4; Trp-Met-Asp-Phe(NH(2)) = WMDF(NH(2))), was extended to investigate the degradative process of these analogs using rabbit jejunum brush-border membrane vesicles and to find a better enzyme-inhibitor system for intestinal absorption of peptide drugs. Various enzyme inhibitors and a lower pH buffer were applied to discover the major enzyme(s) involved in each process. Metabolic pathways showing degradative processes were proposed for both analogs. The major cleavage site occurs at the W(1)-M(2) for CCK4. At least three metabolic pathways occur independently for CCK8 and appear at peptides bonds between G(4)-W(5), M(6)-D(7), and D(7)-F(NH(2))(8). Many different enzymes of aminopeptidase, endopeptidase, angiotensin-converting enzyme, metalloenzyme, and others were involved in each process. Identification of more specific yet safe enzyme inhibitors and co-administration of various these inhibitors may lead to further enhancement in intestinal peptide absorption when administered orally.

99mTc-labeling experiments on CCK(4) by a direct method.

99mTc-labeling studies have been performed on CCK(4) fragment of cholecystokinin, starting from 99mTc-pertechnetate, by using tin(II)pyrophosphate or tin(II)gluconate as reducing agents, together with NaBH(4) acting as a stabilizing agent of tin(II). Gluconate has been used as exchange ligand in the carrier added experiments and in the syntheses of 99Tc-CCK(4) and Re-CCK(4) complexes to be able to reproduce at macroscopic level the same chemical reactions occurring at non carrier added conditions. 99mTc-labeling yields higher than 95% have been achieved depending on Sn(II) concentration, CCK(4)/gluconate ratio, reaction time and applied temperature. The species produced with 99mTc, 99Tc, and cold rhenium nuclides have been compared by means of HPLC measurements, which showed similar retention times and thus probably the same species in the three situations.

Biological effects of newly synthesized cholecystokinin analogs.

Cholecystokinin (CCK) is a gut hormone that regulates pancreatic endocrine functions via CCK(A) receptors. CCK(4) (Trp-Met-Asp-Phe-NH(2)) has an insulinotropic effect, but is 1,000-fold less potent than CCK(8) in rodents. The in vitro potencies with respect to binding, the biological effects and the selectivity of newly synthesized CCK(4) analogs constructed by computer modelling experiments were investigated in vitro in rat pancreas and brain, INS-1 cells, and guinea pig ileum. Exchanging various amino acids, e.g. Met by either Pro or Nle, and modifying Phe by adding various substituents in different positions led to compounds which were more effective as insulin secretagogues than CCK(4) itself and even show insulinotropic effects comparable with those of CCK(8) (e. g. compounds M1 and M2 being substituted at Phe). Some compounds which possess electron withdrawing groups on the C-terminal Phe and possess a Pro instead of a Met were especially effective. The CCK(A) receptor antagonist L-364,718, but not by the CCK(B) receptor antagonist L-365,260, inhibited the insulinotropic effects. The synthetic CCK(4) compounds were not selective for the endocrine pancreas: e.g. M1 and M2 had binding activity with respect to rat brain homogenates but no activity with respect to contraction of the guinea pig ileum. The data indicate that some of the newly synthesized CCK tetrapeptides exhibit a high affinity for the CCK receptor of beta-cells and have an insulinotropic effect much higher than CCK(4).

Experiments on a new phosphine-peptide chelator for labelling of peptides with Tc-99m.

A phosphine-containing ligand providing a N-[N-[3-(diphenylphosphino)propionyl]glycyl]-L-S-benzyl-cystein (PNNS) donor atomset for the chelation of 99mTc was studied in labelling experiments with a model peptide (tetragastrin, cholecystokinin-fragment). The peptide was conjugated to the ligand chelator by active ester chemistry either before or after radiolabelling. Both the chelator-conjugate and the preformed chelate approaches resulted in the same radiolabelled isomers of the ligand peptide. Sequence and reaction conditions influence yield and purity.

Mimicry of beta II'-turns of proteins in cyclic pentapeptides with one and without D-amino acids.

The solution structure of eight cyclic pentapeptides has been determined by two-dimensional 1H-NMR spectroscopy combined with spectra simulations and restrained molecular dynamic simulations. Six of the cyclic pentapeptides were derived from the C-terminal cholecystokinin fragment CCK-4 enlarged with Asp1 resulting in the sequence (Asp-Trp-Met-Asp-Phe), one L-amino acid after the other was substituted by its D-analog. In addition, two peptides, including an all-L-amino-acid-containing cyclic pentapeptide, cyclo(Asp-Phe-Lys-Ala-Thr) and cyclo(Asp-Phe-Lys-Ala-D-Thr) were investigated. All D-amino-acid-containing peptides show beta II'-turn conformations with the D-amino acid in the i + 1 position, excepting the D-aspartic-acid-containing peptides. These two peptides are characterized by the lack of beta-turns at pH values less than 4, suggesting that D-aspartic acid in the full-protonized state avoids the formation of beta-turns in these compounds. At pH values greater than 5, a conformational change into the beta II'-turn conformation was also observed for these peptides. Conformations without beta-turns are expected for cyclic all-L pentapeptides, but both cyclo(Asp-Phe-Lys-Ala-Thr) and the D-Thr analog cyclo(Asp-Phe-Lys-Ala-D-Thr) exhibit beta II'-turn conformations around Thr-Asp and D-Thr-Asp. Thus cyclic all-L pentapeptides and those with one D-amino acid are able to form similar structures preferably with a beta II'-turn. The beta-turn formation in cyclic pentapeptides containing a D-aspartic acid is dependent on the ionization state. The relevance of the work to the design of beta'-turn mimetics is discussed.

[Improvement of intestinal absorption of peptide and protein drugs by chemical modification with fatty acids].

It is well known that the oral bioavailability of peptide and protein drugs is generally poor because they are extensively degraded by proteases in the gastrointestinal tract and impermeable through the intestinal mucosa. Therefore, various approaches have been examined to overcome the delivery problems of these peptides and to improve their absorption via the gastrointestinal tract. Of these approaches, a potentially useful approach to solve these delivery problems may be chemical modification of peptides and proteins to produce prodrugs and analogues. Thus, it is plausible that this approach may protect peptides against degradation by peptidases and other enzymes present at the mucosal barrier and renders the peptides and proteins more lipophilic, resulting in increased bioavailability. From these standpoints, we synthesized lipophilic derivatives of peptides and proteins such as thyrotropin-releasing hormone (TRH), tetragastrin (TG), calcitonin and insulin by chemical modification with fatty acids. The pharmacological activities of these derivatives were relatively high as compared with the native peptides. A significant increase in the intestinal absorption of these derivatives of peptides was observed in comparison with native peptides. Overall, the effects of acylation on the intestinal absorption of these peptides were more predominant in the large intestine than those in the small intestine. In addition, these derivatives were more stable than the parent peptides in homogenates of the various intestinal mucosae. We also examined the intestinal transport characteristics of TG and its acyl derivatives using Caco-2 cell monolayers in order to assess the contribution of enzymatic and transport barriers on their intestinal absorption. The degradation clearance of TG on the apical membrane was decreased by chemical modification with fatty acids. In addition, the permeability clearance of TG was improved by the acylation. On the other hand, the intestinal absorption of thyrotropin releasing hormone (TRH), which is transported by a carrier-mediated process, was also enhanced by chemical modification with lauric acid. In summary, this chemical modification approach may be useful to improve the intestinal absorption of peptide and protein drugs.

Effects of C-terminal fragments of cholecystokinin on plasma insulin and glucagon concentrations in sheep.

The effects of three C-terminal fragments of cholecystokinin (CCK) (CCK-8-sulphated form [SF], CCK-8-non-sulphated form [NSF] and CCK-4) on insulin and glucagon secretion were examined in sheep in vivo. Each CCK fragment was injected intravenously at a wide range of doses (1 pmol to 3 x 10(5) pmol kg-1). CCK-8(SF) had the lowest threshold dose (10 pmol kg-1) and a maximal response dose of 10(3) pmol kg-1 for increasing plasma insulin concentration; the respective threshold doses of CCK-8(NSF) and CCK-8 for increasing plasma insulin were 30 and 100 times greater than that of CCK-8(SF). A maximal insulin response was not obtained at the highest doses of CCK-8(NSF) or CCK-4 tested (3 x 10(3) and 3 x 10(5) pmol kg-1, respectively). These results indicate that CCK-A type receptors rather than CCK-B receptors may be involved in CCK-induced insulin secretion in sheep. None of the CCK fragments affected plasma glucagon concentration. The lack of a glucagon response to exogenous CCK-fragments may be one of the characteristics of the endocrine pancreatic responses of ruminant species.

Minor structural differences in Boc-CCK-4 derivatives dictate affinity and selectivity for CCK-A and CCK-B receptors.

We previously reported novel Boc-CCK-4 (Boc-Trp-Met-Asp-Phe-NH2) derivatives possessing the general structure Boc-Trp-Lys[N epsilon-CO-NH-(R-Ph)]-Asp-Phe-NH2 (Shiosaki et al. J. Med. Chem. 1991, 34, 2837-2842). In contrast to Boc-CCK-4, which is 70-fold selective for the CCK-B receptor, the modified lysine-bearing tetrapeptides were highly potent and selective full agonists at the CCK-A receptor. Further investigation of the structure-activity profile following modification of the substituted phenylurea moiety appended off the lysine revealed that moving certain substituents, e.g. nitro or acetyl, from the 2- or 3-position on the phenyl ring to the 4-position, a relatively minor and subtle structural modification within the tetrapeptide, resulted in loss of CCK-A receptor selectivity and development of a trend toward CCK-B selectivity. These tetrapeptides, e.g. Boc-Trp-Lys[N epsilon-CO-NH-(4-NO2-Ph)]-Asp-Phe-NH2 and Boc-Trp-Lys[N epsilon-CO-NH-(4-Ac-Ph)]-Asp-Phe-NH2, were full agonists relative to CCK-8 in stimulating intracellular calcium mobilization in a cell line that expresses the CCK-B receptor.