The third intracellular loop of the rat and mouse cholecystokinin-A receptors is responsible for different patterns of gene activation.

It has previously been reported that the cholecystokinin analog JMV-180 behaves differently on the rat and the mouse cholecystokinin-A receptor (CCK-AR). In mice this analog acts as an agonist on low- and high-affinity sites of the CCK-AR, whereas in rats this compound acts as an agonist on high-affinity sites and as an antagonist on low-affinity sites. In an attempt to understand why the same compound behaves differently on these two CCK-A receptors, we cloned the cDNA encoding the mouse CCK-AR. We then investigated a cellular model able to mimic the effect that was observed in rats and mice. HeLa cells were transiently cotransfected with plasmids leading to expression of the rat or mouse CCK-AR in the presence of pFos-Luc as reporter plasmid; such a plasmid placed the regulatory part of the human c-Fos gene upstream from the firefly luciferase structural gene (Luc). We then observed that the two CCK-A receptors behaved differently, not only in the presence of compound JMV-180 but also in the presence of cholecystokinin or even in absence of ligand; the rat CCK-AR was 2 to 3 times more potent than the mouse CCK-AR in inducing the reporter protein, whatever the ligand studied. This result was confirmed using the same kind of experiment with the reporter plasmid p(TRE)(3)-tk-Luc. Using various mutated receptors, we investigated the role of the putative third intracellular loop. We concluded that both the primary structure of the receptor and the cellular context are in part responsible for the differential behavior of these CCK-A receptors.

Peptide/benzodiazepine hybrids as ligands of CCK(A) and CCK(B) receptors.

The (neuro)hormones gastrin and cholecystokinin (CCK) share a common C-terminal tetrapeptide amide sequence that has been recognized as the message portion while the N-terminal extensions are responsible for the CCK(A) and CCK(B) receptor subtype selectivity and avidity. 1,4-Benzodiazepine derivatives are potent and selective antagonists of these receptors, and according to comparative molecular field analysis, the structures of these nonpeptidic compounds could well mimic the message sequence of the peptide agonists at least in terms of spatial array of the aromatic residues. Docking of a larger series of low molecular weight nonpeptide antagonists to a homology modeling derived CCK(B) receptor structure revealed a consensus binding mode that is further validated by data from site-directed mutagenesis studies of the receptors. Whether this putative binding pocket of the nonpeptide antagonists is identical to that of the message portion of the peptide agonists, or whether it is distinct and spatially separated, or overlapping, but with distinct interaction sites, is still object of debate. Using a 1,4-benzodiazepine core amino-functionalized at the C3 position, related tryptophanyl derivatives were synthesized as mimics of the tetrapeptide and subsequently extended N-terminally with gastrin and CCK address sequences. All hybrid constructs were recognized as antagonists by the CCK(A) and CCK(B) receptors, but their address portions were incapable of enhancing in significant manner selectivity and avidity. Consequently, the binding of the peptide/benzodiazepine hybrids has to be dictated mainly by the benzodiazepine moiety, which apparently prevents optimal interactions of the address peptides with extracellular receptor subdomains. These findings would strongly support the view of distinct binding sites for the message portion of the peptide agonists and the benzodiazepine-based nonpeptide antagonists.

Arginine 197 of the cholecystokinin-A receptor binding site interacts with the sulfate of the peptide agonist cholecystokinin.

The knowledge of the binding sites of G protein-coupled cholecystokinin receptors represents important insights that may serve to understand their activation processes and to design or optimize ligands. Our aim was to identify the amino acid of the cholecystokinin-A receptor (CCK-AR) binding site in an interaction with the sulfate of CCK, which is crucial for CCK binding and activity. A three-dimensional model of the [CCK-AR-CCK] complex was built. In this model, Arg197 was the best candidate residue for a ionic interaction with the sulfate of CCK. Arg197 was exchanged for a methionine by site-directed mutagenesis. Wild-type and mutated CCK-AR were transiently expressed in COS-7 cells for pharmacological and functional analysis. The mutated receptor on Arg197 did not bind the agonist radioligand 125I-BH-[Thr, Nle]-CCK-9; however, it bound the nonpeptide antagonist [3H]-SR27,897 as the wild-type receptor. The mutant was approximately 1,470- and 3,200-fold less potent than the wild-type CCK-AR to activate G proteins and to induce inositol phosphate production, respectively. This is consistent with the 500-fold lower potency and 800-fold lower affinity of nonsulfated CCK relative to sulfated CCK on the wild-type receptor. These data, together with those showing that the mutated receptor failed to discriminate nonsulfated and sulfated CCK while it retained other pharmacological features of the CCK-AR, strongly support an interaction between Arg197 of the CCK-AR binding site and the sulfate of CCK. In addition, the mutated CCK-AR resembled the low affinity state of the wild-type CCK-AR, suggesting that Arg197-sulfate interaction regulates conformational changes of the CCK-AR that are required for its physiological activation.

Evidence for a functional role of the cholecystokinin-B/gastrin receptor in the human fetal and adult pancreas.

Gastrin (G) and cholecystokinin (CCK) are gastrointestinal neuropeptides that are released into circulation during a meal. G is also transiently expressed during embryogenic and early ontogenic development of the pancreas and is believed to act on islet-cell development. Both peptides act on pancreatic endocrine function; however, the effects are dependent on the species and on cellular and molecular underlying mechanisms that remain poorly characterized. Since CCK-B/G subtype receptor is predominant over the CCK-A subtype in the human pancreas, we hypothesized that it could be expressed by islet cells. Here we present reverse transcription-polymerase chain reaction and immunohistochemistry data demonstrating that the CCK-B/G receptor is expressed in islet cells and that islet glucagon-producing cells are the major site of CCK-B/G receptor expression in adult and fetal pancreas. Moreover, G immunoreactivity was detected in the fetal human pancreas at embryogenic week 22. G- and CCK-stimulated glucagon are released from purified human islets. Concentration of CCK and G eliciting a half-maximal level of glucagon secretion were 13 +/- 6 and 8 +/- 5 pmol/l, respectively. Maximal glucagon secretion was achieved in the presence of 30 pmol/l peptides and was similar to that obtained in the presence of 10 mmol/l L-arginine (1.6 pmol x ml(-1) x 90 min(-1)). The nonpeptide antagonist of the CCK-B/G receptor, RPR-101048, fully inhibited CCK- and G-stimulated glucagon secretion at 100 nmol/l concentration. These data are consistent with the view that the CCK-B/G receptor is involved in glucose homeostasis in adult humans and mediates the autocrine effects of G on islet differentiation and growth in the fetal pancreas.

Evidence for a direct interaction between the penultimate aspartic acid of cholecystokinin and histidine 207, located in the second extracellular loop of the cholecystokinin B receptor.

Recently, we reported that the mutation of His(207) to Phe located in the second extracellular loop of the cholecystokinin B receptor strongly affected cholecystokinin (CCK) binding (Silvente-Poirot, S., Escrieut, C., and Wank, S. A. (1998) Mol. Pharmacol. 54, 364-371). To characterize the functional group in CCK that interacts with His(207), we first substituted His(207) to Ala. This mutation decreased the affinity and the potency of CCK to produce total inositol phosphates 302-fold and 456-fold without affecting the expression of the mutant receptor. The screening of L-alanine-modified CCK peptides to bind and activate the wild type and mutant receptors allowed the identification of the interaction of the C-terminal Asp(8) of CCK with His(207). The H207A-CCKBR mutant, unlike the wild type receptor, was insensitive to substitution of Asp(8) of CCK to other amino acid residues. This interaction was further confirmed by mutating His(207) to Asp. The affinity of CCK for the H207D-CCKBR mutant was 100-fold lower than for the H207A-CCKBR mutant, consistent with an electrostatic repulsion between the negative charges of the two interacting aspartic acids. Peptides with neutral amino acids in position eight of CCK reversed this effect and displayed a gain of affinity for the H207D mutant compared with CCK. To date, this is the first report concerning the identification of a direct contact point between the CCKB receptor and CCK.

Arginine 336 and asparagine 333 of the human cholecystokinin-A receptor binding site interact with the penultimate aspartic acid and the C-terminal amide of cholecystokinin.

The cholecystokinin-A receptor (CCK-AR) is a G protein-coupled receptor that mediates important central and peripheral cholecystokinin actions. Residues of the CCK-AR binding site that interact with the C-terminal part of CCK that is endowed with biological activity are still unknown. Here we report on the identification of Arg-336 and Asn-333 of CCK-AR, which interact with the Asp-8 carboxylate and the C-terminal amide of CCK-9, respectively. Identification of the two amino acids was achieved by dynamics-based docking of CCK in a refined three-dimensional model of CCK-AR using, as constraints, previous results that demonstrated that Trp-39/Gln-40 and Met-195/Arg-197 interact with the N terminus and the sulfated tyrosine of CCK, respectively. Arg-336-Asp-8 and Asn-333-amide interactions were pharmacologically assessed by mutational exchange of Arg-336 and Asn-333 in the receptor or reciprocal elimination of the partner chemical functions in CCK. This study also allowed us to demonstrate that (i) the identified interactions are crucial for stabilizing the high affinity phospholipase C-coupled state of the CCK-AR.CCK complex, (ii) Arg-336 and Asn-333 are directly involved in interactions with nonpeptide antagonists SR-27,897 and L-364,718, and (iii) Arg-336 but not Asn-333 is directly involved in the binding of the peptide antagonist JMV 179 and the peptide partial agonist JMV 180. These data will be used to obtain an integrated dynamic view of the molecular processes that link agonist binding to receptor activation.

Benzotriazonine as a new core structure for the design of CCK-receptor antagonists.

The search for heterocyclic scaffolds for the design of non-peptidic and highly selective agonists or antagonists of peptide hormone receptors led to 4-N-benzyl-2,3,4,5,6,7-hexahydro-1H-1,4,7-benzotriazonin-2, 6-dione with a 9-membered core structure as a new low mass lead compound that exhibits submicromolar antagonistic activity at the CCK-A receptor with a 54-fold selectivity over the CCK-B/gastrin receptor.

Transgenic CCK-B/gastrin receptor mediates murine exocrine pancreatic secretion.

BACKGROUND & AIMS: The presence of cholecystokinin (CCK)-B/gastrin receptors in the pancreas of higher mammals including humans has been shown, but their physiological function in the normal pancreas is unknown. The aim of this study was to investigate whether they couple to the secretory machinery of normal acinar cells. METHODS: A transgenic mouse strain expressing the human CCK-B/gastrin receptor in the exocrine pancreas was created. The transgenic construction used the promoter region of the elastase I gene and the human CCK-B/gastrin receptor gene. Analysis of ElasCCKB mice included polymerase chain reaction and receptor autoradiography. Molecular and binding features of the CCK-B/gastrin receptor were determined by Western blot and radioligand binding studies. Amylase secretion and inositol phosphate production assays were used in functional characterization. RESULTS: The CCK-B/gastrin receptor was expressed in the exocrine pancreas and had typical molecular and binding features. CCK and sulfated gastrin stimulated enzyme secretion with identical potencies and efficacies. They activated phospholipase C, but CCK was 60-fold less potent than sulfated gastrin. CONCLUSIONS: The data show that the CCK-B/gastrin receptor mediates exocytosis in acinar cells and can differentially couple to phospholipase C depending on the agonist. The ElasCCKB mice provide a useful model to study phospholipase C-dependent and -independent intracellular transduction pathways leading to pancreatic exocrine secretion.

Role of the extracellular domains of the cholecystokinin receptor in agonist binding.

The cholecystokinin (CCK) receptor types A and B (CCKAR and CCKBR) are G protein-coupled receptors with approximately 50% amino acid identity; both have high affinity for the sulfated CCK octapeptide (CCK-8), whereas only the CCKBR has high affinity for gastrin. Previously, we identified five amino acids in the second extracellular loop (ECL) of the CCKBR that were essential for gastrin selectivity. Subsequent mutagenesis of one of these five amino acids (H207F) resulted in the loss of radiolabeled CCK-8 binding. CCK-8 stimulated total inositol phosphate accumulation in COS-1 cells transiently expressing the CCKBR-H207F with full efficacy and a 3044-fold reduced potency, which suggests that the loss of radioligand binding was caused by a loss in affinity. Alanine scanning mutagenesis was performed on the amino terminus near the top of transmembrane domain I (TMI) and on ECL1, two extracellular domains implicated in ligand binding by previous mutagenesis studies. 125I-Bolton-Hunter-CCK-8 binding to mutant receptors transiently expressed in COS-1 identified one nonconserved amino acid, R57A, at the top of TMI that caused a 21-fold reduction in CCK-8 affinity and four conserved amino acids, N115A, L116A, F120A and F122A, in the ECL1 that caused a 15.6-, 6-, 440-, and 8-fold reduction in affinity or efficacy. Alanine substitution of the equivalent amino acids in the CCKAR corresponding to each of the five amino acids in ECL1 and ECL2 affecting CCK-8 affinity for the CCKBR revealed only two mutations, L103A and F107A, that decreased CCK-8 affinity (68- and 2885-fold, respectively). These data suggest that CCK-8 interacts at multiple contact points in the extracellular domains of CCK receptors and that the CCKAR and CCKBR have distinct binding sites despite their shared high affinity for CCK-8.

Met-195 of the cholecystokinin-A receptor interacts with the sulfated tyrosine of cholecystokinin and is crucial for receptor transition to high affinity state.

Sulfation of the tyrosine at the seventh position from the C terminus of cholecystokinin (CCK) is crucial for CCK binding to the CCK-A receptor. Using three-dimensional modeling, we identified methionine 195 of the CCK-A receptor as a putative amino acid in interaction with the aromatic ring of the sulfated tyrosine of CCK. We analyzed the role played by the two partners of this interaction. The exchange of Met-195 for a leucine caused a minor decrease (2. 8-fold) on the affinity of the high affinity sites for sulfated CCK-9, a strong drop (73%) of their number, and a 30-fold decrease on the affinity of the low and very low affinity sites for sulfated CCK-9, with no change in their number. The mutation also caused a 54-fold decrease of the potency of the receptor to induce inositol phosphates production. The high affinity sites of the wild-type CCK-A receptor were highly selective (800-fold) toward sulfated versus nonsulfated CCK, whereas low and very low affinity sites were poorly selective (10- and 18-fold). In addition, the M195L mutant bound, and responded to, sulfated CCK analogues with decreased affinities and potencies, whereas it bound and responded to nonsulfated CCK identically to the wild-type receptor. Thus, Met-195 interacts with the aromatic ring of the sulfated tyrosine to correctly position the sulfated group of CCK in the binding site of the receptor. This interaction is essential for CCK-dependent transition of the CCK-A receptor to a high affinity state. Our data should represent an important step toward the identification of the residue(s) of the receptor in interaction with the sulfate moiety of CCK and the understanding of the molecular mechanisms that govern CCK-A receptor activation.

Differential expression of the CCK-A and CCK-B/gastrin receptor genes in human cancers of the esophagus, stomach and colon.

The expression of cholecystokinin (CCK) and gastrin (G) receptors in human gastrointestinal cancers remains poorly documented and is still of a controversial nature. We have measured the levels of mRNA for CCK-A and CCK-B/gastrin receptors using quantitative reverse transcription-polymerase chain reaction (RT-PCR) in primary digestive cancers and hepatic metastases. CCK-A-receptor mRNA was detected in 5 out of 8 esophageal cancers (0.1-1 fg/microg), in 5 out of 8 gastric cancers (0.05-4.2 fg/microg) and in 5 out of 12 colon cancers (0.1-1 fg/microg RNA). CCK-B/gastrin mRNA was not detected in esophageal cancers but was detected in 7 out of 8 gastric cancers (0.05-5.2 fg/microg), and in only 2 out of 12 colon adenocarcinomas (0.05-1 fg/microg RNA). The expression of the CCK-A receptor in esophageal, gastric and colon cancers and of the CCK-B/gastrin receptor in the majority of gastric adenocarcinomas screened may be an important indicator of the influence of CCK and gastrin of local or systemic origin on the growth of these cancers.

Mapping of ligand binding sites of the cholecystokinin-B/gastrin receptor with lipo-gastrin peptides and molecular modeling.

Double-tailed lipo-tetragastrin derivatives of increasing fatty acid chain length were used to identify the minimum size of the fatty acid moieties (> or = C10) that restricts the access to the CCK-B/gastrin (CCK: cholecystokinin) receptor via a membrane-bound pathway. Then dimyristoyl-mercaptoglycerol/maleoyl-gastrin adducts of increasing peptide chain length were synthesized to define the minimal peptide size required for receptor binding affinities comparable, to those of underivatized gastrin peptides despite anchorage of the lipid tails in the membrane bilayer. The experimental results indicated that most of the little-gastrin sequence, i.e., 2-17, is needed for optimal interaction of the molecule with the binding cleft of the receptor. From these data experimentally based restraints could be derived for docking of lipo-gastrin onto a CCK-B/gastrin receptor model applying molecular dynamics simulations and energy minimizations. In the receptor-bound state some of the secondary structure elements of gastrin as determined by nmr analysis of gastrin-peptides in low dielectric constant media are retained. The N-terminal gastrin portion interacts in a more or less extended conformation with the receptor surface, and upon a sharp kink at the Ala-Tyr dipeptide portion the C-terminal pentapeptide amide part inserts deeply into the helix bundle. Besides Arg-57 on top of helix 1 of the receptor, for which no potential interaction with the ligand could be detected, the other amino acid residues identified by mutagenesis studies as involved in gastrin recognition were found to interact with the C-terminal portion of gastrin. Even taking into account the strong limitations of such a model system, it represents an interesting tool for rationalizing the experimental results of the extensive structure-function studies performed previously on gastrin and to delineate more precisely the putative ligand binding site on the extracellular face of the receptor.

Identification of two amino acids of the human cholecystokinin-A receptor that interact with the N-terminal moiety of cholecystokinin.

A region between residues 38 and 42 of the human cholecystokinin-A (CCK-A) receptor was shown to be involved in the binding of CCK but not in that of JMV 179 and JMV 180, two peptides closely related to CCK (Kennedy, K., Escrieut, C., Dufresne, M., Clerc, P., Vaysse, N., and Fourmy, D. (1995) Biochem. Biophys. Res. Commun. 213, 845-852). In the present study, we have identified the residues of both the receptor and the ligand responsible for this differential binding. Residues Trp-39 and Gln-40 of the receptor were crucial for binding of the C-terminal nonapeptide of CCK as W39F and Q40N mutants demonstrated parallel decreases in both affinity and potency to induce accumulation of inositol phosphates (12.9- and 20.9-fold). The W39F and Q40N mutant receptors bound CCK analogues modified at their C-terminal end, including JMV 179 and JMV 180, as well as the C-terminal amidated heptapeptide of CCK, with identical affinities to the wild-type receptor. In contrast, W39F and Q40N mutants bound CCK octapeptide with the same decreased affinity as the CCK nonapeptide. The modeling of the CCK-A receptor and the docking of the peptide agonists [Thr,Nle]CCK9 and CCK-8 indicated that their N terminus was connected to the receptor through a strong bond network involving Trp-39 and Gln-40 thus confirming experimental data. These first molecular data identifying the agonist binding site of the human CCK-A receptor represent an important step toward the complete delineation of the agonist binding site and the understanding of the molecular mechanisms that govern differential activation of this receptor by CCK-related peptides.

Molecular cloning, developmental expression and pharmacological characterization of the CCKB/gastrin receptor in the calf pancreas.

We have cloned the calf predominant pancreatic cholecystokinin B (CCKB)/gastrin receptor cDNA. It encodes a 454 amino acid protein with 90% identity with the CCKB/gastrin receptor cloned in other species and tissues. However, the calf pancreatic CCKB/gastrin receptor contains a pentapeptide cassette within the third intracellular loop which is absent in the cloned human brain and stomach receptor. Quantification of the CCKB/gastrin receptor mRNA levels by reverse transcription polymerase chain reaction demonstrated the same level of transcripts at birth, +7 and +28 days. On the other hand, binding study with pancreatic membranes showing a dramatic increase (600-fold) in the number of CCKB/gastrin receptor sites between at birth and +28 days indicates that the development of the calf pancreatic CCKB/gastrin receptor occurs during the first 4 weeks of post-natal life. COS monkey cells (COS-7 cells) transiently transfected by the cloned cDNA exhibit binding of 125I-Bolton-Hunter-[Thr28,Ahx31]CCK-(25-33) and 125I-Bolton-Hunter-[Leu15]human gastrin-(2-17) to two affinity classes of sites. Kd values of the high affinity binding components indicate a 4-fold higher affinity of the receptor for sulfated gastrin than for CCK. Finally, the recombinant receptor is coupled to G proteins and [Ca2+]i mobilization, and is expressed as a glycoprotein of 82 kDa.

Identification of a region of the N-terminal of the human CCKA receptor essential for the high affinity interaction with agonist CCK.

The discovery of an N-terminally truncated isoform of the cholecystokinin A subtype (CCKA) receptor exhibiting an atypical pharmacology led us to study the effects of N-terminal truncation on the pharmacology of the human CCKA receptor. We cloned the cDNA encoding the full CCKA receptor and constructed two truncated forms, one which lacked the first 37 amino acids (CCKAT38) and another which lacked the first 42 amino acids (CCKAT43). Expression of the receptors in COS-7 cells showed that the CCKAT38 receptor displayed a pharmacological profile identical to that of the full receptor. In contrast, the CCKAT43 receptor did not directly bind agonist CCK9; however, the agonist could compete for binding at low affinity sites. Binding of the partial agonist JMV180 and the antagonist JMV179 were unaffected. These results identify for the first time a part of the N-terminal, close to the membrane, of the human CCKA receptor that is essential for the high affinity interaction with CCK.

Photoaffinity labeling of rat pancreatic cholecystokinin type A receptor antagonist binding sites demonstrates the presence of a truncated cholecystokinin type A receptor.

During the past few years, several antagonist ligands for cholecystokinin (CCK) receptors have been discovered, but the mechanism of action of these candidate drugs, as well as the nature of their molecular targets, remains poorly documented. In a previous study, we developed a new antagonist radioligand, 125I-Bolton-Hunter-labeled JMV-179, for the CCK-A receptor (CCK-AR), to analyze CCK antagonist binding sites in pancreatic plasma membranes. We found that 125I-Bolton-Hunter-labeled JMV-179 identified 4 times as many sites as did an agonist radioligand, although agonists were able to interact competitively with the entire population of antagonist sites. In the present work, using biochemical approaches we have identified and characterized CCK antagonist binding sites in pancreatic plasma membranes. We synthesized the photoactivable antagonist probe 125I-azidosalicyclic acid (ASA)-JMV-179. The binding of 125I-ASA-JMV-179 to plasma membranes was inhibited by JMV-179 (IC50, 6 +/- 2 nM), by (Thr28, Ahx31)-CCK-25-33 (IC50, 1.2 +/- 0.5 nM), and by the nonpeptide CCK-AR antagonist L-364,718 (IC50, 2 +/- 1 nM). Photoaffinity labeling using pancreatic membranes or acini demonstrated that 125I-ASA-JMV-179 detected a new 47-50-kDa protein in addition to the 85-100-kDa CCK-AR. The 47-50-kDa protein was not directly detected by a photoactivable agonist, but agonists could inhibit its covalent labeling by 125I-ASA-JMV-179 (IC50 for (Thr28,Ahx31)-CCK-25-33, 15 nM). In competition assays using nonsolubilized or solubilized membranes, this protein displayed binding features of the CCK-AR and was retained on immobilized wheat germ agglutinin, as was the CCK-AR. To further characterize the 47-50-kDa protein, deglycosylation and protease digestions were performed, and the digestion products were separated by sodium dodecyl sulfate-polyacrylamide gel electrophoresis. Protease digestions of both the CCK-AR and the 47-50-kDa protein yielded identical labeled fragments, demonstrating a structural relationship between the two proteins. The CCK-AR, which has three potential sites for N-glycosylation on the amino-terminal extracellular domain and one on the second extracytoplasmic loop, was deglycosylated to a 42-kDa peptide. The 47-50-kDa protein was deglycosylated to a 35-kDa peptide. These data, and the localization of the labeled fragments in the amino acid sequence of the receptor, suggest that the 47-50-kDa protein represents a CCK-AR lacking its amino-terminal extracellular domain.(ABSTRACT TRUNCATED AT 400 WORDS)

Study of the states and populations of the rat pancreatic cholecystokinin receptor using the full peptide antagonist JMV 179.

The full peptide antagonist of the pancreatic cholecystokinin (CCK) receptor, JMV 179, [Boc-Tyr(SO3H)-Ahx-Gly-dTrp-Ahx-Asp phenylethyl ester, where Tyr(SO3H) = sulfated tyrosine, Ahx = 6-aminohexanoic acid] was modified at its N-terminus by incorporation of p-hydroxyphenyl propionate (Bolton-Hunter reagent, BH) and was subsequently radioiodinated. After HPLC purification, 125I-BH-JMV-179, a CCK antagonist radioligand of high specific activity (2000 Ci/mmol) was obtained. 125I-BH-JMV-179 bound to a single population of sites on rat pancreatic plasma membranes, (Kd = 3.9 nM, Bmax = 40 pmol/mg protein). Binding was dependent on time, temperature, and protein concentration, and was fully reversible. JMV 179 radioligand detected four times as many sites as an agonist radioligand [C. Hadjiivanova, M. Dufresne, S. Poirot, P. Sozzani, N. Vaysse, L. Moroder and D. Fourmy (1992) Eur. J. Biochem. 204, 273-279]. Agonists and antagonists of the A- and B-subtype CCK/gastrin receptors inhibited 125I-BH-JMV-179 binding with an order of potency compatible with the A-subtype CCK receptor pharmacology. Moreover, the sulfate group on the tyrosine residue of the CCK peptides appeared to be of much less importance for antagonist affinity than for agonist affinity. Inhibition of 125I-BH-JMV-179 binding by agonists (except JMV 180), demonstrated the presence of two affinity classes of binding sites. The population of sites having an apparent high affinity for CCK represented 30 pmol/mg protein and threefold the number of high-affinity sites previously identified by an agonist radioligand. In presence of non-hydrolyzable GTP, all the sites bound CCK agonists with a low affinity. Moreover, saturation analysis of JMV 179 radioligand binding in the presence of CCK indicated that CCK interacted competitively with all JMV 179 sites and demonstrated binding of JMV 179 radioligand to two distinct affinity classes of sites. In the presence of GTP[S] a single affinity class of sites for JMV 179 radioligand was found as in the control experiments without CCK. This study, with the first CCK peptide antagonist radioligand, demonstrates that CCK receptors exist in two interconvertible affinity states regulated by guanine-nucleotide-binding regulatory protein(s) in rat pancreatic plasma membranes. JMV 179 radioligand does not induce receptor coupling but distinguishes the two affinity states of the CCK receptors. JMV 179 reveals the existence of populations of high-affinity and low-affinity sites for CCK which had not previously been detected by agonist radioligand binding, thus suggesting heterogeneity of CCK receptor sites in membranes.

Cadmium-induced alterations of chlorpropham metabolism in isolated rat hepatocytes.

In order to investigate the various steps of chlorpropham (CIPC) metabolism which could be influenced by cadmium, isolated rat hepatocytes were incubated in the presence of CIPC (0.1 mM) and of increasing Cd concentrations (0-180 microM). The results showed that Cd accumulation in hepatocytes was in good correlation to its concentration in the incubation medium. At 90 microM Cd, hydroxylation of CIPC was only slightly decreased by 30%, while CIPC hydrolysis into 3-chloraniline was unaffected by the presence of Cd. Accordingly, unchanged CIPC increased in hepatocytes. At 27 microM Cd, free 4-hydroxychlorpropham (4-OHCIPC) increased in the intracellular medium as a consequence of a strong suppression of both sulfation and glucuronidation which was related to the strong depletion of the intracellular ATP level under the combined influences of both cadmium and free 4-OHCIPC. Acetylation of 3-chloroaniline, which represents a minor pathway of CIPC metabolism, was already markedly suppressed (43%) with the lowest Cd concentration (27 microM). These in vitro results suggest that Phase II reactions are more sensitive to Cd than Phase I processes and that Cd enhanced the CIPC cytotoxicity as shown by alterations of the membrane integrity.