Importance of the vasoactive intestinal peptide receptor in the stimulation of cyclic adenosine 3',5'-monophosphate in gallbladder epithelial cells of man. Comparison with the guinea pig.

An EDTA procedure was used to prepare isolated epithelial cells of human gallbladder devoid of endogenous vasoactive intestinal peptide (VIP) as measured by radioimmunoassay. Specific binding sites for VIP were characterized in these cells. At 37 degrees C, the binding of (125)I-labeled VIP reached a peak within 20 min and then declined rapidly. At 15 degrees C, binding was stable between 90 and 180 min of incubation. Binding of the labeled peptide was inhibited by concentrations of native VIP of 30 pM-0.1 muM. Half-maximal inhibition was observed at 2 nM. Scatchard analysis indicated two functionally independent classes of receptor sites: 62,000 high affinity sites/cell with a dissociation constant (K(d)) of 1.3 nM, and 510,000 low affinity sites/cell with a K(d) of 16.2 nM. Secretin inhibited tracer binding but with a 1,000 times lower potency than native VIP. VIP strongly stimulated adenosine 3':5' monophosphate (cyclic AMP) production in human gallbladder epithelial cells. At 37 degrees C, 0.1 nM and 10 nM VIP raised cyclic AMP levels 44 and 100 times above the basal level, respectively. Maximal values remained constant between 60 and 90 min at 15 degrees C. The importance of the VIP-induced cyclic AMP rise was related, at least in part, to a low phosphodiesterase activity in human gallbladder epithelial cells. At equilibrium, during a 60-min incubation at 15 degrees C, cyclic AMP production was noted at concentrations of VIP as low as 3 pM. Maximal and half-maximal stimulations were observed at 10 nM and 0.2 nM VIP, respectively. Secretin also stimulated cyclic AMP production but with a 10,000 lower potency than VIP. In the guinea pig, VIP and secretin were equipotent stimulators of cyclic AMP in gallbladder epithelial cells. This particular feature was shown to be due to receptors specific for each peptide that were present in these cells.

PepT1-mediated epithelial transport of dipeptides and cephalexin is enhanced by luminal leptin in the small intestine.

Dietary proteins are mostly absorbed as di- and tripeptides by the intestinal proton-dependent transporter PepT1. We have examined the effects of leptin on PepT1 function in rat jejunum and in monolayers of the human enterocyte-like 2 cell Caco-2. Leptin is produced by the stomach and secreted in the gut lumen. We show here that PepT1 and leptin receptors are expressed in Caco-2 and rat intestinal mucosal cells. Apical (but not basolateral) leptin increased Caco-2 cell transport of cephalexin (CFX) and glycylsarcosine (Gly-Sar), an effect that was associated with increased Gly-Sar uptake, increased membrane PepT1 protein, decreased intracellular PepT1 content, and no change in PepT1 mRNA levels. The maximal velocity (Vmax) for Gly-Sar transport was significantly increased by leptin, whereas the apparent Michaelis-Menten constant (Km) did not change. Furthermore, leptin-stimulated Gly-Sar transport was completely suppressed by colchicine, which disrupts cellular translocation of proteins to plasma membranes. Intrajejunal leptin also induced a rapid twofold increase in plasma CFX after jejunal perfusion with CFX in the rat, indicating enhanced intestinal absorption of CFX. These data revealed an unexpected action of gastric leptin in controlling ingestion of dietary proteins.

Vasoactive intestinal peptide control of cyclic adenosine 3':5'-monophosphate levels in seven human colorectal adenocarcinoma cell lines in culture.

This study was undertaken to assess the role of vasoactive intestinal peptide (VIP) in the control of cyclic adenosine 3':5'-monophosphate production in colonic tumor cells. Seven human colorectal adenocarcinoma cell lines in culture were investigated (HT-29, HRT-18, SW-480, Caco-2, CO-115, CO-125, and HCT-8R). These cell-lines had a cyclic adenosine 3':5'-monophosphate production system which was very sensitive to VIP but less so to prostaglandin E1 and/or isoproterenol. Nonintestinal human malignant epithelial cells, such as HeLa (cervix) and Caki-1 and Caki-2 (kidney), by contrast, did not respond to VIP. The dose-response relationships of malignant colorectal cells were compared to those obtained with epithelial cells of normal human colon and showed that: (a) maximal responses were observed with 0.1 micro M VIP in both malignant and normal cells; (b) half-maximal responses were elicited by VIP concentrations in the 0.3 to 2 nM range in malignant cells (1.2 nM in normal cells), thus indicating the high apparent affinity of the cells to VIP; and (c) the magnitudes of the responses (stimulated:basal ratios) were highly variable in malignant cells, ranging from 225 in HT-29 cells to 3.5 in Caco-2 cells, but were more constant, in the order of 25, in normal cells. Secretin, a VIP agonist in intestinal tissue, stimulated cyclic adenosine 3':5'-monophosphate accumulation in all colorectal cells, but with a 1000- to 5000-fold lower potency than did VIP. These results show that the VIP-sensitive adenylate cyclase system operates in malignant as well as in normal colon epithelial cells.

Characterization of specific binding sites for vasoactive intestinal peptide in rat intestinal epithelial cell membranes.

Specific binding sites for vasoactive intestinal peptide were characterized in plasma membranes from rat intestinal epithelial cells. At 30 degrees C, the interaction of 125I-labelled peptide with intestinal membranes was rapid, reversible, specific and saturable. At equilibrium, the binding of 125I-labelled peptide was competitively inhibted by native peptide in the 3 . 10(-11)--3 . 10-(7) M range concentration. Scatchard analysis of binding data suggested the presence of two distinct classes of vasoactive intestinal peptide binding sites: a class with a high affinity (Kd = 0.28 nM) and a low capacity (0.8 pmol peptide/mg membrane protein) and a class with a low affininty (Kd = 152 nM) and a high capacity (161 pmol peptide/mg membrane protein). Secretin competitively inhibited binding of 125I-labelled peptide but its potency was 1/1000 that of native peptide. Glucagon and the gastric inhibitory peptide were ineffective. The guanine nucleotides, GTP and Gpp(NH)p inhibited markedly the interaction of 125I-labelled peptide with its binding sites, by increasing the rate of dissociation of peptide bound to membranes. The other nucleotides triphosphate tested (ATP, ITP, UTP, CTP) were also effective in inhibiting binding of 125I-labelled peptide to membranes but their potencies were 1/100--1/1000 that of guanine nucleotides. The specificity and affinity of the vasoactive intestinal peptide-binding sites in plasma membranes prepared from rat intestinal epithelial cells, which is in agreement with an adenylate cyclase highly sensitive to the peptide recently characterized in these membranes (Amiranoff, B., Laburthe, M., Dupont, C. and Rosselin, G. (1978) Biochim. Biophys. Acta 544, 474--481) further argue for a physiological role of the peptide in the regulation of intestinal epithelial function.

Characterization of a vasoactive intestinal peptide-sensitive adenylate cyclase in rat intestinal epithelial cell membranes.

A vasoactive intestinal peptide-sensitive adenylate cyclase in intestinal epithelial cell membranes was characterized. Stimulation of adenylate cyclase activity was a function of vasoactive intestinal peptide concentration over a range of 1 . 10(-10)-1 . 10(-7) M and was increased six-times by a maximally stimulating concentration of vasoactive intestinal peptide. Half-maximal stimulation was observed with 4.1 +/- 0.7 nM vasoactive intestinal peptide. Fluoride ion stimulated adenylate cyclase activity to a higher extent than did vasoactive intestinal peptide. Under standard assay conditions, basal, vasoactive intestinal peptide- and fluoride-stimulated adenylate cyclase activities were proportional to time of incubation up to 15 min and to membrane concentration up to 60 microgram protein per assay. The vasoactive intestinal peptide-sensitive enzyme required 5-10 mM Mg2+ and was inhibited by 1 . 10(-5) M Ca2+. At sufficiently high concentrations, both ATP (3 mM) and Mg2+ (40 mM) inhibited the enzyme. Secretin also stimulated the adenylate cyclase activity from intestinal epithelial cell membranes but its effectiveness was 1/1000 that of vasoactive intestinal peptide. Prostaglandins E1 and E2 at 1 . 10(-5) M induced a two-fold increase of cyclic AMP production. Vasoactive intestinal peptide was the most potent stimulator of adenylate cyclase activity, suggesting an important physiological role of this peptide in the cyclic AMP-dependent regulation of the intestinal epithelial cell function.

Peptide YY and neuropeptide Y in the gut: availability, biological actions, and receptors.

Intensive research on the actions of peptide YY(PYY) and neuropeptide Y (NPY) on the gut has been stimulated by findings of potent anti-secretory effects in small intestine and the discovery of their common receptor in this tissue. There is evidence that the hormone PYY and the neurotransmitter NPY are involved in the regulation of fluid and electrolyte secretion, motility, and blood flow in the intestine. Intestinal PYY/NPY receptors may have pharmacological value for the treatment of diarrhea.

Peptide-YY and neuropeptide-Y inhibit vasoactive intestinal peptide-stimulated adenosine 3',5'-monophosphate production in rat small intestine: structural requirements of peptides for interacting with peptide-YY-preferring receptors.

Previous binding studies indicated that peptide-YY (PYY) and neuropeptide-Y (NPY) shared a common PYY-preferring receptor site in rat small intestinal epithelium. We showed here that PYY and NPY inhibited vasoactive intestinal peptide (VIP)-stimulated cAMP production in epithelial cells isolated from rat small intestine and examined their structure-activity relationship. Inhibition of VIP-stimulated cAMP by PYY or NPY is time and dose dependent; half-maximal effects were observed for 10 and 107 nM, respectively. In contrast, the structurally related peptide, pancreatic polypeptide, was only active at 1 microM. PYY or NPY reduced the efficacy of VIP by about 50% without altering its potency. Both peptides also suppressed prostaglandin E1-, prostaglandin E2-, and forskolin-stimulated cAMP production and reduced basal cAMP levels. Their inhibitory effects were observed throughout the small intestine, including duodenum, jejunum, and ileum, but not in large intestine. PYY or NPY and epinephrine (through alpha 2-adrenergic receptors) did not exert additive inhibitory effects on intestinal cAMP production. Several fragments of PYY and NPY were used to characterize their structural requirement for inhibiting VIP-stimulated cAMP production and competing with [125I]PYY for binding to intestinal membranes. A highly significant correlation was observed between IC50 values measured in the two assays. No partial sequence of PYY retained the full activity of intact PYY, but the C-terminal portion of PYY was shown to be much more important than the N-terminal portion. Deletion of 21 amino acids from the N-terminus [PYY-(22-36)] only resulted in a 4- to 5-fold decrease in potency compared to that of PYY-(1-36). In contrast, PYY-(27-36) exhibited a drastic loss of potency. The N-terminal fragments PYY-(1-22) and PYY-(1-28) also had very low potencies. Similar results were obtained with NPY fragments. These results provide the first insight on the negative coupling of PYY-preferring receptors with the cAMP production system in small intestine and evidence of the crucial role of the C-terminal portion of PYY in interaction with these receptors.

Interaction of peptide YY with rat intestinal epithelial plasma membranes: binding of the radioiodinated peptide.

High affinity binding sites for peptide YY (PYY) have been identified and characterized in plasma membranes prepared from rat jejunal epithelium by studying the kinetics, stoichiometry, and chemical specificity of the interaction of 125I-labeled PYY with membranes. Binding of [125I]PYY was rapid, saturable, reversible, specific, and depended on temperature, pH, and ionic strength. In optimized steady state conditions of binding (2 h of incubation at 15 C), the degradation of both [125I] PYY and binding sites did not exceed 20%. The concentration dependence of PYY binding, determined by adding increasing concentrations of [125I]PYY, indicated that specific binding saturated at 2-3 nM peptide. Scatchard analysis revealed a single class of binding sites with a dissociation constant (Kd) of 434 +/- (SE) 56 pM and a binding capacity of 336 +/- 41 fmol/mg protein (n = 11). Identical results were obtained when increasing concentrations of unlabeled PYY were added to a fixed concentration of [125I]PYY, indicating that the radioiodinated peptide has the same apparent affinity as native PYY. Peptides structurally unrelated to PYY, such as members of the vasoactive intestinal peptide family, insulin, or cholecystokinin octapeptide, were unable to compete with [125I]PYY for binding to membranes. Rat, human, and avian pancreatic polypeptides, which display, respectively, 42%, 47%, and 53% homology with PYY, did inhibit [125I]PYY binding but with an approximate or equal to 100,000-fold lower potency than PYY, indicating the strict structural requirement for recognition by PYY binding sites. In contrast, natural or synthetic neuropeptide Y, which has 25 out of 36 amino acids in common with PYY, retained a high affinity for PYY binding sites [only 4.7 +/- 1.2 (n = 5) times lower than that of PYY]. Specific [125I]PYY binding was particularly high in the upper small intestine and could not be detected in stomach, large intestine, or liver. These findings indicate that rat small intestinal epithelium expresses specific binding sites for the candidate gut hormone PYY that also binds the neuropeptide Y with high affinity, suggesting that the two peptides may regulate the function of small intestinal epithelium, through interaction with a common receptor site.

Characterization of galanin receptors in the insulin-secreting cell line Rin m 5F: evidence for coupling with a pertussis toxin-sensitive guanosine triphosphate regulatory protein.

The present work characterizes galanin receptors in the insulin-secreting pancreatic beta-cell line Rin m 5F and documents their regulation by guanine nucleotides. Binding of [125I]galanin to cell membranes was found to be temperature dependent, rapid, saturable, reversible, and highly peptide specific. Optimal steady state conditions were achieved after a 60-min incubation at 15 C. The concentration dependence of galanin binding determined by adding increasing concentrations of [125I]galanin indicated that galanin receptors were saturated at 2-3 nM peptide. Scatchard analysis revealed a single class of receptors, with a Kd of 0.3 nM and a binding capacity of 82 fmol/mg protein. Guanyl 5'-yl imidodiphosphate dramatically enhanced the dissociation of bound [125I]galanin. Some guanine nucleotides inhibited [125I]galanin binding to membranes with the following order of potency: guanyl 5'-yl imidodiphosphate greater than GTP = GDP. Other nucleotides had no effect. The effect of the guanine nucleotides was Mg2+ dependent, but Na+ independent, although Mg2+ ions alone (5 mM) slightly enhanced [125I]galanin binding, and Na+ ions alone (100 mM) induced a 60% decrease in the binding. Finally, overnight treatment of Rin m 5F cells with pertussis toxin (0.4 microgram/ml) dramatically reduced [125I]galanin binding to cell membranes. This was related to a 4-fold decrease in receptor affinity, with no change in binding capacity. In conclusion, for the first time evidence of the existence of galanin receptors on functional pancreatic beta-cells is presented. Also, other findings support the fact that galanin receptors are functionally associated with a pertussis toxin-sensitive GTP-binding protein mediating guanine nucleotide control of galanin binding.

Identification and functional studies of a specific peptide YY-preferring receptor in dog adipocytes.

Specific binding sites for peptide YY (PYY) and neuropeptide Y (NPY) as well as functional responses were identified in dog adipocytes. Studies were carried out using the radioligand [125I-Tyr1]monoiodo-PYY on crude adipocyte membranes. [125I]PYY bound to dog adipocyte membranes with a high affinity (156 +/- 24 pM) and binding capacity of 314 +/- 48 fmol/mg protein. Competition studies revealed a higher affinity of the binding sites for PYY than NPY (inhibition constants were 118 +/- 17 pM and 300 +/- 53 pM, respectively, P < or = 0.001). NPY analogs displaced [125I]PYY specific binding with the following order of potency: NPY-(13-36) > NPY-(18-36) > NPY-(22-36) >> [Leu31-Pro34]NPY. Neither adrenergic nor adenosine agents (activating or inhibiting other antilipolytic systems) interacted with [125I]PYY binding sites. So [125I]PYY binding was specific, saturable, and reversible. Lipolysis experiments performed with PYY, NPY, and NPY analogs confirm the relative order of potency found in competition experiments. The data agree with the definition of PYY-preferring receptor which resembles a Y2 receptor subtype since NPY-(13-36), a specific Y2 receptor agonist, inhibited binding and lipolysis in a similar way to PYY, whereas [Leu31-Pro34]NPY did not. No difference was observed in the antilipolytic response between IC50 values measured on omental, perirenal, and subcutaneous fat deposits. Moreover, PYY and NPY (10(-6) M) significantly attenuated forskolin-stimulated cAMP levels, involving inhibition of adenylyl cyclase as a transmembrane signaling mechanism. Cross-linking of bound [125I]PYY to membranes indicated that the mol wt of the receptor was 62K. The relative importance of such a receptor on fat cells alongside another powerful antilipolytic receptor--the alpha 2-adrenoceptor--is discussed.

Galanin receptors in a hamster pancreatic beta-cell tumor: identification and molecular characterization.

High affinity binding sites for galanin are identified and characterized in membranes from a hamster pancreatic beta-cell tumor. Using the radioiodinated peptide [125I] galanin, interaction of the peptide with pancreatic membranes is shown to be saturable, reversible, and time, temperature, membrane protein concentration, pH, and ionic strength dependent. In optimized equilibrium conditions of binding (90 min at 10 C), native galanin competitively inhibits the binding of [125I]galanin in a dose-dependent manner (from 10(-11)-10(-8) M); half-maximal inhibition is induced by 1 nM peptide. Scatchard analysis indicates the existence of a single population of sites of high affinity (Kd = 1.5 nM) and low capacity (44 fmol/mg protein). The monophasic dissociation process confirms the homogeneity of galanin-binding sites. Galanin-binding sites are highly specific, since apart from native galanin, none of the numerous biologically active peptides tested competes with [125I] galanin for binding to pancreatic membranes. The cross-linking of [125I]galanin to beta-cell membranes is performed using the chemical bifunctional reagent ethylene glycol bis-(succinimidyl succinate). After sodium dodecyl sulfate-polyacrylamide gel electrophoresis analysis in the presence or absence of dithiothreitol, one single band of 57,000 mol wt is observed, which may be corresponding to the [125I]galanin-receptor complex. Indeed, labeling of this 57,000 mol wt component is abolished only by native galanin but is unaffected by various other digestive peptides. Assuming one molecule of [125I]galanin is bound per molecule of protein, a 54,000 mol wt protein is identified as the pancreatic galanin receptor. In conclusion, our results indicate for the first time the identification of galanin receptors. Their presence in pancreatic beta-cells suggests a direct role of galanin in regulating endocrine beta-cell function.

Evidence for and characterization of specific high affinity binding sites for the gastric inhibitory polypeptide in pancreatic beta-cells.

High affinity binding sites have been found in membrane preparations from hamster beta-cell tumors by using radiolabeled gastric inhibitory polypeptide (125I-GIP). HPLC of 125I-GIP resulted in two major peaks (A III and B III), with identical specific binding. It was verified that peaks A III and B III stimulate insulin release from the isolated perfused rat pancreas to an extent at least equal to that obtained with unlabeled GIP at 10(-9) M. Natural GIP competitively inhibited the binding of 125I-GIP in the range of 10(-10) -10(-6) M and half-maximal inhibition was observed at 1.9 +/- 0.19 X 10(-9) M GIP. The number of high affinity sites was 219 +/- 8 fmol/mg protein and the dissociation constant was 2.05 +/- 0.1 X 10(-9) M. None of 10 regulatory peptides tested exhibited any effect on the 125I-GIP binding at concentrations in the range of 10(-6) -10(-4) M. Consequently, saturable, high affinity and specific binding sites for the GIP have been found and characterized in the plasma membranes of beta-cells. This model can be of use in studying the interaction of GIP with its preponderant target tissue.

The human vasoactive intestinal peptide receptor: molecular identification by covalent cross-linking in colonic epithelium.

To characterize the molecular components of the vasoactive intestinal peptide (VIP) receptor in human intestine, [125I]VIP was covalently bound to human colonic epithelial membranes using dithio-bis(succinimidyl propionate). Sodium dodecyl sulfate-polyacrylamide gel autoradiographic studies of affinity labeled membranes revealed three major bands corresponding to [125I]VIP-protein complexes of 66,000, 33,000, and 16,000 mol wt. Labeling of the 66,000 and 33,000 mol wt complexes was specific, since it was abolished by VIP, while labeling of the 16,000 mol wt complex was not. Densitometric scanning of autoradiographs indicated that labeling of the 66,000 mol wt complex was inhibited by low VIP concentrations in the 10(-10)-10(-8) M range, but was unaffected by glucagon or octa-cholecystokinin. It was also reduced by VIP-(2-28), with a potency 1/100th that of VIP, and by GTP in the concentration range of 10(-7)-10(-3) M. The 33,000 mol wt complex behaved similarly to the 66,000 mol wt complex with respect to specificity and GTP sensitivity, but differed in one major feature, its affinity for VIP. Its labeling was inhibited by native VIP concentrations in the 10(-9)-10(-7) M range. Assuming one molecule of [125I]VIP bound per molecule of protein, two proteins of 63,000 and 30,000 mol wt were identified as VIP-binding sites. The 63,000 mol wt protein had the properties expected for the VIP receptor coupled to adenylate cyclase in human colon, while the 30,000 mol wt protein was a low affinity binding site. Treatment of human colonic membranes with the sulfhydryl reducing agent dithiothreitol before [125I]VIP binding strongly reduced the labeling of the two proteins. This finding does not support the hypothesis that the low affinity 30,000 mol wt binding site may be a monomer of the high affinity binding site.

Characterization of vasoactive intestinal peptide receptors in human colonic epithelial cells.

Receptors, i.e. specific binding sites for vasoactive intestinal peptide (VIP), have been characterized in human colonic epithelial cells isolated by EDTA treatment using 125I-labeled porcine VIP. The binding was time and temperature dependent. Conditions of apparent equilibrium were obtained at 15 C after 45 min of incubation in the presence of 2.1-7.4 micrograms cell DNA-ml; these conditions minimized the degradation of the peptide and the binding sites. Native VIP competitively inhibited the binding of [125I]VIP in the range of 3 x 10(-11)-10(-7) M, and half-maximal inhibition was observed at 2 x 10(-9) M VIP. Scatchard analysis of these data was consistent with the existence of two classes of binding sites: 7.8 x 10(-9) high affinity sites/microgram DNA with a dissociation constant (Kd) of 1.4 x 10(-9) M, and 12.0 x 10(10) low affinity sites/microgram DNA with a Kd of 46 x 10(-9) M. Among the natural hormones structurally related to VIP, gastric inhibitory polypeptide (GIP) and glucagon had no effect on the binding of labeled porcine VIP. Porcine secretin inhibited [125I]VIP binding, but at doses 1000 times higher than those of porcine VIP. Studies of the coupling between the binding of VIP and the stimulation of cAMP formation indicated a nonlinear relationship between the two processes, with full activation of the cAMP-producing system with occupancy of only a limited number of the binding sites. The presence of binding sites with high affinity for VIP coupled with the cAMP production in human colonic epithelial cells support the concept that this peptide may contribute to the physiological regulation of the functions of the human colonic epithelium in normal and pathological conditions.

Phorbol ester induces loss of VIP stimulation of adenylate cyclase and VIP-binding sites in HT29 cells.

Treatment of HT29 cells with the tumor promoting phorbol ester PMA resulted in an attenuation of VIP-stimulated cAMP production in intact cells and VIP-stimulated adenylate cyclase activity in cell membranes. PMA did not decrease the ability of cholera toxin and forskolin to elevate cAMP levels in intact cells. Fluoride-stimulated adenylate cyclase activity in HT29 cells homogenates was not affected by PMA. The maximal VIP binding capacity of homogenates prepared from HT29 cells treated with PMA was decreased by 50%. It is concluded that protein kinase C regulates VIP receptor function possibly through phosphorylation of the VIP receptor.

Interaction of Gila monster venom with VIP receptors in intestinal epithelium of human. A comparison with rat.

Gila monster venom (1-300 micrograms/ml) is shown to inhibit completely the binding of [125I]VIP to human and rat intestinal epithelial cell membranes. In both models, the venom inhibits [125I]VIP binding and stimulates adenylate cyclase with a maximal efficiency that is similar to that of VIP and a potency that is 10000-50000 times lower than that of the peptide, on a weight basis. At maximal doses, VIP and Gila monster venom do not exert an additive effect on adenylate cyclase, suggesting that the activation of the enzyme by the venom occurs through VIP receptors. As is the case for VIP, adenylate cyclase activation by Gila monster venom requires the presence of GTP in the incubation medium. Finally, no VIP-like immunoreactivity was detected in the venom using an antiserum raised against mammalian VIP. All these data suggest the presence in the venom of the Gila monster, of a new substance which behaves as a VIP agonist in human as well as rat intestine.

Interaction of GRF with VIP receptors and stimulation of adenylate cyclase in rat and human intestinal epithelial membranes. Comparison with PHI and secretin.

GRF (10(-8) - 10(-5) M) is shown to inhibit competitively the binding of [125I]VIP to human and rat intestinal epithelial membranes. The affinity of GRF for VIP receptor is 700-800-times lower than that of VIP in both species. The order of affinity of different peptides is VIP greater than PHI greater than secretin greater than GRF in rat, and VIP greater than GRF greater than PHI greater than secretin in man. The important species specificity of VIP receptors in recognizing PHI and secretin does not occur in the case of GRF. GRF stimulates adenylate cyclase through its interaction with VIP receptors in rat and human membranes. However, while GRF behaves as a VIP agonist in human tissue, it is a partial agonist/antagonist of VIP in the rat.

Structure-activity studies including a Psi(CH(2)-NH) scan of peptide YY (PYY) active site, PYY(22-36), for interaction with rat intestinal PYY receptors: development of analogues with potent in vivo activity in the intestine.

Peptide YY (PYY) is a gut hormone that inhibits secretion and promotes absorption and growth in the intestinal epithelium. We have performed structure-activity studies with the active site, N-alpha-Ac-PYY(22-36)-NH(2), for interaction with intestinal PYY receptors. Investigation of aromatic substitutions at position 27 resulted in analogues that exhibited potent in vitro antisecretory potencies with N-alpha-Ac-[Trp(27)]PYY(22-36)-NH(2) exhibiting even greater potency than intact PYY. In vivo studies in dogs revealed that this analogue also promoted intestinal absorption of water and electrolytes during continuous intravenous and intraluminal infusion. Investigations carried out to identify features that would enhance stability revealed that incorporation of Trp(30) increased affinity for PYY receptors. A "CH(2)-NH" scan revealed that incorporation of reduced bonds at position 28-29 or 35-36 imparted greater receptor affinity. In general, disubstituted analogues designed based on the results of single substitutions exhibited good receptor affinity with N-alpha-Ac-[Trp(27),CH(2)-NH(35-36)]PYY(22-36)-NH(2) having the greatest affinity (IC(50) = 0.28 nM). Conservative multiple substitutions with Nle-->Leu and Nva-->Val also imparted good affinity. An analogue designed to encompass most of the favored substitutions, N-alpha-Ac-[Nle(24,28),Trp(30),Nva(31), CH(2)-NH(35-36)]PYY(22-36)-NH(2), exhibited a proabsorptive effect in dogs comparable to, but longer lasting than, that of intact hormone. Selected analogues also exhibited good antisecretory potencies in rats with N-alpha-Ac-[Trp(30)]PYY(22-36)-NH(2) being even more potent than PYY. However, the potencies did not correlate well with the PYY receptor affinity or the proabsorptive potencies in dogs. These differences could be due to species effects and/or the involvement of multiple receptors and neuronal elements in controlling the in vivo activity of PYY compounds. PYY(22-36) analogues exhibited good affinity for neuronal Y2 receptors but poor affinity for Y1 receptors. Also, crucial analogues in this series hardly bound to Y4 and Y5 receptors. In summary, we have developed PYY(22-36) analogues which, via interacting with intestinal PYY receptors, promoted potent and long-lasting proabsorptive and antisecretory effects in in vivo models. These compounds or analogues based on them may have useful clinical application in treating malabsorptive disorders observed under a variety of conditions.

Intestinal VIP receptors: differential effect of trypsin on the high and low affinity binding sites.

The effects of trypsin treatment on VIP binding to rat intestinal epithelial cell membranes were examined. The decrease in specific binding of [125I]VIP is dependent on the amount of trypsin used and digestion time. Specific binding decreases by 50% after 8 min with 20 micrograms/ml trypsin. Trypsin is active in the 1-100 micrograms/ml concentration range (ED50 approximately equal to 5 micrograms/ml). Non-specific binding is unaltered by the enzyme. The effect of trypsin is abolished by trypsin inhibitor. Scatchard analysis of VIP binding reveals two types of binding sites: sites I characterized by a high affinity, a low capacity and a high sensitivity to low trypsin levels (1-5 micrograms/ml); sites II characterized by a low affinity, a high capacity, resistant to low trypsin levels (1-5 micrograms/ml) but sensitive to a high trypsin level (20 micrograms/ml). Trypsin decreases the binding capacity by lowering the site number without altering their affinity. Sites not destroyed by trypsin retain their functional characteristics: KD, sensitivity to GTP and coupling with adenylate cyclase. It is concluded that sites I and II are proteins with different structures and/or differently localized in the membrane.

Insulin-like growth factor II/mannose-6-phosphate receptors are transiently increased in the rat distal intestinal epithelium after resection.

The levels of insulin-like growth factor II/mannose-6-phosphate (IGF-II/Man-6-P) receptor and the insulin-like growth factor I (IGF-I) receptor were measured in the intestinal epithelium after 50% resection of the small intestine. Controls were either pair-fed to match the reduced food intake of the resected group or fed ad libitum. [125I]IGF-II binding was transiently increased 2-fold in the distal segment of the small intestine 3 days after resection compared with the pair-fed control. Receptor levels increased from 2.60 nmol/mg protein (pair-fed) to 4.63 nmol/mg protein (resected; p less than 0.001) with no significant change in affinity of IGF-II binding (Kd = 11.2 vs. 9.8 nmol/l). The increase in IGF-II/Man-6-P receptors coincided with increased activity of thymidine kinase in the distal intestinal segment after the resection. [125I]IGF-I binding remained unchanged after the resection. However, the decreased food intake of the pair-fed and resected groups caused a 2-fold increase in the amount of IGF-I receptors (0.18 nmol/mg protein; p less than 0.001) compared with the control fed ad libitum (0.08 nmol/mg protein). IGF-II/Man-6-P receptors were only moderately increased during restricted food intake (2.60 vs. 1.78 nmol/mg protein; p less than 0.005). These results suggest that the IGF-II/Man-6-P receptor may play a role in the adaptive regenerative response of the intestinal epithelium.