Abstract
Neither the native ligand nor the cell biology of the bombesin (Bn)-related orphan receptor subtype 3 (BRS-3) is known. In this study, we used RT-PCR to identify two human lung cancer lines that contain sufficient numbers of native hBRS-3 to allow study: NCI-N417 and NCI-H720. In both cell lines, [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) stimulates [3H]inositol phosphate. In NCI-N417 cells, binding of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) was saturable and high-affinity. [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) stimulated phospholipase D activity and a concentration-dependent release of [3H]inositol phosphate (EC50 = 25 nM) and intracellular calcium (EC50 = 14 nM); the increases in intracellular calcium were primarily from intracellular stores. hBRS-3 activation was not coupled to changes in adenylate cyclase activity, [3H]-thymidine incorporation or cell proliferation. No naturally occurring Bn-related peptides bound or activated the hBRS-3 with high affinity. Four different bombesin receptor antagonists inhibited increases in [3H]inositol phosphate. Using cytosensor microphysiometry, we found that [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) caused concentration-dependent acidification. The results show that native hBRS-3 receptors couple to phospholipases C and D but not to adenylate cyclase and that they stimulate mobilization of intracellular calcium and increase metabolism but not growth. The discovery of human cell lines with native, functional BRS-3 receptors, of new leads for a more hBRS-3-specific antagonist and of the validity of microphysiometry as an assay has yielded important tools that can be used for the identification of a native ligand for hBRS-3 and for the characterization of BRS-3-mediated biological responses.
The mammalian Bn-related peptides NMB and GRP mediate a diversity of biological responses, including thermoregulation, satiety, control of circadian rhythm, stimulation of pancreatic secretion and stimulation of GI hormone release (Tache et al., 1988). In addition, these peptides exhibit potent developmental effects and mitogenic effects on both normal and malignant cells (Tache et al., 1988). Two receptor subtypes have been well characterized, one having selectivity for GRP, the other having a greater selectivity for NMB (Kroog et al., 1995; Battey and Wada, 1991). Both subtypes have an architecture that resembles heptahelical G protein-coupled receptors (Kroog et al., 1995; Battey and Wada, 1991) and are coupled to similar signal transduction pathways: upon ligand binding, PLC activity ensues, resulting in protein kinase C activation and mobilization of intracellular calcium (Tache et al., 1988). Elevation of phospholipase D activity (Ben-Av et al., 1993; Hou et al., 1997) and tyrosine phosphorylation of intracellular proteins (Leeb-Lundberg and Song, 1991; Tsuda et al., 1997a) have also been described for these two receptor subtypes.
Recently, a 399-amino acid orphan receptor was identified in mammalian tissues (Gorbulev et al., 1992; Fathi et al., 1993) and has been proposed to represent a third mammalian Bn receptor subtype. This receptor, named bombesin receptor subtype 3 (BRS-3) because of its approximately 50% homology to GRP and NMB receptors (Fathi et al., 1993), has a pattern of expression that differs from the broader distribution described for the other established members of this receptor family. Studies of BRS-3 mRNA expression revealed a pattern limited to secondary spermatocytes (Fathiet al., 1993), pregnant uterus (Gorbulev et al., 1992), a few brain regions (Gorbulev et al., 1992) and tumor cell lines derived from human lung (Fathi et al., 1993), breast (Gorbulev et al., 1994) and epidermal tissues (Gorbulev et al., 1994). A recent study (Ohki-Hamazakiet al., 1997) using targeted disruption of the BRS-3 receptor demonstrates that it is important in regulating obesity and metabolic control of insulin and glucose. At present, the ligand is unknown, and there is a lack of cell lines expressing sufficient endogenous BRS-3 for study. However, recent studies using the newly discovered synthetic peptide agonist [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) in BALB 3T3 cells and NCI-H1299 lung cancer cells stably transfected with human BRS-3 suggest that BRS-3 employs signal transduction processes similar to those observed with the other Bn receptor subtypes (Mantey et al., 1997; Ryan et al., 1998).
In this study, we examined the ability of the novel peptide [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) to bind and stimulate intracellular signaling events in two lung cancer cell lines, NCI-N417 and NCI-H720, that natively express hBRS-3 (Fathiet al., 1993). In addition, we wanted to determine whether activation of native hBRS-3 receptors stimulated cell growth. With this compound, we demonstrate for the first time that in cells natively expressing this protein, BRS-3 receptors couple to phospholipase C to elicit IP metabolism and calcium mobilization as well as to phospholipase D to generate diacylglycerol. However, BRS-3 activation was not coupled to changes in activity of adenylate cyclase, nor did it cause cell proliferation. In addition, our results show that none of the currently known, naturally occurring Bn peptides were the putative ligand for hBRS-3. However, several synthetic peptides that function as GRP or NMB receptor antagonists also behaved as hBRS-3 antagonists, which could prove useful in determining the biological role of this receptor.
Finally, we examined the effect of [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) in a novel bioassay (McConnell et al., 1992) that permits real-time measurement of hBRS-3-mediated changes in metabolic rate in NCI-N417 cells. The discovery of cells that natively express functional hBRS-3 receptors and the discovery of the utility of metabolic rate activation as a bioassay represent important developments in our effort to understand the function of BRS-3.
Materials and Methods
Materials.
The following were kindly provided by or obtained from the sources indicated: NCI-N417 human small cell lung carcinoma cells and NCI-H720 human non-small cell lung carcinoma cells (Herb Oie of the NCI-Navy Medical Oncology Branch, Naval Medical Center, Bethesda, MD), A375-6 human melanoma cells (Pius Hildebrand, University Hospital, Basel, Switzerland), RPMI 1640, DMEM, PBS, G418 sulfate and FBS (Gibco BRL, Grand Island, NY), Tris HCl (Bethesda Research Labs, Gaithersburg, MD), formic acid, ammonium formate, disodium tetraborate, IBMX, epinephrine, EDTA, β-aminoethyl ether EGTA and soybean trypsin inhibitor (Sigma, St. Louis, MO), BSA fraction V (ICN Biomedicals Inc., Aurora, OH), aprotinin and HEPES (Boehringer Mannheim Biochemicals, Indianapolis, IN), AG 1-X8 resin (BIO-RAD, Richmond, CA), monobasic sodium phosphate (Mallinckrodt Inc., Paris, KY), Na[125I] (2200 Ci/mmol), [2-3H]adenine (22 Ci/mmol), [methyl-3H]-thymidine (25 Ci/mmol) and [9,10(n)-3H]palmitic acid (53 Ci/mmol) (Amersham Life Science Inc., Arlington Heights, IL), [γ-32P]ATP (3000 Ci/mmol) and myo-[2-3H] inositol (20 Ci/mmol) (Dupont/NEN, Boston, MA), 1,2,4,6-tetrachloro-3α-6α-diphenylglycouril (Iodo-Gen) (Pierce Chemical Co., Rockford, IL), silica gel G TLC plates (LK6D) (Whatman, Clifton, NJ), phosphatidylethanol (Avanti Polar Lipids, Birmingham, AL), PACAP-38, PACAP-27, Bn, neuromedin B, GRP, litorin, phyllolitorin, rohdei-litorin and ranatensin (Bachem, Torrence, CA), [dArg1,dTrp7,9,Leu11]substance P and [dPro4,dTrp7,9,10] substance P(4-11) (Peninsula Laboratories, Belmont, CA) and [Arg8] vasopressin (Novabiochem Corp., La Jolla, CA). [Phe13]bombesin, [Ser19]GRP(18-27) (frog GRP-10) and SAP-Bn were gifts from John Taylor of Biomeasure, Inc., Milford, MA. All other chemicals were reagent grade.
Materials and Methods
Cell culture.
NCI-N417, NCI-H720 and A375-6 cells were grown in RPMI-1640. Untransfected BALB 3T3 cells and BALB 3T3 cells transfected with human NMB receptors (Ryan et al., 1996) or human BRS-3 receptors (Mantey et al., 1997) were grown in DMEM. Both cell media were supplemented with 10% (v/v) FBS (plus 300 μg/ml G418 sulfate for the BALB 3T3 transfectants). All cell lines were incubated at 37°C in a 5% CO2 atmosphere.
Isolation of RNA.
Total RNA from all cell lines studied was isolated using the RNeasy Midi Kit (Qiagen, Inc., Chatsworth, CA) according to the instructions supplied by the manufacturer.
RT-PCR and Southern blotting.
For RT-PCR, first strand cDNA was created using 1.0 μg of total cellular RNA with the First Strand Synthesis Kit (BRL/Gibco, Grand Island, NY). Gene-specific primers for hBRS-3 receptor (Mantey et al., 1997), hGRP receptor (Manteyet al., 1997) and hNMB receptor (Mantey et al., 1997) were used for amplification of first strand cDNA. To ensure that only cDNA could be used as a template, the primers were positioned on either side of an intron. PCR was performed using the GeneAmp PCR System 9600 thermal cycler (Perkin Elmer Cetus, Emeryville, CA) under routine conditions recommended by the manufacturer. Separation of PCR products was achieved by electrophoresis on 1.2% (w/v) SeaKem GTG agarose gels (FMC BioProducts, Rockland, ME). The products were then transferred to nitrocellulose filters. Hybridization was carried out at room temperature for 16 hr in a hybridization buffer containing 40% (v/v) formamide (Fluka Chemical, Switzerland), 4 × SSC (300 mM sodium chloride, 30 mM sodium citrate; Research Genetics, Huntsville, AL), 20 mM Tris (pH 7.5) (Quality Biological, Gaithersburg, MD), 10% (v/v) dextran sulfate (Oncor, Gaithersburg, MD), 1 × Denhardt solution (Digene Diagnostics, Beltsville, MD), 20 μg/ml sonicated herring sperm DNA (Digene Diagnostics, Beltsville, MD) and hGRP receptor, hNMB receptor or hBRS-3 receptor synthetic oligonucleotide probes end-labeled with [γ-32P]ATP. The oligonucleotide probes contained gene-specific sequences between the gene-specific PCR primer pairs for each receptor. The nitrocellulose filters were washed with increasing stringency, with a final wash in 0.1 × SSC, 0.1% (v/v) at 25°C. After air-drying, the filters were exposed to XAR X-ray film (Kodak, Rochester, NY).
Preparation of peptides.
The peptides were synthesized by solid-phase methods as previously described (Coy et al., 1988; Wang et al., 1990; Orbuch et al., 1993). Introduction of the reduced peptide bond (ψ) in various peptides was performed on methylbenzhydrylamine resin (Advanced Chem Tech, Louisville, KY) (Coy et al., 1988).dNal,Cys,Tyr,dTrp,Lys,Val,Cys,NalNH2was synthesized as described previously (Orbuch et al., 1993), using methylbenzhydrylamine resin. Various alkylamide and ester analogs of Bn(6-13) were synthesized in a standard Leu-O-polystyrene resin, using tosyl group protection for the imidazole group of His (Wang et al., 1990). Free peptide was removed from the resin after synthesis by transesterification with 10% triethylamine/methanol at 40°C for 48 hr. The peptides were first purified on a Sephadex G-25 column (2.5 × 90 cm), followed by preparative HPLC on a Vydac C18 column (1.5 × 50 cm, bore size 10–15 μm). After rechromatography to achieve ≥97% purity, the peptides were characterized by amino acid analysis and matrix-assisted laser desorption mass spectroscopy (Finnegan, Hemel Hemstead, UK).
Preparation of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14).
125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14), with a specific activity of 2200 Ci/mmol, was prepared by methods described previously (Mantey et al., 1997). Briefly, 0.8 μg of an Iodo-Gen solution (0.01 μg in chloroform) was dried under nitrogen and washed with 100 μl of monobasic potassium phosphate (pH 7.4). To this solution, 20 μl of monobasic potassium phosphate (pH 7.4), 8 μg of [dTyr6,βAla11, Phe13,Nle14]Bn(6-14) in 4 μl of water and 2 mCi (20 μl) of Na[125I] were added, and the reaction was allowed to run at room temperature for 6 min after gentle mixing. The reaction was stopped by incubation of the mixture at 80°C for 60 min. The reaction mixture was added to a Sep-Pak (Waters Associates, Milford, MA), and free 125I was eluted with 5 ml of water followed by 0.1% (v/v) trifluoroacetic acid (TFA). Radiolabeled peptide was removed by sequential elution (10 × 200 μl) with 60% acetonitrile in 0.1% TFA. The fractions with the highest radioactivity were pooled and purified by reverse-phase HPLC as previously reported (Mantey et al., 1997). Fractions that tested positive for radioactivity and binding were neutralized with 0.2 M Tris (pH 9.5) and stored with 0.5% BSA (w/v) at −20°C.
Binding of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) to NCI-N417 cells.
NCI-N417 cells (1 × 107cells/ml) were incubated with 75 pM 125I-labeled ligand for the indicated durations and temperatures in a binding buffer solution containing 24.5 mM HEPES (pH 7.4), 98 mM sodium chloride, 6 mM potassium chloride, 2.5 mM monobasic sodium phosphate, 5 mM sodium pyruvate, 5 mM sodium fumarate, 5 mM sodium glutamate, 2 mM glutamine, 11.5 mM glucose, 0.5 mM calcium chloride, 1.15 mM magnesium chloride, 0.01% soybean trypsin inhibitor, 0.2% (v/v) amino acid mixture, 0.2% (w/v) BSA and 0.1% (w/v) bacitracin. Nonsaturable binding was the amount of radioactivity seen with 75 pM125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) in the presence of 1 μM [dTyr6,βAla11,Phe13,Nle14]Bn(6-14), and was <10% of total binding in all experiments. Receptor affinities of ligands were determined using a least-squares curve-fitting program (LIGAND) and the Cheng-Prusoff equation.
Dissociation of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) from NCI-N417 cells.
The time- and temperature-dependence of dissociation of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) from NCI-N417 cells was determined by incubation of the radioligand with the cells for 45 min at 25°C. The incubation mixture was then diluted 100-fold with binding buffer at the times indicated before filtering the cells on GF/B filters, which were washed and counted for saturably bound radioactivity.
Measurement of IP.
NCI-N417 or NCI-H720 cells (5 × 105 cells/ml) were subcultured into 75-cm2tissue culture flasks containing RPMI-1640 supplemented with 3 μCi/ml myo-[2-3H] inositol and 2% (v/v) FBS. After a 24-hr incubation period (37°C), the cells were washed and incubated for 10 min at 37°C with an equivalent volume of PBS (pH 7.0) containing 20 mM lithium chloride. The cells were then resuspended in an equivalent volume of IP assay buffer [135 mM sodium chloride, 20 mM HEPES (pH 7.4), 2 mM calcium chloride, 1.2 mM magnesium sulfate, 1 mM EGTA, 20 mM lithium chloride, 11.1 mM glucose and 0.05% BSA (w/v)], and 500 μl of cell suspension was added to tubes containing the peptides studied. For the hBRS-3-transfected BALB 3T3 cells, loading of myo-[2-3H] inositol and the assay protocol were as previously described (Benya et al., 1994). Briefly, cells were subcultured into 24-well plates (5 × 104cells/well) in their respective propagation media and then incubated at 37°C for 24 hr. The cells were incubated with 3 μCi/ml of myo-[2-3H] inositol in growth medium supplemented with 2% FBS for an additional 24 hr. Before assay, the 24-well plates were washed and incubated for 10 min at 37°C with 1 ml/well PBS (pH 7.0) containing 20 mM lithium chloride. The wash buffer was aspirated and replaced with 500 μl of assay buffer/well with or without any of the peptides studied. The experiments were terminated with 1 ml of ice-cold hydrochloric acid/methanol (0.1% v/v). After a 30-min extraction period (4°C), the samples were applied to glass columns containing 500 μl of a 1:3 (v/v) slurry of Dowex AG1-X8 anion exchange resin/distilled water to separate the various isomers. Total [3H]IP was isolated by a variation of a method described previously (Benya et al., 1994). Briefly, samples were loaded onto columns, washed with 5 ml of distilled water to remove [3H]inositol, and then washed with 2 ml of 5 mM disodium tetraborate/60 mM sodium formate solution to remove [3H]glycerophosphorylinositol. The columns were then eluted with 2 ml of 1 mM ammonium formate/100 mM formic acid solution to elute total [3H]IP. Each of the eluates was collected and mixed with 10 ml of Hydrofluor scintillation cocktail (National Diagnostics, Atlanta, GA), and the radioactivity was measured in a scintillation counter.
[Ca++]i.
Cells harvested by centrifugation (2 min, 300 × g) were resuspended in an assay buffer [24.5 mM HEPES (pH 7.4), 98 mM sodium chloride, 6 mM potassium chloride, 2.5 mM monobasic sodium phosphate, 5 mM sodium pyruvate, 5 mM sodium fumarate, 5 mM sodium glutamate, 2 mM glutamine, 11.5 mM glucose, 1.45 mM calcium chloride, 1.15 mM magnesium chloride, 0.01% soybean trypsin inhibitor, 0.2% (v/v) amino acid mixture, and 0.2% BSA (w/v)] to a concentration of 1.5 × 106cells/ml and incubated with 2.5 μM Fura-2/AM (Molecular Probes, Eugene, OR) for 30 min at 37°C followed by 15 min at 25°C. After two washes with assay buffer, 2 ml of cell suspension were placed in a Delta PTI Scan 1 spectrofluorimeter (Photon Technology International, South Brunswick, NJ) equipped with a stir bar and water bath (37°C). Fluorescence was measured at dual excitation wavelengths of 340 nm and 380 nm, using an emission wavelength of 510 nm. Autofluorescence was corrected for by running a sample of unlabeled cells in identical experimental conditions.
PLD assay.
PLD activity was determined using a modification of a method previously reported (Cook et al., 1991). NCI-N417 cells (5 × 106 cells/ml) were incubated in RPMI-1640 containing 2% FBS (v/v) for 24 hr (37°C) before the experiments. The cells were then labeled with 4 μCi/ml [3H]palmitic acid in 2% serum-supplemented media for 24 hr at 37°C. After this period, the cells were washed and preincubated in PLD buffer [serum-free RPMI-1640, 20 mM HEPES (pH 7.4), and 1% BSA (w/v)] for 30 min (37°C) and then incubated for an additional 5 min in fresh PLD buffer containing 1% (v/v) ethanol. To start the assay, the cells were incubated in fresh PLD buffer containing [dPhe6,βAla11,Phe13,Nle14]Bn(6-14), GRP or NMB at the indicated concentrations with 1% (v/v) ethanol for 30 min. The 30 min assay period was used because previously performed time-course experiments showed that this was the interval needed for measuring maximal PLD activity (data not shown). The experiments were terminated by the addition of 1.4 ml of methanol after removal of medium. After extraction with an equivalent volume of chloroform (15 min, 25°C), the samples were mixed with 585 μl of water and centrifuged (2500 × g, 5 min) to separate the phases. The organic phase was collected and dried under nitrogen gas and then was redissolved in 30 μl of chloroform/methanol (19:1, v/v). Before thin-layer chromatography (TLC) on Whatman TLC plates, PETH standard was added to each sample. Lipids were separated using a solvent system containing 2,2,4-trimethylpentane/ethyl acetate/acetic acid/water (5:12:2:10, by volume). Upon staining with iodine vapor, [3H]PETH was identified as the band co-migrating with the PETH standard. The bands were scraped into scintillation vials and mixed with Hydrofluor scintillation cocktail, and the radioactivity was measured in a scintillation counter.
Microphysiometry.
The effect of various natural and synthetic Bn-related peptides on the metabolic activity of NCI-N417 cells was examined using the Cytosensor Microphysiometer system (Molecular Devices, Sunnyvale, CA), which employs a light-addressable potentiometric sensor to detect pH changes in the extracellular fluid (McConnell et al., 1992). Briefly, NCI-N417 cells were harvested by centrifugation and resuspended to a concentration of 2 × 107 cells/ml in assay medium [bicarbonate-free DMEM (pH 7.4) supplemented with 44 mM sodium chloride and 0.1% (w/v) BSA]. The cell solution was mixed 1:1 with Agarose Cell Entrapment Medium (Molecular Devices, Sunnyvale, CA), and 10 μl aliquots of this solution were seeded into 12-mm capsule cups and placed into the Cytosensor. The assembly was equilibrated in assay medium for 1 hr at a perfusion rate of 100 μl/min. The cells were exposed to the various peptides for 4 min, and the acidification rates were determined during the last 30 sec of the peptide exposure interval. A temperature of 37°C was maintained throughout the equilibration and experimental periods.
cAMP.
NCI-N417 cells (2 × 106 cells/ml) were incubated with RPMI-1640 medium supplemented with 2% FBS (v/v) and 2 μCi/ml [3H]adenine for 24 hr at 37°C. The cells were harvested by centrifugation and resuspended into an equivalent volume of RPMI-1640 containing 1% BSA (w/v) and 0.5 mM IBMX. Then 500 μl aliquots of cell suspension were added to tubes containing the indicated agents at the indicated concentrations and incubated for 30 min at 37°C. Reactions were terminated by the addition of 100 μl of stopping solution [2% SDS (v/v), 5 mM cAMP] followed by 900 μl of ice-cold Tris (50 mM, pH 7.4). Samples were stored at −20°C until analyzed.
The amount of cAMP formation was determined using a modification of a method reported previously (Benya et al., 1994). Frozen samples of NCI-N417 cells were thawed and added to glass columns containing 1 ml of 1:1 (v/v) slurry of Dowex AG1-X8 anion exchange resin, which had previously been washed once with 4 ml of 1 N sodium hydroxide, once with 4 ml of 1 N hydrochloric acid and twice with 10 ml of deionized water. After the addition of sample, the columns were washed twice with 1 ml of deionized water and then stacked over another set of glass columns containing 1 g of alumina, which had previously been washed with 10 ml of deionized water and 4 ml of 100 mM imidazole (pH 7.2). The samples were eluted with 3 ml of deionized water onto the alumina columns. As a final elution step, 4 ml of 0.1 N imidazole was added to each alumina column. The eluate was collected and mixed with Hydrofluor scintillation fluid, and the radioactivity was counted.
[3H]-Thymidine incorporation.
The ability of hBRS-3 activation to stimulate DNA synthesis was examined using a modification of a previously described [3H]-thymidine incorporation assay (Benya et al., 1994). Briefly, 100-μl of 2 × 104 NCI-N417 cells/well in serum-free RPMI-1640 medium were plated into 96-well plates. After a 24-hr incubation at 37°C, 1 μCi/well of [methyl-3H]-thymidine was added with 100 μl of serum-free RPMI-1640 medium containing no peptide, 30 nM or 1000 nM [dPhe6,βAla11,Phe13,Nle14]Bn(6-14), or medium containing 10% FBS (v/v). After incubation for an additional 24 hr at 37°C, the radiolabeled DNA was collected on glass-fiber filters (Wallac, Gaithersburg, MD) using a cell harvester (Tomtec, Orange, CT), and the radioactivity was measured in a scintillation counter.
Cell proliferation.
The ability of hBRS-3 activation to stimulate cell proliferation was determined using the CellTiter 96 AQueous cell proliferation assay kit (Promega, Madison, WI). The method, which is a modification of the MTT assay (Carmichaelet al., 1988), employs the yellow tetrazolium dye MTS and the electron-coupling reagent phenazine ethosulfate. The MTS compound is reduced by viable cells to purple, water-soluble formazan product and is a colorimetric index of cell proliferation. NCI-N417 cells (5 × 103/well) were plated in RPMI-1640 medium containing 2% FBS (v/v) and incubated for 24 hr at 37°C. In contrast to the [3H]-thymidine assay, 2% FBS (v/v) was included in all samples because there was a significant loss in cell viability after 3 days in the absence of FBS. After addition of medium containing no peptide, 30 nM or 1000 nM [dPhe6,βAla11,Phe13, Nle14]Bn(6-14), or 10% FBS, the cells were allowed to incubate at 37°C. On the indicated days, 20 μl of MTS solution was added, and the plates were incubated in the dark for 3 hr at 37°C. The absorbance at 490 nM was obtained using a spectrophotometric plate reader (Molecular Devices Corp., Sunnyvale, CA).
Statistical analysis.
Data plotting and iterative curve fitting were performed with KaleidaGraph graphing software (Synergy Software, Reading, PA). Analysis of Schild plots and statistical analysis of the data were performed using Statview version 1.01 (BrainPower, Inc., Calabasas, CA). Student’s t test was used to determine the statistical significance of the difference between group means. P values of less than .05 were considered significant.
Results
NCI-N417 and NCI-720 cells have been reported to have detectable levels of hBRS-3 mRNA (Fathi et al., 1993). To determine whether these cell lines expressed hBRS-3 receptor or any other Bn receptor, we used RT-PCR and Southern blot analysis (fig.1). NCI-N417 cells expressed only hBRS-3 receptors, whereas NCI-H720 cells expressed both hBRS-3 and hGRP receptors. Neither cell line expressed hNMB receptors. To determine whether these receptors were functional, we examined the ability of [dPhe6,βAla11,Phe13, Nle14]Bn(6-14), GRP and NMB to stimulate an increase in [3H]IP in both cell lines (table 1). In the NCI-N417 cells, only [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) was capable of stimulating a significant release of [3H]IP at both 10 nM and 1 μM concentrations. [dPhe6]Bn(6-13) methyl ester, a GRP receptor-specific antagonist that has low affinity for BRS-3 and NMB receptors (Mantey et al., 1997) did not inhibit this increase. Neither GRP nor NMB had an agonist effect at 1 μM. In the NCI-H720 cells, both [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) and GRP stimulated an elevation of [3H]IP at 10 nM and 1 μM concentrations, and agonist activity was observed with 1 μM NMB (table 1). [dPhe6]Bn(6-13) methyl ester blocked the effect of GRP and NMB, attenuated the rise in [3H]IP seen with 10 nM [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) by 18% and had a smaller but statistically significant antagonist effect against 1 μM [dPhe6,βAla11,Phe13,Nle14] Bn(6-14) (11%). The RT-PCR and [3H]IP data suggested that the NCI-H720 cells contained hGRP receptors and that these were present in sufficient numbers to result in GRP-stimulated increases in [3H]IP, so we used only the NCI-N417 cells for assessing hBRS-3 activation in the remaining experiments, because they possessed only hBRS-3 receptors.
We examined the ability of125I-[dTyr6,βAla11,Phe13, Nle14]Bn(6-14), which binds to hBRS-3 receptors (Mantey et al., 1997), to bind to NCI-N417 cells. Binding was time- and temperature-dependent (fig. 2), reaching a maximum by 20 min at 37°C and 30 min at 22°C, and remained constant for 40 and 30 min, respectively. At both temperatures, the binding was markedly attenuated (>90%) by the addition of 1 μM [dTyr6,βAla11,Phe13,Nle14]Bn(6-14). At an incubation temperature of 4°C, saturable binding was reduced to 12% to 14% of the maximal binding seen at 37°C and 22°C. The rate of dissociation was temperature-dependent; as shown in figure3, 30% of the ligand dissociated within 10 min, and an additional 30% dissociated over the next 50 min at 37°C, but the rate of dissociation was slowed sufficiently at 4°C so that only 10% dissociated by 60 min.
[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) attenuated binding of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) in a concentration-dependent manner in the NCI-N417 cells (fig.4). Detectable inhibition was observed at 0.1 nM [dTyr6,βAla11,Phe13, Nle14]Bn(6-14), half-maximal inhibition at 7.4 nM and complete inhibition at 1 μM. Analysis of the [dTyr6,βAla11,Phe13, Nle14]Bn(6-14) inhibition curve (fig. 4, insert) demonstrated that the binding was best fitted with a single-site model, using least-squares curve-fitting analysis (LIGAND). The affinity of [dTyr6,βAla11,Phe13,Nle14]Bn(6-14) for the hBRS-3 receptor on NCI-N417 cells was 7.4 ± 1.5 nM, with a binding capacity of 1.1 ± 0.2 fmol/mg protein (68 ± 10 fmol/106 cells). The NCI-N417 cells had little or no affinity for Bn; 3 μM did not cause a significant decrease in binding of125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) (fig. 5). GRP caused detectable binding at 3 μM, and NMB at 1 μM (fig. 5), which showed that the hBRS-3 receptor had a very low affinity (>5000 nM) for each of these naturally occurring mammalian Bn peptides.
To determine whether any of the known naturally occurring Bn-related peptides interacted with native hBRS-3 receptors, we determined the affinities of 11 other natural occurring peptides of the bombesin family for the hBRS-3 receptor in NCI-N417 cells (table2). None of the 11 peptides had high affinity for the hBRS-3 receptor on NCI-N417 cells, and none had an affinity greater than 3 μM. Of the 11 evaluated, ranatensin and NMB had the highest affinity for hBRS-3 receptors, which was >3 μM for both peptides (table 2). Similar results were obtained previously in hBRS-3-transfected BALB 3T3 and NCI-H1299 cells (Ryan et al., 1997), and none of the natural peptides had high affinity for hBRS-3 receptors (table 2).
Numerous synthetic peptides, which behave as agonists or antagonists at GRP or NMB receptors, have been described (Jensen and Coy, 1991; Wanget al., 1990). Twenty-one of these compounds, which are representative of the different types of synthetic peptides described, were tested for their ability to interact with hBRS-3 in NCI-N417 or hBRS-3-transfected cells. Representative members of four classes of the Bn receptor antagonists (Jensen and Coy, 1991) had a much lower affinity (i.e., >4000 nM) for hBRS-3 receptors than reported for the hGRP or hNMB receptors, which included adPhe12-substituted analog (analog 20); two Bn pseudopeptide GRP analogs (analogs 21 and 22); twodPro13 Bn pseudopeptides (analogs 23 and 24) and eight des-Met14 amides, esters or alkylamides (analogs 26–33) (Wang et al., 1990). Two classes of Bn receptor antagonists, the d-substituted substance P analogs (analogs 35 and 36), which are broad-spectrum neuropeptide receptor antagonists, and a somatostatin octapeptide analog (analog 37), had low affinity (4–9 μM) for the hBRS-3 receptor (table 2; fig.6), which is similar to that reported for these antagonists for the hGRP or hNMB receptors. Three synthetic Bn-related agonists (analogs 16–18), with substitutions similar to [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) (analog 15), and a NMB analog (analog 19) also had low affinity for hBRS-3 receptors (table 2).
However, five peptides (litorin, phyllolitorin, rohdei-litorin, alytesin and NMB) had affinities ≤5 μM in both transfectants (table2). Five peptides (SAP-Bn, [Phe13]Bn, ranatensin,Xenopus NMB and [Leu8]phyllolitorin) had affinities >5 μM in the BALB 3T3 cells and three ([Phe13]Bn, ranatensin and Leu8]phyllolitorin) in the H1299 cells. Three peptides in the BALB 3T3 transfectants (Bn, GRP and frog GRP-10) and five in the H1299 transfectants (Bn, SAP-Bn, GRP, frog GRP-10 andXenopus NMB) had almost no affinity for hBRS-3 receptors (table 2).
To determine whether any of the naturally occurring Bn-related peptides activated hBRS-3 receptors, we examined the ability of a number of these peptides to stimulate [3H]IP release on NCI-N417 cells and hBRS-3-transfected BALB 3T3 cells (table3), because previous studies showed that transfected hBRS-3 receptors couple to phospholipase C (Ryan et al., 1998; Wu et al., 1996; Fathi et al., 1993; Mantey et al., 1997). None of the 10 naturally occurring Bn peptides that we studied, at a concentration of 1 μM, elicited a significant [3H]IP response in the NCI-N417 cells, whereas 1 μM [dPhe6,βAla11,Phe13,Nle14]Bn(6-14), a synthetic Bn analog, stimulated a 2-fold increase in total [3H]IP (table 3). At higher concentrations (i.e., >1000 nM) NMB, but not GRP, stimulated a detectable response (fig. 7). In the hBRS-3-transfected BALB 3T3 cells, five naturally occurring Bn-related peptides (Bn, GRP, NMB, SAP-Bn and frog GRP-10) did not cause an increase in [3H]IP, whereas five naturally-occurring peptides (litorin, phyllolitorin, rohdei-litorin, [Phe13]Bn and ranatensin) did (table 3).
[dPhe6,βAla11,Phe13,Nle14]Bn(6-14) and three other peptides, Ac-NMB(3-10), [dPhe6]Bn(6-13) propylamide and [dPhe6,Phe13]Bn(6-13) propylamide, which have been reported to have high affinity for transfected hBRS-3 receptors (Wu et al., 1996; Ryan et al., 1998), were also studied for their ability to activate phospholipase C (table 3). [dPhe6,βAla11, Phe13,Nle14]Bn(6-14) and two of the other peptides, Ac-NMB(3-10) and [dPhe6]Bn(6-13) propylamide, caused detectable stimulation of [3H]IP at concentrations of 1 μM in both NCI-N417 cells and hBRS-3-transfected BALB 3T3 cells (table 3). Dose-response curves for these peptides (fig. 7) demonstrated that each of these three peptides stimulated [3H]IP release in a concentration-dependent manner in the NCI-N417 cells with EC values of 25 ± 6 nM for [dPhe6,βAla11, Phe13,Nle14]Bn(6-14), 1500 ± 140 nM for Ac-NMB(3-10) and 2760 ± 900 nM for [dPhe6]Bn(6-13) propylamide (fig. 7). In contrast, [dPhe6,Phe13]Bn(6-13) propylamide had no detectable agonist activity, even up to concentrations of 10 μM (table 3; fig. 7).
One member of each of the five classes of GRP or NMB receptor antagonists was examined for intrinsic agonist activity by altering phospholipase C activity through the hBRS-3 receptor (table4, fig. 8). [dArg1,dTrp7,9,Leu11] substance P stimulated a significant increase in [3H]IP in the NCI-H417 cells and hBRS-3-transfected BALB 3T3 cells at a concentration of 100 μM but had no agonist activity at lower concentrations (data not shown). Each of the other Bn receptor antagonists, [dPhe6]Bn(6-13) methyl ester, [(3-Ph-Pr6)-His7,dAla11,dPro13,ψ(13-14),Phe14]Bn(6-14)NH2, [dPhe6,Leu13, ψ(CH2NH),Cpa14]Bn(6-14),dNal,Cys,Tyr,dTrp,Lys,Val,Cys,NalNH2and [dPro4,dTrp7,9,10]SP(4-11), at concentrations up to 100 μM, had no agonist activity (data not shown).
To determine the antagonist activities of each of the four Bn receptor antagonists that lacked agonist activity, we examined their ability to inhibit increases in [3H]IP caused by 100 nM [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) (table 4; fig. 8). The reduced peptide bond Bn analog [dPhe6,Leu13,ψ(CH2NH), Cpa14]Bn(6-14), the dPro13 Bn pseudopeptide [(3-Ph-Pr6)-His7,dAla11,dPro13,ψ(13-14),Phe14]Bn(6-14)NH2, the somatostatin octapeptide analogdNal,Cys,Tyr,dTrp,Lys,Val,Cys,NalNH2and the d-amino acid substance P(4-11) analog [dPro4,dTrp7,9,10]substance P(4-11) all significantly inhibited 100 nM [dPhe6,βAla11,Phe13,Nle14]Bn(6-14)-stimulated [3H]IP (table 4).dNal,Cys,Tyr,dTrp,Lys,Val,Cys,NalNH2, which is a NMB receptor-selective antagonist, was the most potent antagonist, causing detectable inhibition at 1 μM, half-maximal inhibition at 2 μM and 90% inhibition at 30 μM (fig. 8). [dPhe6]Bn(6-13) methyl ester was a weak inhibitor, attenuating the response by only 12% to 26% at the highest concentration tested (table 4).
Because previous studies with hBRS-3-transfected cells revealed that activation of hBRS-3 receptors caused cytosolic calcium release (Ryanet al., 1998), we evaluated the effect of [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) on calcium mobilization in the NCI-N417 cells. [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) (100 nM) stimulated a rapid rise in cytosolic calcium, which reached maximal levels in 13 sec and returning to basal levels in 1 min (fig.9, left panel). Both GRP and NMB (1 μM) failed to stimulate calcium release (fig. 9, left panel). When EGTA was added to remove extracellular calcium, the magnitude of the calcium transient was reduced by 25%, the latency to reach peak levels was increased and the return to basal levels was faster than that seen with cells in calcium-containing buffer (fig. 9, right panel). Both the magnitude of released calcium and the time to reach the peak of the transient were concentration-dependent (fig.10, left panel). [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) caused a detectable response at 1 nM and a maximal 3.6-fold increase at 1 μM. Analysis of the dose-response data by nonlinear, iterative curve fitting (fig. 10, right panel) revealed an EC50 of 14 ± 7.1 nM.
To determine whether hBRS-3 receptor activation affected the metabolic state of NCI-N417 cells, we examined the ability of GRP, NMB and [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) to stimulate extracellular acidification (fig.11). [dPhe6,βAla11, Phe13,Nle14]Bn(6-14) stimulated a 11 ± 0.8% increase in the acidification rate, which returned to basal levels in 6 to 8 min. The cells could be repeatedly stimulated, and the magnitude of the response from successive, equivalent doses of [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) was not significantly different from the initial treatment (data not shown). Neither GRP nor NMB was able to elicit acidification, and the GRP receptor antagonist [dPhe6]Bn(6-13) methyl ester was ineffective at attenuating the stimulation of acidification by [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) (fig. 11). When examined in more detail, the response seen with the synthetic peptide [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) was shown to be concentration-dependent, having an EC50 of 4.3 ± 1.6 nM (fig. 12).
Because the hBRS-3 structurally related receptors, the mammalian GRP and the NMB receptor, have been shown to couple to phospholipase D and promote diacylglycerol formation (Pettitt and Wakelam, 1993; Houet al., 1997), we examined the effect of NMB, GRP and [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) on phospholipase D activity in NCI-N417 cells using the transphosphatidylation assay. Neuromedin B and GRP, at a concentration of 100 nM, did not cause a significant increase in phospholipase D activity (fig. 13). However, [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) stimulated a significant increase in phospholipase D activity in NCI-N417 cells at 10 nM and 100 nM; increases of 105 ± 36% and 157 ± 47%, respectively, were observed.
Because it had previously been shown that natively expressed GRP receptors in Swiss 3T3 fibroblasts could stimulate cAMP release upon receptor activation (Millar and Rozengurt, 1988), we studied the ability of [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) and various agonists known to activate adenylate cyclase via receptor activation. As shown in table 5, no stimulatory effect was observed with [dPhe6,βAla11,Phe13, Nle14]Bn(6-14), vasopressin or epinephrine. Only two agents, PACAP-27 and PACAP-38, were capable of stimulating a significant increase in cAMP similar to that seen with forskolin, a direct activator of adenylate cyclase (table 5).
To determine whether hBRS-3 receptor activation resulted in DNA synthesis and proliferation, we examined the ability of [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) to stimulate an increase in [methyl-3H]-thymidine incorporation and/or an increase in cell number in the NCI-N417 cells. We found that 10% FBS stimulated a 3.5-fold increase in [methyl-3H]-thymidine incorporation (fig.14, left panel). The incorporation observed in the presence of [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) at either concentration was not significantly greater than that in unstimulated cells (fig. 14, left panel). The growth kinetic profile of NCI-N417 cells was examined using the MTS assay. The cells displayed a 24-hr lag phase followed by 48 hr of logarithmic growth, which was followed by steady-state growth (fig. 14, right panel). With 10% FBS at 1, 3 and 5 days after plating, the detected absorbance was significantly greater than the untreated control. [dPhe6,βAla11, Phe13,Nle14]Bn(6-14), at concentrations of 30 nM and 1000 nM, did not significantly increase the detected absorbance compared with that in the untreated cells (fig.14, right panel).
Discussion
Having an unknown ligand, BRS-3 remains an orphan receptor, and little is known about its putative signaling mechanisms or physiological roles. Recent studies have used various hBRS-3-transfected cell lines (Wu et al., 1996; Manteyet al., 1997; Ryan et al., 1998) to screen for naturally occurring and synthetic substances to provide insight into the pharmacology and possible signal transduction mechanisms associated with this receptor. However, the assumption that the results of such transfection studies represent the behavior of the native receptor is not always valid. In a study wherein the murine GRP receptor was transfected into BALB 3T3 cells (Benya et al., 1994), GRP caused no increase in cAMP, whereas it increased cAMP in untransfected murine Swiss 3T3 cells (Millar and Rozengurt, 1988), which natively possess GRP receptors and are the cells from which the murine GRP receptor was originally cloned. Furthermore, the Bn analog [dPhe6]Bn(6-13) ethylamide was shown to antagonize Bn- and NMB-stimulated calcium mobilization in NCI-H345 cells (Ryan et al., 1993), which natively express hGRP and hNMB receptors, and this Bn analog was devoid of intrinsic agonist activity. However, subsequent studies using hGRP and hNMB receptor-transfected BALB 3T3 cells indicated that [dPhe6]Bn(6-13) ethylamide behaved as a partial agonist at both receptors (Wu et al., 1995; Ryanet al., 1996). These results demonstrate that with other closely related members of the Bn receptor family, results with transfected receptors may differ from those with cells that natively express the receptor.
Similarly, several studies with various cell lines transfected with other G protein-coupled receptors have revealed that these transfectants may differ in either affinity for ligands or intracellular coupling when compared with cells that natively express the receptors. For example, when the tachykinin receptor subtypes NK1, NK2 and NK3 were transfected in Chinese hampster ovary (CHO) cells, the binding affinities of agonists to both NK1 and NK2, but not NK3, were similar to those seen with native receptors. In contrast, when expressed in COS cells, only the NK3-transfected cells showed similar affinities for agonists compared with native cells, which demonstrates that the cell type used for expression could have a marked effect on receptor affinity (Gether et al., 1992). Additional studies have demonstrated that natively expressed receptors that couple to a single effector pathway can couple to multiple signaling pathways when transfected into cells, particularly if the level of receptor expression is higher than that seen in native cells (Akbar et al., 1994; Zhu et al., 1994). In cells transfected with human luteinizing hormone receptors (Zhu et al., 1994) or somatostatin receptors (Akbar et al., 1994), which are coupled to the stimulation or inhibition of adenylyl cyclase in native cells, respectively, phospholipase C was stimulated in the presence of these peptides in transfected cells. Therefore, although studies of transfected BRS-3 receptors have provided important preliminary information about this orphan receptor, a cell line natively expressing endogenous hBRS-3 would be a significant advance for studying hBRS-3 receptor pharmacology and function. However, most cells that contain native hBRS-3 receptors express very low levels of hBRS-3 mRNA, and no hBRS-3 receptor-containing cell line has been found to possess adequate numbers of the receptor for investigations into the pharmacology or biology of hBRS-3. Furthermore, no high-affinity ligand has been available to screen various cells for hBRS-3 receptors.
We had recently discovered a high-affinity ligand, [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) (Mantey et al., 1997), that functioned as a hBRS-3 receptor agonist in small cell lung cancer cells and BALB 3T3 cells stably transfected with hBRS-3 receptors (Ryan et al., 1998). We used this ligand, its radiolabeled analog125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14), RT-PCR and Southern blot analysis in the present study to attempt to identify a cell line that possessed sufficient native hBRS-3 receptors to be useful for studying its pharmacology or cell biology. We screened various human small and non-small lung cancer cells for hBRS-3 receptors, because previous studies had shown that some human small cell and non-small cell lung cancer cells possess hBRS-3 mRNA (Fathiet al., 1993). We found that two cell lines, the small cell lung cancer cell line NCI-N417 and the carcinoid lung cancer cell line NCI-H720, possessed sufficient numbers of hBRS-3 receptors for binding and functional studies to be carried out on endogenous hBRS-3 receptors. A number of results in the present study demonstrate that the NCI-N417 cell line will be particularly useful for studying hBRS-3 receptor binding and cell biology. First, in contrast to the NCI-H720 cells, we found that the NCI-N417 cells expressed only hBRS-3 receptors and none of the other bombesin receptor subtypes. In a previous study (Fathi et al., 1993), NCI-N417 cells have been reported to contain hGRP or hNMB receptor mRNA as detected by RT-PCR or RNAase protection assays. However, we detected no expression of any other mammalian Bn receptors using RT-PCR in the NCI-N417 cells. Furthermore, neither GRP nor NMB, which are hGRP and hNMB receptor agonists, respectively, caused changes in phospholipase C activity in these cells, whereas the hBRS-3 receptor agonists caused activation of phospholipase C. Second, the ligand125I-[dTyr6,βAla11,Phe13,Nle14]Bn(6-14) bound to NCI-N417 cells with high affinity, and the receptor number was sufficient for detailed investigation of ligand-hBRS-3 receptor interaction. Third, the level of hBRS-3 receptor expression on the NCI-N417 cells altered cellular function enough to permit detailed studies of the intracellular coupling associated with hBRS-3 receptor activation, including the mobilization of intracellular calcium, the stimulation of phospholipase D activity and cellular metabolism.
When the pharmacology of the native hBRS-3 receptor on NCI-N417 cells was compared to transfected hBRS-3 receptors on BALB 3T3 or NCI-H1299 cells, we found several close similarities. A recent study (Manteyet al., 1997) using hBRS-3-transfected cells proposed that either the putative ligand for this receptor is not a Bn-like peptide or it has an amino acid sequence that is completely different from those of the known Bn-like peptides. In the present study, we found that none of the 14 naturally occurring Bn-related peptides tested had high affinity or potent agonist activity for native hBRS-3 receptors on NCI-N417 cells. In addition, several synthetic bombesin peptides, which were reported to be hBRS-3 receptor agonists in hBRS-3 transfectants (Wu et al., 1996; Ryan et al., 1998) had agonist activity in the NCI-N417 cells. Furthermore, except for [dPhe6,βAla11,Phe13,Nle14]Bn(6-14), none of the synthetic Bn receptor agonists tested had high affinity for hBRS-3. Several classes of GRP and neuromedin B receptor antagonists have been described, and in a previous study using cells stably transfected with hBRS-3 (Ryan et al., 1998), representative members of each of these receptor classes were also found to have low affinity (>5 μM), which is similar to our results on native hBRS-3 receptors in NCI-N417 cells. Furthermore, in a recent study we found three classes of peptides that could function as hBRS-3 receptor antagonists (Ryan et al., 1998). In the present study, these synthetic peptide antagonists had moderate affinity (<5 μM) for native hBRS-3 receptors.
There were, however, some differences between the results from this study and those reported by others using cell lines transfected with hBRS-3 receptors. A recent paper (Wu et al., 1996) described three synthetic peptides, Ac-NMB(3-10), [dPhe6]Bn(6-13) propylamide and [dPhe6,Phe13]Bn(6-13) propylamide, that were capable of stimulating calcium mobilization in hBRS-3-transfected BALB 3T3 cells with high affinity. In this study, both Ac-NMB(3-10) and [dPhe6]Bn(6-13) propylamide could activate phospholipase C in the NCI-N417 cells, but their potencies were 7- and 30-fold less, respectively, than those observed in hBRS-3-transfected BALB 3T3 cells (Wu et al., 1996). Furthermore, [dPhe6, Phe13]Bn(6-13) propylamide was reported as the most potent agonist in this study (Wuet al., 1996). However, in another study (Ryan et al., 1998) this synthetic peptide was reported to have little agonist activity in either NCI-N417 cells or hBRS-3-transfected cells, even at high concentrations. Our results in the present study agree with the latter study in hBRS-3-transfected cells (Ryan et al., 1998), because we found that in cells containing native hBRS-3 receptors, [dPhe6,Phe13]Bn(6-13) propylamide had no agonist activity, even at concentrations up to 10 μM. We also found some differences between the results seen with our hBRS-3 BALB 3T3 transfectants reported in a previous study (Ryan et al., 1998) and those with the NCI-N417 cells in the present study. First, in general, agonists had greater efficacy in hBRS-3-transfected cells than in NCI-N417 cells. Specifically, [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) caused a greater-fold increase of [3H]IP in hBRS-3 receptor-transfected cells than in NCI-N417 cells (3.6- vs.2.4-fold, respectively). Similarly, at a concentration of 1 μM, Ac-NMB(3-10) and [dPhe6]Bn(6-13) propylamide had greater efficacy in the hBRS-3 receptor-transfected cells (table3). Second, in hBRS-3 receptor-transfected cells (Ryan et al., 1998), we found that [dPhe6,Phe13]Bn(6-13) propylamide had agonist activity at high concentrations (>5 μM), whereas in the present study it had no agonist activity in NCI-N417 cells. Finally, three natural peptides (litorin, phyllolitorin and rohdei-litorin) had higher affinities for hBRS-3 receptor-transfected cells than for the other naturally occurring Bn-related peptides, which suggests that the unknown natural occurring ligand might be structurally more similar to these peptides. In NCI-N417 cells, however, these peptides had very low affinities for the hBRS-3 receptor.
In a previous study (Mantey et al., 1997), we proposed, on the basis of limited structure-function data, that the βAla11 primarily and, to a lesser extent, the Phe13 of [dPhe6,βAla11, Phe13,Nle14]Bn(6-14) were the important changes in the structure of Bn that were responsible for the development of high affinity for transfected hBRS-3 receptors. The data in the present study with the native hBRS-3 receptor support the central importance of the βAla11 replacement as a determinant of affinity, because other [dPhe6]Bn(6-14) or Bn analogs with norleucine as the COOH terminal amino acid did not have high affinity. The results in the present study suggest that the insertion of Phe13into Bn or an equivalent position of a related peptide did not significantly increase affinity for the hBRS-3 receptor. This interpretation is supported by the fact that neither [Phe13]Bn nor any of the naturally occurring Bn-related peptides with a penultimate Phe (NMB, litorin, phyllolitorin, rohdei-litorin, Xenopus NMB or ranatensin) had an affinity >10 μM. Therefore, the results in the present study do not imply that the natural ligand for the BRS-3 receptor resembles any existing Bn peptide.
Although the reasons for these differences between the characteristics of the hBRS-3 receptor when studied in the native NCI-N417 cells and the hBRS-3 transfectants are not clear, it is possible that the receptor number in hBRS-3-transfected cells [7- and 40-fold greater in hBRS-3-transfected NCI-H1299 and BALB 3T3 cells, respectively (Manteyet al., 1997)] or a larger receptor spareness exists in the stably transfected cell lines, so that minimal receptor occupation resulted in greater [3H]IP responses. A recent study (Tsuda et al., 1997b) demonstrates that for the GRP receptor, which couples to phospholipase C, receptor number can have a marked effect on phospholipase C activation and other receptor-mediated processes. In addition, potential differences in receptor-effector coupling efficiency, post-translational processing of hBRS-3 and possible disparities in the intracellular signaling milieu between the NCI-N417 cells and hBRS-3-transfected cell lines could contribute to the observed discrepancies.
In an outcome consistent with previous studies of hBRS-3 receptor-transfected cells (Fathi et al., 1993; Wu et al., 1996), a number of our results confirm that like structurally related mammalian Bn receptors (Kroog et al., 1995), the natively expressed hBRS-3 receptor couples to phospholipase C and phospholipase D, resulting in generation of phosphoinositides and changes in both cellular calcium and phosphatidic acid. First, we found that phospholipase C activation ensued upon hBRS-3 receptor activation because [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) stimulated an increase in total phosphoinositides in NCI-N417 cells. Second, native hBRS-3 receptor activation resulted in an increase in cytosolic calcium. Third, this increase in cytosolic calcium was diminished only 40% in calcium-free medium. These results, taken together with the fact that in a recent study [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) stimulated [3H]IP release and calcium mobilization in hBRS-3-transfected cells (Ryan et al., 1998), suggest that the initial release of intracellular calcium is from an inositol (1,4,5) trisphosphate-sensitive calcium pool with subsequent capacitive calcium entry, a mechanism previously described for hGRP and hNMB receptors (Ryan et al., 1993; Ryan et al., 1996). That the hBRS-3 couples to phospholipase D was shown by the ability of [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) to stimulate [3H]PETH release in NCI-N417 cells.
Elevation of cAMP has been associated with activation of GRP receptors in some cells (Millar and Rozengurt, 1988), but not with activation of NMB receptors (Benya et al., 1992). In the present study, activation of hBRS-3 receptors in NCI-N417 cells did not result in elevation of cAMP. Because PACAP-27 and PACAP-38 were capable of stimulating an increase in cAMP, it is unlikely that the NCI-N417 cells possessed inadequate GS. Therefore, the failure of hBRS-3 receptors to mediate adenylate cyclase activity cannot be explained on the basis of insufficient availability of G protein. Furthermore, forskolin stimulated a significant cAMP response, which shows that adenylate cyclase could be directly activated in these cells. These results support the conclusion that hBRS-3 receptor activation is not coupled to activation of adenylate cyclase.
It has been demonstrated that activation of GRP (Tache et al., 1988) or NMB receptors (Markowska et al., 1993;Lach et al., 1995) leads to mitogenesis. In addition, studies have shown that activation of GRP or NMB receptors in small cell lung carcinoma cell (SCLC) lines can stimulate clonal growthin vitro (Cuttitta et al., 1985). Because hBRS-3 has been detected in both SCLC and non-small cell lung carcinoma cell (NSCLC) lines (Fathi et al., 1993), we examined the ability of activated hBRS-3 receptors to stimulate DNA synthesis and proliferation in the NCI-N417 SCLC cells. The results from this study demonstrate that BRS-3 receptor activation does not mediate mitogenesis in NCI-N417 cells, because the BRS-3 agonist [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) failed to stimulate a significant increase in DNA synthesis or elicit proliferation in vitro. However, Hutu-80 human duodenal tumor cells (Williams and Schonbrunn, 1994) and A375-6 human melanoma tumor cells (Pansky et al., 1997) have been shown to contain functional receptors for GRP, yet activation of these GRP receptors was insufficient to stimulate mitogenesis, whereas GRP receptor activation in other cells did stimulate mitogenesis (Cuttitta et al., 1985; Tache et al., 1988). Therefore, the proliferative response mediated by Bn receptor subtypes may be tissue-specific, which necessitates further identification and study of cells that native expressing hBRS-3 before we draw definitive conclusions regarding a potential role of hBRS-3 in cellular proliferation.
In previous studies using hBRS-3-transfected cells (Ryan et al., 1998; Mantey et al., 1997), it was determined that most of the classes of high-affinity GRP or NMB receptor antagonists had very low affinity for the hBRS-3 receptor, which included representative members of the GRP and bombesin pseudopeptides, [des-Met14]Bn or [des-Met27]GRP esters, alkylamides or hydrazides and [dPro13]Bn pseudopeptide analogs. However, in one study using hBRS-3-transfected cells (Ryan et al., 1998), three classes of GRP or NMB receptor antagonists, including various d-amino acid substituted substance P analogs, the synthetic somatostatin octapeptide analogdNal,Cys,Tyr,dTrp,Lys,Val,Cys,NalNH2and two Bn pseudopeptide analogs (table 4), were able to function as hBRS-3 receptor antagonists. In the present study, similar results were obtained with the native hBRS-3 receptor in NCI-N417 cells. For both NCI-N417 cells and hBRS-3 receptor-transfected NCI-H1299 cells,dNal,Cys,Tyr,dTrp,Lys, Val,Cys,NalNH2 was the most potent antagonist, having an affinity of 2 μM. Comparing these results with those of a previous study on other Bn receptors shows that dNal, Cys,Tyr,dTrp,Lys,Val,Cys,NalNH2 has the highest affinity for NMB receptors, a 5- to 10-fold lower affinity for hBRS-3 receptors and almost no affinity for GRP receptors. In the future, modification of this somatostatin analog might yield selective hBRS-3 antagonists.
The present study demonstrates that the relationship between hBRS-3 receptor occupation and intracellular coupling may differ significantly from that seen with the mammalian Bn receptors GRP-R and NMB-R. In the present study, the dose-response curve of the agonist [dPhe6,βAla11,Phe13, Nle14]Bn(6-14) for hBRS-3 receptor occupation and its dose-response curve for mobilization of cytosolic calcium were superimposable. In contrast, the dose-response curve for mobilization of cellular calcium for GRP receptors and NMB receptors is at least 10-fold to the left of that for receptor occupation (Sinnett-Smith et al., 1993; Tsudaet al., 1997a). These results demonstrate that unlike the GRP and NMB receptors, where submaximal receptor occupation results in maximal mobilization of cellular calcium, there is no receptor spareness with the hBRS-3 receptor, and receptor occupation and mobilization of calcium are more closely coupled.
Finally, we evaluated the utility of a new bioassay, cytosensor microphysiometry (McConnell et al., 1992), for investigating the pharmacology of hBRS-3 in NCI-N417 cells. This method involves measuring the rate of extracellular acidification in response to an agonist, which is a consequence of changes in cellular metabolism. Although the mechanisms mediating the response are complex and are not well understood, the response has been shown to be reproducible for a variety of agonists and has been used recently to study NMB receptor-transfected CHO cells (Pinnock et al., 1995), as well as other peptide hormone receptors (Taylor et al., 1996). However, it is not clear whether the assay sensitivity is comparable to conventional measurements of intracellular mediators such as phosphoinositides in cells that contain hBRS-3 receptors. To address this issue, we determined the ability of [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) and other mammalian Bn-like peptide receptor agonists and antagonists to effect detectable metabolic changes with the cytosensor using the NCI-N417 cells. A number of our results support the conclusion that the changes detected with the cytosensor closely reflect those seen with more standard measures of cell activation, such as changes in cytosolic calcium or phosphoinositide metabolism. First, [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) caused detectable changes in acidification over the same concentration ranges over which it caused increases in phosphoinositides, mobilization of calcium and receptor occupation. Second, in a result similar to the increases in [3H]IP, acidification caused by [dPhe6,βAla11,Phe13,Nle14]Bn(6-14) was insensitive to the GRP receptor antagonist [dPhe6]Bn(6-13) methyl ester. Finally, none of the other mammalian Bn peptides that interact with high affinity at other Bn receptors, but not at the hBRS-3 receptor, was capable of invoking a significant acidification response. Therefore, our results suggest that microphysiometry could prove useful for future studies of hBRS-3 receptor pharmacology, particularly in studies attempting to identify selective hBRS-3 receptor agonists or antagonists.
In conclusion, we report for the first time that two lung cancer cell lines, NCI-N417 and NCI-H720, possess sufficient numbers of hBRS-3 receptors to make possible studies of binding and intracellular signaling pathways. By studying the NCI-N417 cells, which contain only hBRS-3, we report for the first time that native hBRS-3 receptors are coupled to phospholipases C and D and that activation of phospholipase C stimulates mobilization of cellular calcium. The pharmacology of native hBRS-3 receptors is in most respects similar to that reported in studies of transfected hBRS-3 receptors (Mantey et al., 1997). However, it differs from one recent study (Wu et al., 1996) in that the native hBRS-3 receptor had very low affinity for [dPhe6,Phe13]Bn(6-13) propylamide. Pharmacological results show that the putative ligand for the native hBRS-3 receptor is none of the recognized naturally occurring Bn-related peptides. Three classes of low-affinity GRP or NMB receptor antagonists were found to function as antagonists on cells that natively express hBRS-3. The discovery of cell lines that express functional, endogenous hBRS-3 receptors, the availability of the agonist [dPhe6, βAla11,Phe13,Nle14]Bn(6-14) and the validity of microphysiometry as an additional assay for examining hBRS-3 receptor pharmacology represent important tools that can be used for identification of the native ligand, for further studies of cellular coupling, for the development of selective agonists and antagonists and for studies of the role of the hBRS-3 receptor in normal physiology and various disease states.
Footnotes
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Send reprint requests to: Dr. Robert T. Jensen, NIH/NIDDK/DDB, Bldg. 10, Rm. 9C-103, 10 Center Dr. MSC 1804 Bethesda, MD 20892-1804.
- Abbreviations:
- AM
- acetoxymethyl ester
- 3-Ph-Pr
- 3-phenylpropanolamine
- Bn
- bombesin
- BRS-3
- bombesin receptor subtype 3
- BSA
- bovine serum albumin
- Cpa
- chlorophenylalanine
- DMEM
- Dulbecco’s minimum essential medium
- dNal
- β-napthyl-d-alanine
- EGTA
- ethylene glycol-bis(β-aminoethyl ether) N,N,N′,N′-tetraacetic acid
- FBS
- fetal bovine serum
- GRP
- gastrin-releasing peptide
- IBMX
- 3-isobutyl-1-methylxanthine
- IP
- inositol phosphate
- Me
- methyl
- MTS
- [3-(4,5-dimethylthiazol-2-yl)-5-(3-carboxymethoxyphenyl)-2-(4-sulophenyl)-2H-tetrazolium, inner salt]
- Nle
- norleucine
- NMB
- neuromedin B
- PACAP
- pituitary adenylate cyclase-activating peptide
- PBS
- Dulbecco’s phosphate-buffered saline
- PETH
- phosphatidylethanolamine
- SAP-Bn
- [Ser3,Arg10,Phe13]-bombesin
- TFA
- trifluoroacetic acid
- ψ(13-14)
- a pseudopeptide bond in the 13-14 position of Bn
- [Ca2+]i
- intracellular calcium
- frog GRP-10
- frog gastrin-releasing peptide COOH terminal decapeptide = [Ser19]GRP(18-27)
- XenopusNMB
- [Gln3,Ile6]neuromedin B
- RT-PRC
- reverse transcription-polymerase chain reaction(s)
- PLD
- phospholipase D
- Received December 9, 1997.
- Accepted April 14, 1998.
- The American Society for Pharmacology and Experimental Therapeutics