An orphan receptor discovered in 1993 was called bombesin receptor subtype 3 (BRS-3) because of 47-51% amino acid identity with bombesin (Bn) receptors. Its pharmacology is unknown, because no naturally occurring tissues have sufficient receptors to allow studies. ]Bn-(6 -14) bound to both cell lines with high affinity. Neither Bn nor 14 other naturally occurring Bn peptides bound to hBRS-3 with a K d <1000 nM. Twenty-six synthetic peptides that are high affinity agonists or antagonists at other bombesin receptors had an affinity >1000 nM. Guanosine 5-(,␥-imido)triphosphate inhibited binding to both cells due to a change in receptor affinity. These results demonstrate hBRS-3 has a unique pharmacology. It does not interact with high affinity with any known natural agonist or high affinity antagonist of the Bn receptor family, suggesting the natural ligand is either an undiscovered member of the Bn peptide family or an unrelated peptide. The availability of these cell lines and the hBRS-3 ligand should facilitate identification of the natural ligand for BRS-3, its pharmacology, and cell biology. We made two cell lines stably expressing the human BRS-3 (hBRS-3). hBRS-3 was overexpressed in the huRecently, an orphan receptor that is a member of the heptahelical superfamily of receptors was described in both human small cell lung cancer cells (1) and guinea pig uterus (2). Because this orphan receptor had a high degree of homology to mammalian bombesin receptors (i.e. 51-52% for the gastrinreleasing peptide receptor (GRP-R) 1 and 47% for the neuromedin B receptor (NMB-R) (1, 2)), it was named the BRS-3 for bombesin receptor subtype-3 in one study (1). Studies of the distribution of the receptor mRNA show that BRS-3 has a pattern of expression limited to rat secondary spermatocytes (1), guinea pig brain and pregnant uterus (2), and some tumor cell lines (various human small cell and non-small cell lung cancer cell lines (1), the human ductal breast cancer cell line T47D (3), and the human epidermal cancer cell line A431 (3)). However, the natural ligand that interacts with the BRS-3 is unknown, and its pharmacology is largely unknown because of the lack of a radioligand. In addition, little is known about the cellular basis of action of BRS-3 except that it is coupled to phospholipase C when expressed in Xenopus oocytes (1) or when transfected into Balb 3T3 cells (4). The ability to elucidate the pharmacology of the BRS-3 is not only limited by the lack of a radioligand but also by the lack of a cell containing native BRS-3 receptors in sufficient numbers to allow binding studies to identify a possible radioligand.To deal with this latter issue, in the present study we have used two different strategies to produce cell lines stably expressing the human BRS-3 (hBRS-3) receptor whose pharmacology and coupling will probably closely resemble that of the native hBRS-3. Furthermore, we have discovered a unique ligand that is a synthetic analogue of bombesin-(6 -14), which interacts with high affinity with the hBRS-3. With ...
Bombesin (Bn) receptor subtype 3 (BRS-3) is an orphan receptor that is a predicted member of the heptahelical G-protein receptor family and so named because it shares a 50% amino acid homology with receptors for the mammalian bombesin-like peptides neuromedin B (NMB) and gastrin-releasing peptide. In a recent targeted disruption study, in which BRS-3-deficient mice were generated, the mice developed obesity, diabetes, and hypertension. To date, BRS-3's natural ligand remains unknown, its pharmacology unclear, and cellular basis of action undetermined. Furthermore, there are few tissues or cell lines found that express sufficient levels of BRS-3 protein for study. The mammalian bombesin (Bn) 1 -like peptides gastrin-releasing peptide (GRP) and neuromedin B (NMB) contribute to diverse biological functions in the central nervous system (1, 2) and peripheral tissues (1, 2), which include thermoregulation (3), satiety (4), control of circadian rhythm (5), stimulation of pancreatic secretion (6), stimulation of gastrointestinal hormone release (7-9), and macrophage activation (10). These peptides also have important developmental effects (11,12) and potent growth effects (13-15), causing proliferation of normal cells (13,14,16,17) and various tumor cell lines (15, 16, 18 -20). To date, two mammalian receptor subtypes and their ligands have been identified, each of which has an architecture suggesting they are members of the heptahelical G-protein coupled receptor superfamily (21-23). One subtype, the GRP receptor, exhibits selectivity for GRP (21, 22, 24 -26), whereas the other, the NMB receptor, has selectivity for NMB (23,26,27). The intracellular signaling pathways of these two receptors have been characterized, with ligand binding resulting in stimulation of phospholipase C (14, 28 -30), protein kinase C activation (14), [Ca 2ϩ ] i mobilization (14,29,30), and tyrosine phosphorylation of various intracellular proteins (31-34).Recently, it has been proposed that an orphan receptor may represent a third type of mammalian bombesin receptor (35,36). This 399-amino acid protein, which was later identified in human tissues (35), was named bombesin receptor subtype-3 (BRS-3), due to its 51% and 47% amino acid sequence homology
Recently, a fourth member of the bombesin (Bn) receptor family (fBB4-R) was isolated from a cDNA library from the brain of the frog, Bombina orientalis. Its pharmacology and cell biology are largely unknown, and no known natural cell lines or tissues possess sufficient numbers of fBB4-R's to allow either of these to be determined. To address these issues, we have used three different strategies. fBB4-R expression in cells widely used for other Bn receptor subtypes was unsuccessful as was expression in two frog cell lines. However, stable fBB4-R cell lines were obtained in CHO-K1 cells which were shown to faithfully demonstrate the correct pharmacology of the related Bn receptor, the GRP receptor, when expressed in these cells. [DPhe6,betaAla11,Phe13,Nle14]Bn(6-14) was found to have high affinity (Ki = 0.4 nM) for the fBB4 receptor and 125I-[DTyr6,betaala11,Phe13,Nle14]Bn(6-14) to be an excellent ligand for this receptor. The fBB4-R had a unique pharmacology for naturally occurring Bn-related agonists, with the presence of a penultimate phenylalanine being critical for high-affinity interaction. It also had a unique profile for six classes of Bn antagonists. The fBB4-R was coupled to phospholipase C with activation increasing [3H]inositol phosphates and mobilizing Ca2+ almost entirely from cellular sources. There was a close correlation between agonist the receptor occupation and the receptor activation. Three of the five classes of Bn receptor antagonists that interacted with higher affinity with the fBB4-R functioned as fBB4-R antagonists and two as partial agonists. fBB4-R activation stimulated increases in phospholipase D (PLD) over the same range of concentrations at which it activated phospholipase C. These results demonstrate that the fBB4 receptor has a unique pharmacology for agonists and antagonists and is coupled to phospholipase C and D. The availability of these cell lines, this novel ligand, and the identification of three classes of antagonists that can be used as lead compounds should facilitate the further investigation of the pharmacology and cell biology of the BB4 receptor.
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