cDNA cloning, characterization, and brain region-specific expression of a neuromedin-B-preferring bombesin receptor.

Recent binding studies in the central nervous system and other tissues provide evidence that the mammalian bombesin-like peptides, gastrin-releasing peptide (GRP) and neuromedin-B (NMB), exert their numerous physiological effects through at least two different receptors. We describe the structure and expression of a cloned NMB-preferring bombesin receptor (NMB-R) with properties distinct from a GRP-preferring bombesin receptor (GRP-R) reported previously. In particular, the NMB-R shows higher affinity binding to NMB than to GRP in BALB 3T3 fibroblasts expressing the cloned NMB-R. The distinct regional distribution of NMB-R and GRP-R mRNA in the brain suggests that both bombesin receptor subtypes play independent roles in mediating many of the dramatic effects of bombesin-like peptides in the central nervous system.     

Distinguishing bombesin receptor subtypes using the oocyte assay.

Physiological responses to mammalian bombesin-like peptides were studied in Xenopus oocytes injected with mRNA isolated from Swiss 3T3 cells and rat esophagus in order to identify and characterize bombesin receptor subtypes. Both groups respond similarly to either gastrin releasing peptide or neuromedin B, but only the response to neuromedin B in oocytes expressing the esophagus mRNA is not blocked by a specific gastrin releasing peptide receptor antagonist, des-Met-[D-Phe6]Bn(6-13) ethyl ester. Complete desensitization of gastrin releasing peptide-evoked responses in oocytes expressing esophagus mRNA does not abolish neuromedin B-evoked responses. A single application of neuromedin B abolishes responses to subsequently applied gastrin releasing peptide in oocytes expressing esophagus, but not Swiss 3T3, mRNA. RNA blot hybridization studies using a Swiss 3T3 gastrin releasing peptide receptor cDNA probe show no detectable hybridization in esophagus mRNA samples. These data suggest that a gastrin releasing peptide receptor is expressed in the esophagus and that it is distinct from that expressed in Swiss 3T3 cells and may represent a third subtype of mammalian bombesin receptor.     

Expression and electrophysiological identification of the receptor for bombesin and gastrin-releasing peptide in Xenopus laevis oocytes injected with polyA+ RNA from rat brain

The receptor for bombesin and the related peptide, gastrin-releasing peptide (GRP) has been induced in frog oocytes by injection of polyA+ RNA from rat brain. The primed oocytes responded to peptides of the bombesin family (GRP, neuromedin C of bombesin) by showing dose-dependent oscillations in membrane currents as recorded by the voltage-clamp method. The induced membrane changes were suppressed when oocytes were pretreated with a bombesin-receptor antagonist.     

Two distinct bombesin receptor subtypes are expressed and functional in human lung carcinoma cells.

Bombesin-like peptides have been implicated as autocrine growth factors influencing the pathogenesis and progression of some human lung carcinoma cells. To determine the pharmacologic and structural properties of the bombesin receptors expressed in human lung carcinoma cells, cDNA clones encoding a human gastrin-releasing peptide receptor (GRP-R) and a pharmacologically distinct neuromedin-B preferring bombesin-receptor (NMB-R) were isolated from a human small cell lung carcinoma cell line (NCI-H345). After expression in Xenopus oocytes, a GRP-R-specific antagonist was effective in blocking responses elicited from the cloned GRP-R, but not the NMB-R. Both GRP-R and NMB-R mRNA expression was detected at varying levels in a panel of human lung cancer cell lines. These results indicate heterogeneity of bombesin receptor subtypes exists in human lung carcinoma cells and should be considered in the design of bombesin receptor antagonists intended to inhibit tumor cell growth.     

Neuromedin B-like peptides in rat brain: biochemical characterization, mechanism of release and localization in synaptosomes

Neuromedin B-like peptides were characterized in the rat brain. A rabbit antisera was utilized which recognized neuromedin B but not bombesin or GRP. Using gel filtration and HPLC techniques, a major and minor peak of immunoreactivity was present in rat brain extracts. In both cases the main peak of immunoreactivity coeluted with synthetic neuromedin B. The density of neuromedin B-like peptides ranged 50-fold being greatest in the olfactory bulb and hypothalamus, intermediate in the hippocampus, spinal cord, medulla/pons, pituitary, midbrain, thalamus, striatum and cortex and lowest in the cerebellum. Release studies indicated that neuromedin B-like peptides were secreted from hypothalamic, olfactory bulb and thalamic slices in a Ca++-dependent manner when KCl (75 mM) was present. Also, the neuromedin B-like peptides in the rat brain were localized to synaptosomes. These data indicate that neuromedin B-like peptides may function as regulatory peptides in the CNS distinct from bombesin/GRP.     

Identification of a novel neuromedin U receptor subtype expressed in the central nervous system

Neuromedin U is a neuropeptide prominently expressed in the upper gastrointestinal tract and central nervous system. Recently, GPR66/FM-3 (NmU-R1) was identified as a specific receptor for neuromedin U. A BLAST search of the GenBank(TM) genomic database using the NmU-R1 cDNA sequence revealed a human genomic fragment encoding a G protein-coupled receptor that we designated NmU-R2 based on its homology to NmU-R1. The full-length NmU-R2 cDNA was subsequently cloned, stably expressed in 293 cells, and shown to mobilize intracellular calcium in response to neuromedin U. This response was dose-dependent (EC(50) = 5 nm) and specific in that other neuromedins did not induce a calcium flux in receptor-transfected cells. Expression analysis of human NmU-R2 demonstrated its mRNA to be most highly expressed in central nervous system tissues. Based on these data, we conclude that NmU-R2 is a novel neuromedin U receptor subtype that is likely to mediate central nervous system-specific neuromedin U effects.     

High-affinity receptors for bombesin-like peptides in normal guinea pig lung membranes.

The binding of the radiolabelled bombesin analogue [125I-Tyr4]bombesin to guinea-pig lung membranes was investigated. Binding of [125I-Tyr4]bombesin was specific, saturable, reversible and linearly related to the protein concentration. Scatchard analysis of equilibrium binding data at 25 degrees C indicated the presence of a single class of non-interacting binding sites for bombesin (Bmax = 7.7 fmol/mg protein). The value of the equilibrium dissociation constant (KD = 90 pM) agrees with a high-affinity binding site. Bombesin and structurally related peptides such as [Tyr4]bombesin, neuromedin B and neuromedin C inhibited the binding of [125I-Tyr4]bombesin in an order of potencies as follows: [Tyr4]bombesin greater than bombesin greater than or equal to neuromedin C much greater than neuromedin B. These results indicate that guinea-pig lung membranes possess a single class of bombesin receptors with a high affinity for bombesin and a lower one for neuromedin B.     

Comparison of the actions of bombesin, gastrin-releasing peptide-27, neuromedin B, and gastrin-releasing peptide-10 in causing release of gastrin and gastric inhibitory peptide in rats

The objective of this study was to compare the gastrin- and gastric inhibitory peptide (GIP)-releasing actions of bombesin, gastrin-releasing peptide (GRP)-27, neuromedin B, and GRP-10 in rats. Both bombesin and GRP-27 are potent stimulants of gastrin and GIP release, whereas neuromedin B and GRP-10 are less effective, on a molar basis.     

Characterization of the murine pancreatic receptor for gastrin releasing peptide and bombesin.

The murine pancreatic receptor for bombesin and gastrin releasing peptide (GRP) has been characterized. Analysis of the binding of 125I-GRP to membranes indicates a single class of sites (10(-13) mol/mg protein) with Kd of 43 pM. A 70 kDa membrane protein was cross-linked to 125I-GRP by bis(sulfosuccinimidyl) suberate; labeling was blocked by GRP, GRP (14-27), AcGRP(20-27), GRP(18-27), bombesin and ranatensin, was partially blocked by [Leu13 psi (CH2NH)Leu14]bombesin and was unaffected by GRP(21-27) and GRP(1-16). The IC50 values for the competitive displacement of 125I-GRP from intact membranes by these peptides were similar to those obtained by the cross-linking experiments showing that the 70 kDa protein is the GRP receptor. The GRP receptor is G-protein coupled; divalent cations are required for high-affinity binding and nonhydrolyzable GTP analogs decrease receptor affinity. In minced pancreas, GRP caused a dose-dependent increase in inositol phosphates implicating phospholipase C in signal transduction. We suggest that the murine pancreatic receptor for bombesin/GRP is a 70 kDa membrane protein, is associated with a G-protein and stimulates phosphatidylinositol turnover.     

Bombesin-like peptide receptor gene expression,regulation, and function in fetal murine lung

Bombesin-peptide (BLP) immunoreactivity occurs at high levels in fetal lung. Previous studies showed that bombesin promotes fetal lung development. To test the hypothesis that such effects are mediated by known mammalian bombesin receptors [gastrin-releasing peptide (GRP)/bombesin-preferring receptor (GRPR), neuromedin B (NMB) receptor (NMBR), and the orphan bombesin receptor subtype-3 (BRS-3)], we analyzed the ontogeny of GRPR, NMBR, and BRS-3 gene expression in mouse lung. We examined the regulation of these three genes by dexamethasone and bombesin, which modulate lung development. Using incorporation of [3H]thymidine and [3H]choline, we then assessed whether GRP, NMB, and Leu8-phyllolitorin modulate lung growth and maturation in fetal lung explants. GRPR gene expression was detected predominantly in utero, whereas NMBR and BRS-3 genes were expressed from embryonic days 13-16 and on multiple postnatal days. All three mRNAs are present in airway epithelium and mesenchymal cells but occur in different relative patterns. These genes were regulated differently. Dexamethasone and bombesin increased GRPR mRNA, bombesin downregulated NMBR, and neither agent affected BRS-3. GRP increased incorporation of [3H]thymidine and [3H]choline in explants, whereas NMB induced cell proliferation and Leu8-phyllolitorin yielded variable results. Cumulative data suggest the involvement of multiple BLP receptors, including novel molecules, and argue against simple functional redundancy within this gene family during lung development.     

Development and function of bombesin-like peptides and their receptors

Amphibian bombesin and its related peptides consist a family of neuropeptides in many vertebrate species. Bombesin and two major bombesin-like peptide in mammals, gastrin-releasing peptide (GRP) and neuromedin B (NMB), have been shown to elicit various physiological effects. These include inhibition of feeding, smooth muscle contraction, exocrine and endocrine secretions, thermoregulation, blood pressure and sucrose regulations and cell growth. Receptors for GRP and NMB (GRP-R and NMB-R), as well as third subtype of bombesin-like peptide receptor (BRS-3) have been cloned. These receptors are G-protein-coupled receptors and are expressed in various brain regions and in the digestive tract. In this paper, we will summarize studies on these peptides and their receptors, with special reference to research using gene-knockout mice. These studies clearly demonstrated the role of three receptors in vivo and in vitro. We will also discuss the phylogeny of these receptors.     

Chronic desensitization to bombesin by progressive down-regulation of bombesin receptors in Swiss 3T3 cells. Distinction from acute desensitization

Prolonged exposure (40 h) of Swiss 3T3 cells to bombesin induced homologous desensitization to bombesin and structurally related peptides including mammalian gastrin releasing peptide (GRP). The ability of bombesin to mobilize intracellular Ca2+, inhibit epidermal growth factor binding, and stimulate DNA synthesis was profoundly and selectively inhibited. In contrast, Ca2+ mobilization by either vasopressin or bradykinin was unaffected, indicating that chronic desensitization is mechanistically distinct from acute desensitization of Ca2+ mobilization. Prolonged (24 or 40 h) pretreatment with bombesin also induced a 78 +/- 5% loss of bombesin receptor binding sites in both intact and plasma membrane preparations of Swiss 3T3 cells without an apparent change in receptor affinity (Kd = 1.9 +/- 0.1 x 10(-9) M and Kd = 1.8 +/- 0.2 x 10(-9) M for control and pretreated cells, respectively). Loss of 125I-GRP binding was slow and progressive with half-maximal loss of binding occurring after 7 h and maximal after approximately 14 h. Cross-linking of 125I-GRP to intact cultures and membrane preparations revealed an identical time-dependent loss of the Mr = 75,000-85,000 cross-linked band, previously identified as the bombesin receptor. Prolonged exposure of the cells to phorbol 12,13-dibutyrate, epidermal growth factor, cholera toxin, or mitogenic combinations of these agents did not alter 125I-GRP binding. Receptor down-regulation and loss of mitogenic responsiveness to bombesin were: (a) induced in a parallel dose-dependent manner by bombesin (ED50 = 1 nM), GRP (ED50 = 2 nM), and neuromedin B (ED50 = 20 nM), but not by the biologically inactive fragment GRP (1-16); (b) inhibited by the specific bombesin antagonist [Leu13-psi(CH2NH)-Leu14] bombesin, and (c) reversed upon removal of bombesin with a similar time course (full recovery after 15 h). On the basis of these observations, we propose that prolonged pretreatment of Swiss 3T3 cells with bombesin induces homologous desensitization to peptides of the bombesin family by down-regulation of cell surface bombesin receptors.     

Cloning and expression of a rat neuromedin K receptor cDNA

Functional cDNA clones for rat neuromedin K receptor were isolated from a rat brain cDNA library by cross-hybridization with the bovine substance K receptor cDNA. Injection of the mRNA synthesized in vitro from the cloned cDNA into Xenopus oocytes elicited electrophysiological responses to tachykinins, with the most potent sensitivity being to neuromedin K. Ligand-binding displacement in membranes of mammalian COS cells transfected with the cDNA indicated the rank order of affinity of the receptor to tachykinins: neuromedin K greater than substance K greater than substance P. The hybridization analysis showed that the neuromedin K receptor mRNA is expressed in both the brain and the peripheral tissues at different levels. The rat neuromedin K receptor consists of 452 amino acid residues and belongs to the family of G protein-coupled receptors, which are though to have seven transmembrane domains. The sequence comparison of the rat neuromedin K, substance P, and substance K receptors revealed that these receptors are highly conserved in the seven transmembrane domains and the cytoplasmic sides of the receptors. They also show some structural characteristics, including the common presence of histidine residues in transmembrane segments V and VI and the difference in the numbers and distributions of serine and threonine residues as possible phosphorylation sites in the cytoplasmic regions. This paper thus presents the first comprehensive analysis of the molecular nature of the multiple peptide receptors that exhibit similar but pharmacologically distinguishable activities.     

Simple luminometric assay to detect phosphoinositol-linked receptor expression in Xenopus oocytes.

A simple and sensitive method to measure the expression of phosphoinositol-linked receptors in Xenopus laevis oocytes is described. Oocytes are co-injected with the calcium photoprotein aequorin and RNA, encoding the receptor of interest. The binding of ligand to the expressed receptor increases intracellular calcium that induces the aequorin to luminesce. With an autosampler-equipped luminometer, this provides a fully automated assay of receptor expression of oocytes. This method was applied to cloning the bombesin/GRP receptor expressed in Swiss 3T3 fibroblasts. Oocytes expressing the cloned BR showed up to a 10,000-fold increase in light emission in response to bombesin. The sensitivity of this procedure allowed detection of positive luminometer signals in single oocytes injected with RNA transcribed from cDNA pools as large as 25,000 clones. These findings show the potential value of this procedure for rapid screening of expression libraries, structure/function analysis of receptors and analysis of receptor antagonists or agonists.     

Gastrin-releasing peptide (GRP) is not mammalian bombesin. Identification and molecular cloning of a true amphibian GRP distinct from amphibian bombesin in Bombina orientalis.

On the basis of structural homology and similar biological activity, gastrin-releasing peptide (GRP) has been considered the mammalian equivalent of amphibian bombesin. In this paper we now show this to be incorrect. Chromatography of frog (Bombina orientalis) gut extracts demonstrated two peaks of bombesin-like immunoreactivity (BLI), one similar in size to GRP and one similar in size to amphibian bombesin. These peaks were purified by high pressure liquid chromatography then subjected to mass spectrometric analyses to determine molecular weights and amino acid sequence. Based on the amino acid sequence of the lower molecular weight BLI species, a mixed oligonucleotide probe was prepared and used to screen a B. orientalis stomach cDNA library. Sequence analysis showed that all hybridizing clones encoded a 155-amino acid protein homologous to the mammalian GRP precursor. The mass spectra of the high and low molecular weight peaks of frog gut BLI were consistent with their origin from the processing of the frog GRP (fGRP) precursor into GRP-29 and GRP-10, just like the processing of the rat GRP precursor. Sequence homology showed that the fGRP precursor is more homology showed that the fGRP precursor is more closely related to the mammalian GRP precursors than to either the frog bombesin or frog ranatensin precursors. Northern blot analysis showed that fGRP is encoded by a mRNA of 980 bases, clearly different from the 750-base mRNA which encodes frog bombesin. Northern blot analysis and in situ hybridization showed fGRP mRNA in frog brain and stomach and bombesin mRNA in frog skin, brain, and stomach. That frogs have independent genes for both GRP and bombesin raises the possibility that mammals have an as yet uncharacterized gene encoding a true mammalian bombesin.     

Organization and chromosomal localization of the gene for the human bombesin receptor subtype expressed in pregnant uterus

The gene encoding the human homologue of the guinea pig uterine bombesin receptor [(1992) Eur. J. Biochem. 208,405] was isolated from a genomic lambda library by the PCR/homology screening approach. The gene spans more than 4 kb and consists of 3 exons and 2 introns. The deduced amino acid sequence shows about 86% identity to that of guinea pig bombesin receptor. This subtype of bombesin receptor is expressed in the pregnant uterus and in two human tumour cell lines, T47D (ductal breast carcinoma) and A431 (epidermal carcinoma). PCR analysis of genomic DNA from human-mouse cell hybrids allows the cloned gene to be localized to the region q26–q28 on chromosome X.     

A new high affinity technetium-99m-bombesin analogue with low abdominal accumulation

99mTc-labeled bombesin analogues have shown promise for noninvasive detection of many tumors that express bombesin (BN)/gastrin-releasing peptide (GRP) receptors. 99mTc-labeled peptides, however, have a tendency to accumulate in the liver and intestines due to hepatobiliary clearance as a result of the lipophilicity of the 99mTc chelates. This makes the imaging of lesions in the abdominal area difficult. In this study, we have synthesized a new high affinity 99mTc-labeled BN analogue, [DTPA1, Lys3(99mTc-Pm-DADT), Tyr4]BN, having a built-in pharmacokinetic modifier, DTPA, and labeled with 99mTc using a hydrophilic diaminedithiol chelator (Pm-DADT) to effect low hepatobiliary clearance. In vitro binding studies using human prostate cancer PC-3 cell membranes showed that the inhibition constant (Ki) for [DTPA1, Lys3(99Tc-Pm-DADT), Tyr4]BN was 4.1 +/- 1.4 nM. Biodistribution studies of [DTPA1, Lys3(99mTc-Pm-DADT), Tyr4]BN in normal mice showed very low accumulation of radioactivity in the liver and intestines (1.32 +/- 0.13 and 4.58 +/- 0.50% ID, 4 h postinjection, respectively). There was significant uptake (7.71 +/- 1.37% ID/g, 1 h postinjection) in the pancreas which expresses BN/GRP receptors. The uptake in the pancreas could be blocked by BN, partially blocked by neuromedin B, but not affected by somatostatin, indicating that the in vivo binding was BN/GRP receptor specific. Scintigraphic images showed specific, high contrast delineation of prostate cancer PC-3 xenografts in SCID mice. Thus, the new peptide has a great potential for imaging BN/GRP receptor-positive cancers located even in the abdomen.     

Development of a potent bombesin receptor antagonist with prolonged in vivo inhibitory activity on bombesin-stimulated amylase and protein release in the rat.

Of the various types of potent bombesin(Bn)/gastrin releasing peptide receptor antagonists that have been discovered, the desMet14-methyl ester peptides are devoid of residual agonist activity and are among the most potent in terms of in vitro receptor blockade and also in terms of their prolonged inhibition of bombesin-stimulated amylase and protein release in the rat. We have now examined the in vitro and in vivo properties of a new series of methyl ester analogues, [D-Phe6]Bn(6-13)OMe, [D-Phe6,D-Ala11]Bn(6-13)OMe, N alpha-propionyl-[D-Ala24]GRP(20-26)OMe, and [D-pentafluoro-Phe6,D-Ala11]Bn(6-13)OMe, which have an additional D-amino acid substituent and some highly lipophilic moieties at the N-terminus. All analogues were able to potently antagonize the ability of Bn to stimulate amylase release from rat acinar cells, with IC50 values of 2.4, 2.5, 0.6, and 1.3 nM, respectively. The four peptides were found to have binding affinities for these cells comparable to Bn itself, with K(i)s of 10.3, 2.8, 5.5, and 3.6 nM, respectively, but all had little or no affinity for neuromedin B receptors on murine C6 cells. Single bolus IV injections of these peptides were found to potently inhibit amylase and protein release caused by IV infusion of bombesin into the rat. Generally the peptides containing the D-Ala substituent were longer acting than [D-Phe6]Bn(6-13)OMe, so that [D-Phe6,D-Ala11]Bn(6-13)OMe and N alpha-propionyl-[D-Ala24]GRP(20-26)OMe displayed significant inhibitory effects for up to 1.5 h after administration.(ABSTRACT TRUNCATED AT 250 WORDS)