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Volume 16, Number 18, Issue of September 15, 1996 pp. 5613-5620
Copyright ©1996 Society for NeuroscienceStructure, Functional Expression, and Cerebral Localization of the Levocabastine-Sensitive Neurotensin/Neuromedin N Receptor from Mouse Brain
Jean Mazellaa, Jean-Marie Bottoa, Eric Guillemare, Thierry Coppola, Philippe Sarret, and Jean-Pierre Vincent Institut de Pharmacologie Moléculaire et Cellulaire, Unité Propre de Recherche 411, Centre National de la Recherche Scientifique, 06560 Valbonne, France
ABSTRACT
This work describes the cloning and expression of the levocabastine-sensitive neurotensin (NT) receptor from mouse brain. The receptor protein comprises 417 amino acids and bears the characteristics of G-protein-coupled receptors. This new NT receptor (NTR) type is 39% homologous to, but pharmacologically distinct from, the only other NTR cloned to date from the rat brain and the human HT29 cell line. When the receptor is expressed in Xenopus laevis oocytes, the H1 antihistaminic drug levocabastine, like NT and neuromedin N, triggers an inward current. The pharmacological properties of this receptor correspond to those of the low-affinity, levocabastine-sensitive NT binding site described initially in membranes prepared from rat and mouse brain. It is expressed maximally in the cerebellum, hippocampus, piriform cortex, and neocortex of adult mouse brain.
Key words: neurotensin; neuromedin N; receptor; levocabastine; cloning; low affinity; G-protein-coupled
INTRODUCTION
The existence of multiple receptors for the neurotensin (NT)-related peptides was suggested initially by the description of two families of NT binding sites (KD1 = 0.17 n; KD2 = 2 n) in rat brain synaptic membranes (Mazella et al., 1983) and by the ability of the antihistaminic H1 drug levocabastine to totally inhibit NT binding to the low-affinity sites without affecting binding to the high-affinity sites (Schotte et al., 1986
Recently, an NTR cloned from rat brain (Tanaka et al., 1990
We describe in this work the cloning and functional expression of the low-affinity levocabastine-sensitive NT receptor (NTRL). This receptor is poorly recognized by the nonpeptide NT antagonist SR48692. Its tissue distribution and ontogenic expression were analyzed and compared with those of the previously cloned NTRH.
MATERIALS AND METHODS
Materials. NT and neuromedin N (NN) were purchased from Peninsula Laboratories (Belmont, CA). Trp11-NT, Trp11-NT, and xenin were from Bachem (Torrance, CA). SR48692 was from Sanofi. Levocabastine was a generous gift from Dr. Alain Schotte (Janssen Pharmaceutica, Beerse, Belgium). NT was iodinated and purified as described previously (Sadoul et al., 1984cDNA cloning and expression of the mouse NTR. A cDNA library was constructed from mouse brain poly(A+) RNA into the UniZap XR vector (Stratagene, LaJolla, CA) according to the procedures described by the manufacturer. Clones (5 × 105) derived from the cDNA library were screened by hybridization with the total open reading frame of the rat NTR cDNA (1.27 kb) (Tanaka et al., 1990
The 1.6 kb EcoRI-ApaI fragment of the NTRL was inserted into a eukaryotic expression vector (pcDNA3) containing the cytomegalovirus promoter and the resistance to G418 gene as a selective marker. Transient transfections were performed with 1 µg of recombinant pcDNA3 plasmid by the DEAE-dextran precipitation method (Cullen, 1987
Binding experiments were carried out on freshly prepared cell membrane homogenates as described previously (Chabry et al., 1994
counter. Binding parameters [dissociation constant (KD) and maximal binding capacity (Bmax)] were derived from Scatchard analysis of the data. Competition experiments were performed by incubating membranes with 0.4 n 125I-Tyr3-NT and increasing concentrations of various synthetic or natural analogs of NT (from 10
11 to 10
RNA blot hybridization analysis. RNAs were isolated from different tissues of adult male mice or from whole brain of 7-, 15-, and 35-d-old mice and rats by the guanidinium thiocyanate-phenol-chloroform method (Chomczynski and Sacchi, 1987
Electrophysiological measurements. The pcDNA3 vector containing the cDNA of the mouse NTRL served as template to prepare cRNAs using the in vitro transcription kit from Stratagene. cRNAs (~10 ng) were injected into Xenopus laevis oocytes. The oocytes were then incubated at 18°C for 2-4 d. Electrophysiological measurements were performed at 20°C according to the procedure described previously (Masu et al., 1987
60 mV.
In situ hybridization in mouse brain. A 600 bp cDNA fragment corresponding to nucleotides 660-1260 was inserted into the TA cloning vector (Invitrogen) by PCR and standard cloning techniques and used as a template to produce sense and antisense 33P-labeled RNA probes. Paraformaldehyde-perfused mouse brain sagittal sections were incubated in 120 m phosphate buffer, pH 7.2, containing 50% formamide, 4× SSC, 1× Denhardt's solution, 10% dextran sulfate, and 0.6% sarcosyl with antisense and sense 33P-labeled RNA probes (3 × 105 cpm/slice). After 15 hr at 50°C, slices were washed twice with 4× SSC and 1× SSC at room temperature, treated with RNase A (5 µg/ml) for 5 min at 37°C, and finally washed with 0.1× SSC and dehydrated in graded ethanol before radioautography for 5 d on Amersham Hyperfilm
max.
RESULTS
Molecular cloning and nucleotide and amino acid sequence of the mouse NTR
A mouse brain cDNA library consisting of 5 × 105 clones was screened by hybridization with a cDNA probe corresponding to the open reading frame of the rat NTRH cDNA clone under low-stringency conditions. The only hybridization-positive clone was then purified. Sequence analysis revealed nucleic acid stretches that shared up to 70% homology with the rat NTRH cDNA.Figure 1 shows the 1554 nucleotide sequence determined for the cloned cDNA. The amino acid sequence of the mouse NTRL was assigned from the longest open reading frame of the cDNA. The nucleotide sequence surrounding the putative initiation codon agrees with the consensus sequence for the eukaryotic translation sites (Kozak, 1987
Fig. 1. The cDNA sequence of the mouse NTRL and its deduced amino acid sequence. The amino acid sequence deduced for the NTRL is shown above the nucleotide sequence. Positions of the putative transmembrane domains I-VII of the NTRL are indicated above the amino acid sequence on the basis of hydropathicity profile (Kyte and Doolittle, 1982
[View Larger Version of this Image (52K GIF file)]
The structure of NTRL indicates that it belongs to the large family of G-protein-coupled receptors (Probst et al., 1992
2-C2 adrenergic receptor (Lomasney et al., 1990
NTRL shows a high degree of sequence homology with the rat and human NTRH, as illustrated in Figure 2. The global amino acid homology is 39% and 36% with the rat and human NTRH, respectively. At the level of the transmembrane domains, however, this homology can rise up to 67% in TM III and 76% in TM VII with the rat NTRH. The first and third extracellular loops also show high degrees of sequence homology with the rat NTRH (68 and 59%, respectively). By contrast, the third intracellular loop is 19 amino acids longer than and weakly homologous to that of NTRH. It is noteworthy that NTRL does not show a high degree of sequence similarity with other G-protein-coupled receptors (Probst et al., 1992
Fig. 2. Alignment of the amino acid sequences between mouse, human, and rat NTR. The mouse NTRL (mNTRL) sequence is compared with the rat (rNTRH) (Tanaka et al., 1990
[View Larger Version of this Image (97K GIF file)]
Biochemical properties of the mouse NTRL
The binding properties of the mouse NTRL were characterized by expression after transient transfection of the cloned cDNA in eukaryotic COS-7 cells. 125I-Tyr3-NT bound to membranes prepared from cells transfected with the NTRL cDNA in a specific and saturable manner (Fig. 3). No binding was detected with membranes prepared from untransfected cells or cells transfected with the vector alone (data not shown). Scatchard plot analysis of 125I-Tyr3-NT binding (Fig. 3, inset) showed a single class of sites with a Kd value of 2.45 ± 1.04 n (n = 6). This value is very close to that reported for the low-affinity NT binding site in the brain of mammals (Vincent, 1995
Fig. 3. Saturation of specific 125I-Tyr3-NT binding to membranes prepared from NTRL cDNA-transfected COS-7 cells. Experimental details are described in Materials and Methods. Results are shown from one of three independent experiments. Inset, Scatchard analysis of the data. In this experiment, Kd and Bmax values were 2.2 n and 160 fmol/mg protein, respectively.
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The ability of various unlabeled peptide and nonpeptide compounds to inhibit the binding of 125I-Tyr3-NT to membranes from COS-7 cells transfected with NTRL is shown in Figure 4 and Table 1. With an IC50 of 1-2 n, the antihistaminic drug levocabastine was as potent as unlabeled NT in inhibiting the binding of labeled NT (Fig. 4). By contrast, histamine lacked the ability to compete for binding to NTRL (Table 1). NN, Trp11-NT, and the mammalian xenopsin analog xenin (Feurle et al., 1992
Fig. 4. Displacement of 125I-Tyr3-NT bound to membranes prepared from NTRL cDNA-transfected COS-7 cells by NT, levocabastine, -Trp11-NT, SR48692, and NT (1-10). Experimental details are described in Materials and Methods. The binding of 125I-Tyr3-NT was measured in the presence of increasing concentrations of NT (closed circles), levocabastine (open circles), -Trp11-NT (closed triangles), SR48692, (open squares), and NT (1-10) (open triangles). Each point represents the mean of two separate experiments.
[View Larger Version of this Image (19K GIF file)]
Table 1. IC50 values of NT and its related compounds in competition experiments with 125I-Tyr3-NT on membranes from COS-7 cells transiently transfected with the mNTR, and inhibitory effect of NA+, K+, and Mg2+
Compound Structure IC50 values (n) NT pELYENKPRRPYIL 2-3 NN KIPYIL 1.5-2.5 Levocabastine Nonpeptidic 1-2 Xenin MLTKFETKSARVKGLSFHPKRPWIL 1.5-2 Trp11-NT pELYENKPRRPWIL 1-1.5 -Trp11-NT pELYENKPRRP[-Trp]IL 24-30 SR48692 Nonpeptidic 200-300 Dynorphin (1-13) YGGFLRRIRPKLK 220-300 NT (1-10) pELYENKPRRP >10,000 Histamin Bioamine >10,000 Ions Na+ 250-300 K+ 300-320 Mg2+ >100 The indicated values were obtained from two independent experiments performed in triplicate. Functional properties of the mouse NTRL
To investigate the functional properties of NTRL, we expressed this receptor type into Xenopus laevis oocytes. Figure 5A shows examples of electrophysiological responses recorded after application of NT, NN, xenin, and levocabastine to oocytes injected with cRNAs encoding the receptor. The application of 10
Fig. 5. Current traces recorded from Xenopus oocytes injected with the in vitro synthesized NTRL mRNA. Experimental details are described in Materials and Methods. A, 10
[View Larger Version of this Image (13K GIF file)]
Tissue distribution and ontogeny in the brain of NTRL mRNA
The level of expression of NTRL mRNA in brain and peripheral tissues was examined by blot hybridization analysis. As shown in Figure 6A, mouse poly(A+) RNAs isolated from the brain and the cerebellum were labeled on a single band with an estimated mRNA size of ~1.8 kilonucleotides. Note that NTRL expression was slightly higher in the cerebellum. Surprisingly, no labeling of poly(A+) RNAs isolated from large intestine, heart, testis, and liver was observed under the hybridization conditions used.
Fig. 6. Blot hybridization analysis of poly(A+) RNAs isolated from various mouse tissues (A) and from rat and mouse brains of different ages (B). Experimental details are described in Materials and Methods. The poly(A+) RNAs used were isolated from the following tissues: mouse in A, lane 1, cerebral cortex; lane 2, cerebellum; lane 3, testis; lane 4, heart; lane 5, large intestine; and lane 6, liver; in B, whole brain of rat (top) or mouse (bottom) age 7 d (7d), 15 d (15d), and 35 d (35d). The hybridization was carried out with probes from NTRL in A and B (top) and from NTRH in B (bottom).
[View Larger Version of this Image (61K GIF file)]
To identify definitely the cloned mouse NTRL as the low-affinity binding site characterized previously in rat and mouse brain, the cerebral expression of the NTRL mRNA at different ages was analyzed and compared with the cerebral expression of the rat NTRH at corresponding ages by blot hybridization. Figure 6B demonstrates that the mouse NTRL was poorly expressed in 7-d-old brain and that the expression increased at day 15 to reach a maximal level in 35-d-old brain. By contrast, the rat NTRH was expressed maximally in 7-d-old brain, and its expression decreased progressively until adulthood (35-d-old brain). These results are totally in accordance with results obtained in binding experiments with rat and mouse brain that described the transient high expression of the NTRH between 7 and 10 d after birth, whereas the NTRL appeared later and were expressed maximally in adult brain (Schotte and Laduron, 1987
Distribution of NTRL in the mouse brain
The regional distribution of this NT receptor type was examined by in situ hybridization analysis. The labeling obtained with the antisense probe is illustrated in Figure 7A-C. NTRL mRNAs were expressed in discrete regions of the mouse brain. The most important labeling was observed in the cerebellar cortex, particularly in the layer of Purkinje cells (Fig. 7A-C). The labeling was also important in the CA1-CA3 fields of the hippocampus, in the dentate gyrus, and at the level of the piriform cortex (Fig. 7B,C). A more diffuse but important labeling was also detected throughout the cerebral neocortex. Note the absence of labeling in the substantia nigra and the hypothalamic regions. A negative control obtained with the sense probe is shown in Figure 7D.
Fig. 7. Localization of the NTRL in the mouse brain by in situ hybridization analysis. Experimental details are described in Materials and Methods. Sagittal brain slices were hybridized with the antisense (A, L1.45; B, L2.2; C, L2.45) or with the sense (D) mNTR probe. CA1, CA2, CA3, Fields of the hippocampus; CPu, caudate putamen; DG, dentate gyrus; P, Purkinje cell layer; N, neocortex; SN, substantia nigra; Th, thalamus; Pir, piriform cortex. Scale bar, 1 mm.
[View Larger Version of this Image (108K GIF file)]
DISCUSSION
The present study identifies in the mouse brain a NT receptor that shares 39% and 36% homology with the previously cloned rat and human NTRH, respectively. Such a relatively low degree of homology makes it likely that the newly cloned receptor is not really the mouse counterpart of the NTRH, but rather represents a new NTR type. Actually, several lines of evidence indicate that the mouse brain receptor characterized here corresponds to the low-affinity, levocabastine-sensitive NT binding site described previously in the rat and mouse brain (Schotte et al., 1986The functional consequences of levocabastine binding to NTRL remained unknown until now. The cloning and expression of NTRL in Xenopus leavis oocytes made it possible to address this issue. Interestingly, it was found here that levocabastine behaves as an agonist of the NTRL in the oocyte expression system. It will now be necessary and of interest to investigate further the effects of levocabastine in mammalian systems that express the NTRL, whether normally or on transfection. Because no evidence of coupling to transduction mechanisms has been established for the low-affinity sites, they were considered for a long time as NT acceptor sites devoid of pharmacological function (Laduron, 1995
Several additional data identify this newly cloned NTRL as the low-affinity component of NT binding sites. First, the comparison of the cerebral ontogenic expression of the mouse NTRL with the cerebral expression of the NTRH is totally in accordance with the ontogenic expression of the low- and high-affinity NT binding components, respectively, determined in the rat and mouse brain using binding experiments (Schotte and Laduron, 1987
Some peculiar structural characteristics of the cloned NTRL need to be emphasized. This receptor clearly belongs to the family of G-protein-coupled receptors, because it possesses seven hydrophobic domains and is coupled in the oocyte expression system; however, the N-terminal sequence of the protein is devoid of a putative N-glycosylation site. This rare property, observed only in the case of the
The differential tissue distribution of NTRL and NTRH suggests that these receptors might subserve distinct NT effects. Pharmacological data also support this hypothesis. In this context, it is worth noting that the recently developed nonpeptide antagonist SR48692 is much less potent on the new NT receptor (IC50 = 300 n) than on the rat brain NTRH (IC50 = 5.6 n) (Gully et al., 1993
In summary, this work demonstrates that at least two different types of functional NT receptors exist. The new NT receptor cDNA described here should help to define more accurately the different pathways leading to the expression of the various central and peripheral properties of NT.
FOOTNOTES
Received March 13, 1996; revised June 14, 1996; accepted June 27, 1996.
a These authors contributed equally to this work.
This work was supported by Centre National de la Recherche Scientifique. We thank Dr. Jean-Philippe Hugnot, Gisèle Jarretou, and Gilles Toumaniantz for fruitful discussion and technical comments. We also thank Franck Aguila for excellent artwork, Nicole Zsürger for her help in histology, and Dr. Patrick Kitabgi for carefully reading this manuscript.
GenBank accession number for the nucleotidic sequence of mouse NTRL: U51908[GenBank].
Correspondence should be addressed to Jean Mazella, Institut de Pharmacologie Moléculaire et Cellulaire, Unité Propre de Recherche 411, Centre National de la Recherche Scientifique, 660 Route des Lucioles, Sophia Antipolis, 06560 Valbonne, France.
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