Synthesis and evaluation of novel multimeric neurotensin(8–13) analogs

Neurotensin(8-13) is a hexapeptide with subnanomolar affinity to the neurotensin receptor 1 which is expressed with high incidence in several human tumor entities. Thus, radiolabeled neurotensin(8-13) might be used for tumor targeting. However, its application is limited by insufficient metabolic stability. The present study aims at improving metabolic stability by the synthesis of multimeric neurotensin(8-13) derivatives rather than commonly employed chemical modifications of the peptide itself. Thus, different dimeric and tetrameric peptides carrying C- or N-terminal attached neurotensin(8-13) moieties have been synthesized and their binding affinity toward the neurotensin receptor has been determined. The results demonstrate that branched compounds containing neurotensin(8-13) attached via its C-terminus only show low receptor affinities, whilst derivatives with neurotensin(8-13) attached via the N-terminus show IC50 values in the nanomolar range. Moreover, within the multimeric neurotensin(8-13) derivatives with neurotensin(8-13) attached via the N-terminus an increasing number of branching units lead to higher binding affinities toward the neurotensin receptor.

Direct analysis of a GPCR-agonist interaction by surface plasmon resonance

Despite their clinical importance, detailed analysis of ligand binding at G-protein coupled receptors (GPCRs) has proved difficult. Here we successfully measure the binding of a GPCR, neurotensin receptor-1 (NTS-1), to its ligand, neurotensin (NT), using surface plasmon resonance (SPR). Specific responses were observed between NT and purified, detergent-solublised, recombinant NTS-1, using a novel configuration where the biotinylated NT ligand was immobilised on the biosensor surface. This SPR approach shows promise as a generic approach for the study of ligand interactions with other suitable GPCRs.

A novel form of neurotensin post-translationally modified by arginylation

A novel bioactive form of neurotensin post-translationally modified at a Glu residue was isolated from porcine intestine. Purification of the peptide was guided by detection of intracellular Ca2+ release in SK-N-SH neuroblastoma cells. Using high resolution accurate mass analysis on an ion trap Fourier transform mass spectrometer, the post-translational modification was identified as arginine linked to the gamma-carboxyl of Glu via an isopeptide bond, and we named the newly identified peptide "arginylated neurotensin" (R-NT, N-(neurotensin-C5-4-yl)arginine). Although arginylation is a known modification of N-terminal amino groups in proteins, its presence at a Glu side chain is unique. The finding places neurotensin among the few physiologically active peptides that occur both in post-translationally modified and unmodified forms. Pharmacologically, we characterized R-NT for its ligand activity on three known neurotensin receptors, NTR1, -2, and -3, and found that R-NT has similar pharmacological properties to those of neurotensin, however, with a slightly higher affinity to all three receptors. We expressed the intracellular receptor NTR3 as a soluble protein secreted into the cell culture medium, which allowed characterization of its R-NT and neurotensin binding properties. The creation of soluble NTR3 also provides a potential tool for neutralizing neurotensin action in vivo and in vitro. We have shown that SK-N-SH neuroblastoma cells express NTR1 and NTR3 but not NTR2, suggesting that the Ca2+ mobilization elicited by R-NT is via NTR1.

Identification and Functional Characterization of a 5-Transmembrane Domain Variant Isoform of the NTS2 Neurotensin Receptor in Rat Central Nervous System

The present study demonstrated that alternative splicing of the rat nts2 receptor gene generates a 5-transmembrane domain variant isoform (vNTS2) that is co-expressed with the full-length NTS2 receptor throughout the brain and spinal cord, as evidenced by reverse transcription-PCR. The vNTS2 polypeptide is 281 amino acids in length, which is 135 amino acids shorter than the full-length isoform. Immunohistochemical and radioligand binding studies revealed that the HA-tagged recombinant vNTS2 receptor is poorly targeted to plasma membranes in transfected COS-7 cells. Binding studies also showed that the truncated receptor displayed a 5000-fold lower affinity for neurotensin (NT) than its full-length counterpart (IC(50) of 10 mum and 2 nm, respectively). Yet NT binding induced efficient internalization of receptor-ligand complexes in vNTS2-transfected cells. Furthermore, it produced a rapid (<5 min) activation of the mitogen-activated protein kinases (ERK1/2) pathway, indicating functional coupling of the variant receptor. This activation is sustained (>1 h) and is also produced by the NTS2 agonist levocabastine. Western blotting experiments suggested that vNTS2 is not expressed in monomeric form in the rat central nervous system. However, it does appear to form a variety of multimeric complexes, including homodimers and heterodimers, with the full-length NTS2. Indeed, co-immunoprecipitation studies in dually transfected cells demonstrated that the two receptor isoforms can form stable associations. Taken together, the present results indicated that the rat vNTS2 is a functional receptor that may play a role in NT signaling in mammalian central nervous system.

Neurotensin negatively modulates Akt activity in neurotensin receptor-1-transfected AV12 cells

Neurotensin (NT) regulates a variety of biological processes primarily through interaction with neurotensin receptor-1 (NTR1), a heterotrimeric G-protein-coupled receptor (GPCR). Stimulation of NTR1 has been linked to activation of multiple signaling transduction pathways via specific coupling to G(q), G(i/o), or G(s), in various cell systems. However, the function of NT/NTR1 in the regulation of the Akt pathway remains unknown. Here, we report that activation of NTR1 by NT inhibits Akt activity as determined by the dephosphorylation of Akt at both Ser473 and Thr308 in AV12 cells constitutively expressing human NTR1 (NTR1/AV12). The inactivation of Akt by NT was rapid and dose-dependent. This effect of NT was completely blocked by the specific NTR1 antagonist, (S)-(+)-[1-(7-chloro-4-quinolinyl)-5-(2,6-dimethoxyphenyl)pyrazol-3-yl)-carbonylamino] cyclohexylacetic acid (SR 48527), but unaffected by the less active enantiomer ((R)-(-)-[1-(7-chloro-4-quinolinyl)-5-(2,6-dimethoxyphenyl)pyrazol-3-yl)-carbonylamino] cyclohexylacetic acid (SR 49711)), indicating the stereospecificity of NTR1 in the negative regulation of Akt. In addition, NT prevented insulin- and epidermal growth factor (EGF)-mediated Akt activation. Our results provide insight into the role of NT in the modulation of Akt signaling and the potential physiological significance of Akt regulation by NT.

Receptor trafficking via the perinuclear recycling compartment accompanied by cell division is necessary for permanent neurotensin cell sensitization and leads to chronic mitogen-activated protein kinase activation

Most G protein-coupled receptors are internalized after interaction with their respective ligand, a process that subsequently contributes to cell desensitization, receptor endocytosis, trafficking, and finally cell resensitization. Although cellular mechanisms leading to cell desensitization have been widely studied, those responsible for cell resensitization are still poorly understood. We examined here the traffic of the high affinity neurotensin receptor (NT1 receptor) following prolonged exposure to high agonist concentration. Fluorescence and confocal microscopy of Chinese hamster ovary, human neuroblastoma (CHP 212), and murine neuroblastoma (N1E-115) cells expressing green fluorescent protein-tagged NT1 receptor revealed that under prolonged treatment with saturating concentrations of neurotensin (NT) agonist, NT1 receptor and NT transiently accumulated in the perinuclear recycling compartment (PNRC). During this cellular event, cell surface receptors remained markedly depleted as detected by both confocal microscopy and (125)I-NT binding assays. In dividing cells, we observed that following prolonged NT agonist stimulation, NT1 receptors were removed from the PNRC, accumulated in dispersed vesicles inside the cytoplasm, and subsequently reappeared at the cell surface. This NT binding recovery allowed for constant cell sensitization and led to a chronic activation of mitogen-activated protein kinases p42 and p44. Under these conditions, the constant activation of NT1 receptor generates an oncogenic regulation. These observations support the potent role for neuropeptides, such as NT, in cancer progression.

Synthesis and biological studies of novel neurotensin(8-13) mimetics

Novel neurotensin (NT) (8-13) (Arg(8)-Arg(9)-Pro(10)-Tyr(11)-Ile(12)-Leu(13)) mimetics 3, 4 were designed by adopting all intrinsic functional groups of the native neurotensin(8-13) and using a substituted indole as a template to mimic the pharmacophore of NT(8-13). Biological studies at subtype 1 of the NT receptor showed that 3 has a 55 and 580 nM binding affinity at rat and human neurotensin receptors, respectively. As a comparison, compounds 5 and 6 were also synthesized. The binding difference between 3, 4 and 5, 6 argues the importance of the carboxylic group in achieving higher potency NT(8-13) mimetics.

Membrane biochips

Membrane-bound proteins represent the single most important class of drug targets. This article discusses the issues surrounding fabrication of membrane-protein microarrays by conventional robotic pin printing techniques. Ligand binding selectivity and specificity to G protein-coupled receptor (GPCR) microarrays are presented. The potential applications of these arrays for drug screening are discussed.

Shedding of the luminal domain of the neurotensin receptor-3/sortilin in the HT29 cell line

The neurotensin (NT) receptor-3/sortilin (NTR3) belongs to the new receptor family of VPS10P domain containing receptors. The NTR3 is expressed in all cancer cells on which NT activates cell growth and its cellular location is mainly intracellular within the endoplasmic reticulum and the trans-Golgi network. However, the NTR3 is also present at the cell surface of the HT29 cell line from which it is released by a mechanism activated by phorbol 12-myristate 13-acetate (PMA). The shedding of the NTR3 is sensitive to protein kinase C (PKC) and mitogen-activated protein (MAP) kinase inhibitors and to 1,10-phenanthroline and BB3103, suggesting the activation of zinc-metalloproteases and the ADAM10 (a desintegrin and metalloprotease). The shedding of the membrane NTR3 leads to a soluble protein able to bind exogenous NT, suggesting a role of this process in the biological activity of the peptide.

Neurotensin receptor-1 and -3 complex modulates the cellular signaling of neurotensin in the HT29 cell line

BACKGROUND & AIMS

The neuropeptide neurotensin (NT) exerts its intracellular effect by interacting with 3 different receptors. Two of these receptors (NTR1 and NTR2) belong to the G protein-coupled receptor family, whereas the third one (NTR3) is a type I receptor with a single transmembrane domain. We recently showed that the 2 structurally different receptors NTR1 and NTR3 were coexpressed in several human cancer cells on which NT exerts proliferative effects.

METHODS

Here, by an immunoprecipitation approach, we provide biochemical evidence for an endogenous heterodimerization of the G protein-coupled receptor NTR1 with the NTR3 in the human adenocarcinoma cell line HT29.

RESULTS

We show that both receptors are expressed and colocalized within the cell surface of HT29 cells where they already interact to form a heterodimer. The NTR1-NTR3 complex is then internalized on NT stimulation.

CONCLUSIONS

The complex formed between these 2 structurally unrelated NT receptors modulates both the NT-induced phosphorylation of mitogen-activated protein kinases and the phosphoinositide (PI) turnover mediated by the NTR1.

Topography of the neurotensin (NT)(8-9) binding site of human NT receptor-1 probed with NT(8-13) analogs

A series of neurotensin (NT)(8-13) analogs featuring substitution of the Arg8 and/or Arg9 residues with non-natural cationic amino acids was synthesized and evaluated for binding to the human NT receptor-1 (hNTR-1). The modifications were designed to probe specific steric and electrostatic requirements in the N-terminal cationic region of NT(8-13) for receptor binding as a general evaluation of the feasibility of incorporating minor structural changes into a peptide at a crucial polar receptor binding site. Many of the non-natural amino acids are more or less isosteric to Arg but more lipophilic as a result of addition of alkyl groups or through removal or replacement of NH character with methylene or methyl substituents, whereas others vary the distance between the cation and the alpha-amino acid carbon. Substitution of Arg8 with N(G)-alkylated Arg derivatives or homolysine (Hlys) maintained the subnanomolar affinity of NT(8-13) to the hNTR-1. Position 8 incorporation of Hlys produced the most favorable primary amine side-chain substitution to date. Moderate losses in affinity observed with position 9 substitutions were attributed to adverse steric effects. Doubly substituted [Hlys8, DAB9]NT(8-13), in which DAB is 2,4-diaminobutyric acid, was also prepared and tested as the shorter side-chain of DAB is known to be favored in position 9 of NT(8-13). This analog maintained 60% of NT(8-13) binding affinity making it the most favored des-guanidinium-containing analog known. These results demonstrate that adequate receptor binding affinity can be maintained over a structural range of Arg analogs, thus providing a range of peptides expected to exhibit altered pharmacokinetic properties. From the standpoint of the hNTR-1 cationic binding sites, these results help to map out the structural stringency inherent in the formation of a tight binding complex with NT(8-13) and related analogs.

Recycling ability of the mouse and the human neurotensin type 2 receptors depends on a single tyrosine residue

Receptor recycling plays a key role in the modulation of cellular responses to extracellular signals. The purpose of this work was to identify residues in G-protein coupled neurotensin receptors that are directly involved in recycling. Both the high affinity receptor-1 (NTR1) and the levocabastine-sensitive NTR2 are internalized after neurotensin binding. Here, we show that only the mouse NTR2 recycled to the plasma membrane, whereas the rat NTR1 and the human NTR2 did not. Using site-directed mutagenesis, we demonstrate that tyrosine 237 in the third intracellular loop is crucial for recycling of the mouse NTR2. We show that the mouse NTR2 is phosphorylated on tyrosine residues by NT. This phosphorylation is essential for receptor recycling since the tyrosine kinase inhibitor genistein blocks this process. The absence of recycling observed with the human NTR2 could be completely explained by the presence of a cysteine instead of a tyrosine in position 237. Indeed, substitution of this cysteine by a tyrosine gave a mutant receptor that has acquired the ability to recycle to the cell surface after neurotensin-induced internalization. This work demonstrates that a single tyrosine residue in the third intracellular loop of a G-protein-coupled receptor is responsible for receptor phosphorylation and represents an essential structural element for receptor recycling.

Impaired G protein coupling of the neurotensin receptor 1 by mutations in extracellular loop 3

The neurotensin receptor 1, NTS1, is a G protein-coupled receptor. We have shown previously that the NTS1 receptor-binding site of the peptide agonist involved residues in extracellular loop 3 and at the extracellular junction of transmembrane domains 4 and 6. Here, we investigated by site-directed mutagenesis residues in extracellular loop 3 that might be involved in agonist-induced activation of the rat NTS1 (rNTS1) receptor. Wild type and mutated receptors were expressed in COS (African green monkey kidney fibroblasts) cells. Labeled agonist and antagonist binding as well as inositol phosphate and cAMP productions were studied. Compared to the wild type NTS1 receptor, the W339A, F344A, H348A and Y349A mutant receptors exhibited (i) decreased proportion of high over low affinity agonist binding sites, (ii) increased sensitivity of high affinity agonist binding to GTP gamma S, and (iii) impaired G protein coupling of high affinity agonist-receptor complexes. The data are consistent with the C-terminal part of extracellular loop 3 being essential for allowing high affinity agonist-NTS1 receptor complexes to couple to G proteins.

Involvement of the neurotensin receptor subtype NTR3 in the growth effect of neurotensin on cancer cell lines

The expression of the 3 currently known neurotensin receptors was studied in human cancer cells of prostatic, colonic or pancreatic origin by means of RT-PCR analysis and binding experiments. All the cells selected for this work have been shown to exhibit a growth response to neurotensin. We found that the 7 transmembrane domain, levocabastine insensitive receptor (NTR1) is expressed in most but not all of the cells studied whereas the 7 transmembrane domain, levocabastine sensitive receptor (NTR2) is present in none of these cells. The 100 kDa-type I neurotensin receptor (NTR3) is expressed in all the cells assayed. Moreover, we demonstrated that neurotensin can stimulate the growth of CHO cells stably transfected with the NTR3. Taken together, our results strongly suggest that the NTR3 subtype could be involved in the growth response of human cancer cells to neurotensin.

A single amino acid of the human and rat neurotensin receptors (subtype 1) determining the pharmacological profile of a species-selective neurotensin agonist

The neurotensin (NT) receptor, subtype 1 (NTR1), is a 7-transmembrane-spanning receptor, forming 3 extracellular and 3 intracellular loops. Previously, we showed that the third outer loop (E3) is the binding site for NT and its analogs, several of which bind with higher affinity to rat NTR1 (rNTR1) than to human NTR1 (hNTR1). In particular, NT34 [3,1'-naphthyl-l-Ala(11)]NT(8-13) has greater than 60-fold higher affinity for rNTR1 (46 and 60 pM for transiently- and stably-transfected cells, respectively) than for hNTR1 (2.8 and 5.8 nM for transiently- and stably-transfected cells, respectively) isolated from transfected cell membranes. Previously, our molecular modeling studies of rNTR1 and hNTR1 showed that the binding pocket in the human receptor for NT34 is smaller in volume from the bulky residue Tyr(339) in the pocket center, as compared with the corresponding residue Phe(344) in the rat binding pocket. Therefore, with site-directed mutagenesis, we derived mutant forms of rNTR1(F344Y) and hNTR1(Y339F). Examination of the mutant receptors from membranal preparations of transfected cells in radioligand binding assays and with intact cells in functional assays (phosphatidyl-4,5-bisphosphate turnover) showed that the human-like rat receptor and the rat-like human receptor bound NT34 with a predicted reverse of binding compared with its binding to the wild-type receptors. These results strongly affirm our molecular modeling studies and demonstrate the importance of the study of even minor structural variations in proteins to determine the basis of significantly different drug responses, an area of focus for pharmacological research in the 21st century.

Immunologic differentiation of two high-affinity neurotensin receptor isoforms in the developing rat brain

Earlier studies have demonstrated overexpression of NT1 neurotensin receptors in rat brain during the first 2 weeks of life. To gain insight into this phenomenon, we investigated the identity and distribution of NT1 receptor proteins in the brain of 10-day-old rats by using two different NT1 antibodies: one (Abi3) directed against the third intracellular loop and the other (Abi4) against the C-terminus of the receptor. Immunoblot experiments that used Abi3 revealed the presence of two differentially glycosylated forms of the NT1 receptor in developing rat brain: one migrating at 54 and the other at 52 kDa. Whereas the 54-kDa form was expressed from birth to adulthood, the 52-kDa form was detected only at 10 and 15 days postnatal. Only the 52-kDa isoform was recognized by Abi4. By immunohistochemistry, both forms of the receptor were found to be predominantly expressed in cerebral cortex and dorsal hippocampus, in keeping with earlier radioligand binding and in situ hybridization data. However, whereas Abi4 immunoreactivity was mainly concentrated within nerve cell bodies and extensively colocalized with the Golgi marker alpha-mannosidase II, Abi3 immunoreactivity was predominantly located along neuronal processes. These results suggest that the transitorily expressed 52-kDa protein corresponds to an immature, incompletely glycosylated and largely intracellular form of the NT1 receptor and that the 54-kDa protein corresponds to a mature, fully glycosylated, and largely membrane-associated form. They also indicate that antibodies directed against different sequences of G-protein-coupled receptors may yield isoform-specific immunohistochemical labeling patterns in mammalian brain. Finally, the selective expression of the short form of the NT1 receptor early in development suggests that it may play a specific role in the establishment of neuronal circuitry.

Distribution of the neurotensin receptor NTS1 in the rat CNS studied using an amino-terminal directed antibody

The distribution of neurotensin receptor 1 immunoreactivity in the rat brain was studied using an antibody against the amino-terminal of the receptor expressed as a fusion protein with glutathione-S transferase. Affinity purified antibodies detected the fusion protein and the complete neurotensin receptor sequence expressed in Escherichia coli. The immunostaining was abolished by preabsorption with the amino-terminal fusion protein. Immunoreactive neurotensin receptor 1 immunoreactivity was detected on cell bodies and their processes in a number of CNS regions. In agreement with previous binding studies neurotensin receptor 1 immunoreactivity was particularly localised in cell bodies in the basal forebrain, nucleus basalis and substantia nigra. At the electron microscope level immunoreactivity was found both in axonal bouton and dendrites and spines in the basal forebrain indicating that neurotensin may act both pre- and post-synaptically. There were several regions such as the substantia gelatinosa, ventral caudate-putamen and the lateral reticular nucleus where the neurotensin receptor 1 positive cells had not previously been reported, indicating that distribution of this receptor is widespread.

Identification of residues involved in neurotensin binding and modeling of the agonist binding site in neurotensin receptor 1

The neurotensin receptor 1 (NTR1) subtype belongs to the family of G protein-coupled receptors and mediates most of the known effects of the neuropeptide including modulation of central dopaminergic transmission. This suggested that nonpeptide agonist mimetics acting at the NTR1 might be helpful in the treatment of Parkinson's disease and schizophrenia. Here, we attempted to define the molecular interactions between neurotensin-(8-13), the pharmacophore of neurotensin, and the rat NTR1. Mutagenesis of the NTR1 identified residues that interact with neurotensin. Structure-activity studies with neurotensin-(8-13) analogs identified the peptide residues that interact with the mutated amino acids in the receptor. By taking these data into account, computer-assisted modeling techniques were used to build a tridimensional model of the neurotensin-(8-13)-binding site in which the N-terminal tetrapeptide of neurotensin-(8-13) fits in the third extracellular loop and the C-terminal dipeptide binds to residues at the junction between the extracellular and transmembrane domains of the receptor. Interestingly, the agonist binding site lies on top of the previously described NTR1-binding site for the nonpeptide neurotensin antagonist SR 48692. Our data provide a basis for understanding at the molecular level the agonist and antagonist binding modes and may help design nonpeptide agonist mimetics of the NTR1.

Agonist induced conformation alteration of neurotensin receptor and the mechanism behind Na+ inhibition of 125I-NT binding

In the absence of Na+, 125I-Neurotensin (125I-NT) binding to the Neurotensin receptor (NTR) produces a stable noncovalent 125I-NT-NTR complex whose dissociation rate is extremely low even after the addition of 1 microM NT, 100 microM SR48692 (antagonist), 100 microM GPPNHP or 100 mM NaCl. Lowering the medium pH to 4.5 enhances the process (approximately 70% in 10 minutes). Labeling by photoactivatable 125I-Tyr3-Azo4-NT identifies a approximately 50 KD Mr band along with several other minor components. Interestingly, the labeling intensity is drastically reduced when binding is performed in the presence of Na+ or GPPNHP. However, a minor reduction is noticed when Na+ or GPPNHP is added to the medium after binding. The binding kinetics indicates that Na+ lowers the rate of 125I-NT association by acting as a noncompetitive inhibitor. On the contrary, Na+ favors the interaction of antagonist, SR48692 by lowering the value of Ki. GTPgamma35S binding to membranes in the presence of 30 mM NaCl suggests that Na+ inhibition of 125I-NT binding is due to the uncoupling of NTR associated G protein(s). In order to explain the entire phenomenon, a two-step, binding model has been proposed. In Step-1, interaction between NT and NTR produces a transient complex, which attains a stable state in the absence of NaCl via step-2, thereby altering the native NTR conformation. The presence of Na+ prevents step-2 by dissociating the transition complex.

Mutagenesis and modeling of the neurotensin receptor NTR1. Identification of residues that are critical for binding SR 48692, a nonpeptide neurotensin antagonist

The two neurotensin receptor subtypes known to date, NTR1 and NTR2, belong to the family of G-protein-coupled receptors with seven putative transmembrane domains (TM). SR 48692, a nonpeptide neurotensin antagonist, is selective for the NTR1. In the present study we attempted, through mutagenesis and computer-assisted modeling, to identify residues in the rat NTR1 that are involved in antagonist binding and to provide a tentative molecular model of the SR 48692 binding site. The seven putative TMs of the NTR1 were defined by sequence comparison and alignment of bovine rhodopsin and G-protein-coupled receptors. Thirty-five amino acid residues within or flanking the TMs were mutated to alanine. Additional mutations were performed for basic residues. The wild type and mutant receptors were expressed in COS M6 cells and tested for their ability to bind 125I-NT and [3H]SR 48692. A tridimensional model of the SR 48692 binding site was constructed using frog rhodopsin as a template. SR 48692 was docked into the receptor, taking into account the mutagenesis data for orienting the antagonist. The model shows that the antagonist binding pocket lies near the extracellular side of the transmembrane helices within the first two helical turns. The data identify one residue in TM 4, three in TM 6, and four in TM 7 that are involved in SR 48692 binding. Two of these residues, Arg327 in TM 6 and Tyr351 in TM 7, play a key role in antagonist/receptor interactions. The former appears to form an ionic link with the carboxylic group of SR 48692, as further supported by structure-activity studies using SR 48692 analogs. The data also show that the agonist and antagonist binding sites in the rNTR1 are different and help formulate hypotheses as to the structural basis for the selectivity of SR 48692 toward the NTR1 and NTR2.

Stable expression of the mouse levocabastine-sensitive neurotensin receptor in HEK 293 cell line: binding properties, photoaffinity labeling, and internalization mechanism

The recently cloned new subtype of G protein-coupled neurotensin receptor (NTRL) was stably expressed in the HEK 293 cell line in order to investigate its binding and internalization properties. The expressed receptor exhibited the typical binding characteristics of the low affinity, levocabastine-sensitive binding site previously described in rat and mouse brain and was detected as a protein with an apparent MW of 45 kDa by photoaffinity labeling. Although intracellular modulation of adenylate cyclase, guanylate cyclase and phospholipase C was not detected after application of neurotensin or levocabastine on NTRL-transfected cells, this receptor was able to internalize iodinated neurotensin. The internalization process was followed by recycling of receptors to the cell membrane. By contrast, no recycling was observed with the high affinity neurotensin receptor (NTRH). The differential intracellular routing of NTRH and NTRL after internalization is most probably the consequence of their divergent carboxy-terminal sequences.

Identification in the rat neurotensin receptor of amino-acid residues critical for the binding of neurotensin

In order to identify charged amino-acid residues of the cloned rat brain neurotensin (NT) receptor (NTR) that are critical for NT binding, we performed site-directed mutagenesis on the cDNA encoding this protein, followed by transient expression into mammalian COS-7 cells and in Xenopus laevis oocytes. Point substitutions of charged residues in the N-terminal part and in the 2nd and 3rd extracellular loop of the receptor either did not affect (125)I-Tyr3-NT binding or resulted in a decrease in binding affinity by a factor of 2-3. Mutations of amino acids Asp113 in the second transmembrane domain (TM) and of Arg149 or Asp150 in TM III yielded receptors that bound NT as efficiently as the native receptor. By contrast, replacement of the Asp139 residue in the 1st extracellular loop, or of Arg143 or Arg327-Arg328 residues at the top of TM III and in TM VI, respectively, completely abolished ligand binding. Confocal and EM immunocytochemical studies of the expression of these affected receptors, tagged with the C-terminal sequence of the vesicular stomatitis virus glycoprotein (VSV-G), indicated that this loss of binding was not due to altered receptor expression or to their improper insertion into the plasma membrane. When these mutated forms of neurotensin receptor were expressed into Xenopus oocytes, Asp139-Gly- and Arg143-Gly-modified receptors remained functional in spite of a lowered response to NT whereas the Arg327-Arg328 mutant form was totally insensitive to NT at concentrations up to 10 microM. In the case of the Arg327-Arg328 mutation, the observed insensibility to NT could be the result of a drastic conformational alteration of this mutant protein. By contrast, it would appear that Asp139 and Arg143 residues located in the first extracellular loop of the receptor may be directly involved in the interaction of the receptor with neurotensin.

Radiolabeled ligands specific for the G protein-coupled state of neurotensin receptors

Radiolabeled analogues of neuromedin N have been prepared by acylation of the alpha, epsilon 1, and epsilon 2 amino groups of [Lys2]neuromedin N (Lys-Lys-Pro-Tyr-Ile-Leu) either with the 125l-labeled Bolton-Hunter reagent or with N-succinimidyl[2,3-3H]propionate. The binding properties of the purified analogues toward newborn mouse brain homogenate or toward membranes of cells transitorily (COS) or permanently (AA1) transfected with the cloned rat brain neurotensin receptor cDNA were evaluated and compared with those of radiolabeled neurotensin. The alpha-modified analogue of [Lys2]neuromedin N behaves exactly like neurotensin in these binding experiments, whereas the epsilon 1- and epsilon 2-modified analogues selectively recognize the fraction of neurotensin binding sites that is sensitive to GTP gamma S. The proportion of neurotensin receptors coupled to GTP binding proteins is approximately 50% in membranes of newborn mouse brain or of AA1 cells that respond to neurotensin by an increase of the intracellular inositol trisphosphate concentration. By contrast, membranes of transitorily transfected COS cells that do not respond to neurotensin exhibit very low levels of GTP-sensitive receptors labeled with the epsilon 1- or epsilon 2-modified analogues. These radiolabeled peptides offer new tools to selectively detect active neurotensin receptors.

Chimeric rat/human neurotensin receptors localize a region of the receptor sensitive to binding of a novel, species-specific, picomolar affinity peptide

Recently, we reported the development of a species-specific neurotensin analog that displays selective binding affinity at the rat and human neurotensin (NT) receptor, L-[3,2'-Nal11]NT(8-13) (where Nal is naphthylalanine) (NT19). We have developed another neurotensin analog, L-[3,1'-Nal11]NT(8-13), (NT34), that exhibits a 126-fold difference in binding affinities between the rat and human receptors. This compound differs from our previous reported species-specific ligand in the steric positioning of the naphthyl ring on the L-alanine side chain. For NT34, the observed Kd values at the rat and human neurotensin receptors were 0.046 and 5.8 nM, respectively. In stimulating phosphatidylinositol turnover, the observed EC50 values were 2.8 nM and 130 nM in rat and human, respectively. We constructed a series of chimeric rat/human neurotensin receptor genes and expressed them by transient transfection into human embryonic kidney (HEK-293) cells. Radioligand binding assays were then performed using neurotensin and NT34. Our results led us to propose a region of the neurotensin receptor that may be involved in determining species specificity, i. e. the transmembrane VI, the third extracellular loop, and transmembrane VII regions of the neurotensin receptor.

Proposed ligand binding site of the transmembrane receptor for neurotensin(8-13)

We report here the first proposed ligand binding site of the transmembrane receptor for neurotensin(8-13) in human and rat, the corresponding bound conformation of the peptide ligand, and site-directed mutagenesis studies that support the binding site model. These three-dimensional structures were generated by using a heuristic approach in conjunction with experimental data. The proposed neurotensin(8-13) binding site is primarily composed of eight residues (i.e., Phe326, Ile329, Trp334, Phe337, Tyr339, Phe341, Tyr342, and Tyr344 in the human receptor; Phe331, Ile334, Trp339, Phe342, Phe344, Phe346, Tyr347, and Tyr349 in the rat receptor) located in the third extracellular loop. The seven aromatic residues form an aromatic pocket on the extracellular surface of the neurotensin receptor to accommodate its ligands apparently by cation-pi, pi-pi, and hydrogen bonding interactions. The neurotensin(8-13) ligand adopts a compact conformation at the proposed binding site. In the bound conformation of neurotensin(8-13), the backbone of Arg9-Pro10-Tyr11-Ile12 forms the proline type I turn, and the hydroxy group of Tyr11 interacts with the two guanidinium groups of Arg8 and Arg9. These guanidinium groups are curled toward the hydroxy group so that they interact electrostatically with the hydroxy group, and that the guanidinium group of Arg9 forms an intra-hydrogen bond with the hydroxy group. The proposed three-dimensional structure may not only provide a basis for rationalizing mutations of the neurotensin receptor gene but also offer insights into understanding the binding of many neurotensin analogs, biological functions of the neurotensin receptors, and structural elements for species specificity of the neurotensin receptors, and may expedite developing nonpeptidic neurotensin mimetics for the potential treatment of the neuropsychiatric diseases.