Role of sulfhydryl groups in Y2 neuropeptide Y receptor binding activity.

Benextramine, a tetramine disulfide, irreversibly inhibits neuropeptide Y (NPY) binding to the 50-kDa Y2 NPY receptor in bovine hippocampus (Li, W., MacDonald, R. G., and Hexum, T. D. (1991) Eur. J. Pharmacol. 207, 89-91). Evidence is presented that this inhibition occurs through a thiol-disulfide exchange. Treatment of bovine hippocampal membranes with benextramine inhibited NPY affinity cross-linking to the 50-kDa receptor. This inhibition of labeling was not affected by washing the membranes, but could be completely reversed by the addition of several thiol reducing reagents, including reduced glutathione, beta-mercaptoethanol, and cysteine. Benextramine inhibited 70% of NPY-specific labeling and was much more effective than other sulfhydryl reactive agents, such as oxidized glutathione, cystamine, and 5,5'-dithio-bis(2-nitrobenzoic acid). Furthermore, the sulfhydryl-modifying agents N-ethylmaleimide and p-chloromercuriphenyl-sulfonic acid specifically decreased NPY affinity labeling. Finally, NPY labeling of the 50-kDa receptor was reduced by the heavy metal ions Zn2+, Cu2+, and Hg2+. Preincubation with NPY prevented Y2 receptors from being inactivated by either 400 microM N-ethylmaleimide or 1 mM benextramine. These results suggest that one or more benextramine-sensitive sulfhydryl groups on the Y2 receptor are important for NPY binding activity.     

Y1 and Y2 receptors for neuropeptide Y

By using monoiodinated radioligands of both intact neuropeptide Y (NPY) and of a long C-terminal fragment, NPY13-36, two subtypes of binding sites, which differ in affinity and specificity, have been characterized. The Y1 type of binding site, characterized on a human neuroblastoma cell line, MC-IXC, and a rat pheochromocytoma cell line, PC-12, binds NPY with a dissociation constant (Kd) of a few nanomolar but does not bind NPY13-36. The Y2 type of binding site, characterized on porcine hippocampal membranes and on another human neuroblastoma cell line, SMS-MSN, is of higher affinity and binds both NPY and NPY13-36. None of the binding sites distinguish between NPY and the homologous peptide YY (PYY). It is concluded that NPY/PYY-binding sites occur in two subtypes which may represent two types of physiological receptors.     

Identification of cultured cells selectively expressing Y1-, Y2-, or Y3-type receptors for neuropeptide Y/peptide YY.

Neuropeptide Y (NPY) and peptide YY (PYY) are homologous 36 amino acid amidated peptides that often, but not always, exert similar actions and binding profiles. The present study of cultured cells confirms that both peptides as well as radioiodinated analogs, i.e. 125I-Bolton-Hunter-NPY (125I-BH-NPY) and 125I-peptide YY (125I-PYY), show high affinity to binding sites/receptors of the previously proposed Y1- and Y2-subtypes, selectively expressed by the human neuroblastoma cell lines, SK-N-MC and SK-N-BE(2), respectively. In contrast, bovine adrenal chromaffin cells did not bind 125I-PYY, while displaying high affinity 125I-BH-NPY sites, and may therefore represent a cell type expressing a recently proposed Y3-type of (NPY-preferring) receptors. Several non-labeled fragments/analogs have been used in displacement experiments to further characterize the structural requirements for Y1-, Y2-, and Y3-type binding. In every instance, specific binding was reduced by addition of 5'-guanylylimidodiphosphate [Gpp(NH)p], indicating that the three receptor subtypes belong to the G-protein-coupled superfamily of receptors. Moreover, in both neuroblastoma cell lines, the peptides elicited, with appropriate orders of potency, reduction of forskolin-stimulated adenosine 3',5'-cyclic monophosphate (cAMP) accumulation. Finally, NPY-evoked 45Ca2+ influx was observed in SK-N-MC and in chromaffin cells. A common dual coupling mechanism of NPY/PYY receptors, i.e. to reduction of cAMP and to Ca2+ elevation, is therefore suggested to exist, although both phenomena could not be demonstrated in every cell type.     

The control of bone remodeling by neuropeptide Y receptors

An important role for the neuropeptide Y receptor system in the regulation of bone formation was recently revealed with a significant elevation in trabecular bone formation and bone volume following germline or hypothalamus-specific deletion of neuropeptide Y2 receptors in mice. Subsequent studies have now demonstrated that this central pathway is distinct from that of the other centrally regulated bone formation pathway mediated by leptin. This review discusses these recent findings and outlines how these new pathways could translate into potential novel targets for the treatment of bone disease.     

Role of neuropeptide Y Y(2) receptors in modulation of cardiac parasympathetic neurotransmission.

The aim of the study was to clarify the role of the Y(2) receptor in regulation of vagal control of the heart, using Y(2)((-/-)) receptor-knockout mice. Adult Y(2)((+/+),(-/-)) mice (50% C57BL/6-50% 129/SvJ background) were anaesthetised and artificially ventilated. Arterial blood pressure and pulse interval was recorded and both vagus nerves were cut. The cardiac end of the right vagus nerve was stimulated supra-maximally every 30 s (7 V, 2-2.5 Hz, 5 s). Neuropeptide Y (NPY) and a Y(2) receptor agonist, N-acetyl [Leu(28, 31)]NPY 24-36, were injected intravenously in both groups of mice. N-acetyl [Leu(28, 31)] NPY 24-36 was also administered to control mice in the presence of a Y(2) receptor antagonist, BIIE0246. Stimulation of the vagus nerve increased pulse interval (PI) by approximately 100 ms. NPY and N-acetyl [Leu(28, 31)] NPY 24-36 attenuated the increase in PI evoked by vagal stimulation in control mice only. The attenuation was reduced in the presence of BIIE0246. The results presented here show in Y(2)((-/-)) receptor-knockout mice that NPY and N-acetyl [Leu(28, 31)] NPY 24-36 have no effect on PI evoked by vagal stimulation. These findings demonstrate that NPY attenuates parasympathetic activity to the heart via the Y(2) receptor.     

A Y2 receptor mimetic aptamer directed against neuropeptide Y.

Neuropeptide Y (NPY) is a 36-amino acid neuropeptide that exerts its activity by at least five different receptor subtypes that belong to the family of G-protein-coupled receptors. We isolated an aptamer directed against NPY from a nuclease-resistant RNA library. Mapping experiments with N-terminally, C-terminally, and centrally truncated analogues of NPY revealed that the aptamer recognizes the C terminus of NPY. Individual replacement of the four arginine residues at positions 19, 25, 33, and 35 by l-alanine showed that arginine 33 is essential for binding. The aptamer does not recognize pancreatic polypeptide, a highly homologous Y4 receptor-specific peptide of the gut. Furthermore, the affinity of the aptamer to the Y5 receptor-selective agonist [Ala(31),Aib(32)]NPY and the Y1/Y5 receptor-binding peptide [Leu(31),Pro(34)]NPY was considerably reduced, whereas Y2 receptor-specific NPY mutants were bound well by the aptamer. Accordingly, the NPY epitope was recognized by the Y2 receptor, and the aptamer was highly similar. This Y2 receptor mimicking effect was further confirmed by competition binding studies. Whereas the aptamer competed with the Y2 receptor for binding of [(3)H]NPY with high affinity, a low affinity displacement of [(3)H]NPY was observed at the Y1 and the Y5 receptors. Consequently, competition at the Y2 receptor occurred with a considerably lower K(i) value compared with the Y1 and Y5 receptors. These results indicate that the aptamer mimics the binding of NPY to the Y2 receptor more closely than to the Y1 and Y5 receptors.     

Emerging functions of neuropeptide Y Y(2) receptors in the brain

The Y(2) receptor is the predominant neuropeptide Y (NPY) receptor subtype in the brain. Y(2) receptor mRNA is discretely distributed in the brain, including specific subregions of the hippocampus and the hypothalamus, and is largely consistent with the distribution of Y(2) receptor protein demonstrated by radioligand-binding methods. Y(2) receptor-mediated effects have been reported principally based on the observations using the C-terminal fragments of NPY. Recent studies indicate an involvement of the receptor in food intake, gastrointestinal motility, cardiovascular regulation, and neuronal excitability. Very recently, Y(2) receptor selective antagonist has been developed and Y(2) receptor-deficient animals have been created. These new pharmacological tools will help to clarify the roles of this receptor in brain functions.     

Distribution of neuropeptide Y Y1 and Y2 receptors in the postmortem human heart

In the present study, we present for the first time the presence and distribution of neuropeptide Y (NPY) receptors Y1 and Y2 in the human postmortem heart using specific antibodies raised against extracellular parts of the receptors. A more intensive staining against the Y2 than against the Y1 receptors was detected on both atrial and ventricular cardiomyocytes. Immunoreactivity against both receptors was identified on both conducting fibers and cardiac nerves. More vessels stained positively for the Y2 than for the Y1 receptor, but the Y1 receptors were more abundant in subendocardial than subepicardial vessels of the left ventricular wall.     

Centrally administered neuropeptide Y delays gastric emptying via Y2 receptors in rats

It has been shown that centrally administered neuropeptide Y (NPY) delays gastric emptying. To determine the receptor subtypes of NPY mediating the inhibitory effects on gastric emptying, effects of intracerebroventricular injection of NPY, [Leu31,Pro34]NPY (a Y1 agonist) and NPY-(3-36) (a Y2 agonist) on solid gastric emptying and postprandial antropyloric motility were studied in conscious rats. Intracerebroventricular injection of NPY and NPY-(3-36), but not [Leu31,Pro34] NPY, delayed solid gastric emptying in a dose-dependent manner (0.03-3 nmol). After the feeding (40 min), contractions with low frequency and high amplitude of the antrum were frequently observed, and the peak contraction of the antrum occurred most often 3-6 s before the peak contraction of the pylorus. Intracerebroventricular injection of NPY and NPY-(3-36) (3 nmol), but not [Leu31,Pro34]NPY, significantly reduced antral contractions and the number of antropyloric coordination events. It is suggested that centrally administered NPY impairs postprandial antral contractions and antropyloric coordination via Y2 receptors, resulting in delayed gastric emptying.     

Y2 receptors for neuropeptide Y in the nucleus of the solitary tract mediate depressor responses.

In anesthetized, spontaneously breathing rats, microinjections of selective agonists of neuropeptide Y (NPY) receptor subtypes were made into the medial region of the caudal nucleus of the solitary tract (NTS) at the level of the area postrema. This region of the rat NTS exhibits very high densities of NPY binding sites. Microinjections of the long C-terminal NPY fragment, NPY(13-36), a selective agonist at Y2 receptors, into the caudal NTS elicited pronounced, dose-related reductions in blood pressure and respiratory minute volume. Moreover, the specific pattern of cardiorespiratory responses elicited by NPY(13-36) was remarkably similar, over approximately the same dosage range, with the cardiorespiratory response pattern elicited by intact NPY. In contrast to the potent NTS-mediated responses evoked by NPY(13-36), similar microinjections conducted with either NPY(26-36), an inactive C-terminal NPY fragment, or [Leu31,Pro34]NPY, a NPY analog with specific agonist properties at Y1 receptors, into the same caudal NTS sites did not appreciably affect cardiorespiratory parameters even at 10-20-fold higher dosages. The present results with selective agonists for NPY receptor subtypes suggest that the depressor responses and reductions in minute volume elicited by microinjections of intact NPY and NPY(13-36) were mediated by Y2 receptors in the caudal NTS, likely distributed at presynaptic sites in the medial region of the subpostremal NTS.     

Succinate and phenylsuccinate as modifiers of sulfhydryl groups of inner mitochondrial membrane protein. Study by EPR

Paramagnetic labels specific for sulfhydryl (SH) groups have been used to study the conformational changes of the inner mitochondrial membrane. The EPR spectra of the SH-groups spin-labeled with maleimide or iodoacetamide show the existence of two populations of sulfhydryl groups, differing in their mobility (one weakly, the other strongly immobilized). The incubation with succinate or phenylsuccinate decreased the binding of these labels of the weakly immobilized sites while the number of total SH groups was the same before and after the incubation. These results suggest that succinate or phenylsuccinate induce a reversible change in protein conformation or in protein arrangement within the inner mitochondrial membrane. This change is concomitant to the protein movement between inner membrane and perimembranal space induced by either of these two molecules.     

A novel cyclic analog of neuropeptide Y specific for the Y2 receptor.

The low-molecular-mass, cyclic analog of neuropeptide Y, [Ahx5-24, gamma-Glu2-epsilon-Lys30] NPY (YESK-Ahx-RHYINKITRQRY; Ahx, 6-aminohexanoic acid; NPY, neuropeptide Y), was synthesized and investigated for receptor binding, inhibition of forskolin-stimulated cAMP accumulation, inhibition of electrically stimulated rat vas deferens contractions and ability to increase blood pressure. Like the linear peptide [Ahx5-24] NPY (YPSK-Ahx-RHYINLITRQRY), the more rigid, cyclic analog showed good correlation between receptor binding to rabbit kidney membranes and biological activity in the vas deferens assay. Binding of this peptide to a new Y2-receptor-expressing cell line was slightly reduced, compared to the linear peptide [Ahx5-24] NPY, however inhibition of cAMP accumulation was even more efficient. Unlike the linear peptide [Ahx5-24] NPY, the cyclic analog did not induce a blood pressure increase in rats. Reduced binding to Y1 receptor-expressing SK-N-MC cells, as well as the loss of capability of signal transduction, suggest that only Y2-mediated activity is preserved after cyclization. The selectivity of the cyclic compound for Y2 subtypes of NPY receptors with respect to inhibition of cAMP accumulation is more than fortyfold increased, as compared to the linear NPY-(13-36) peptide, which has been used to determine Y2 selectivity so far.     

Pharmacological characterization of cloned chicken neuropeptide Y receptors Y1 and Y5

The neuropeptide Y (NPY) receptor subtypes Y1 and Y5 are involved in the regulation of feeding and several other physiological functions in mammals. To increase our understanding of the origin and mechanisms of the complex NPY system, we report here the cloning and pharmacological characterization of receptors Y1 and Y5 in the first non-mammal, chicken (Gallus gallus). The receptors display 80-83% and 64-72% amino acid sequence identity, respectively, with their mammalian orthologues. The three endogenous ligands NPY, peptide YY (PYY) and pancreatic polypeptide (PP) have similar affinities as in mammals, i.e. NPY and PYY have subnanomolar affinity for both receptors whereas chicken PP bound with nanomolar affinity to Y5 but not to Y1. A notable difference to mammalian receptor subtypes is that the Y1 antagonist SR120819A does not bind chicken Y1, whereas BIBP3226 does. The Y5 antagonist CGP71863A binds to the chicken Y5 receptor. Anatomically, both Y1 and Y5 have high mRNA expression levels in the infundibular nucleus which is the homologous structure of the hypothalamic arcuate nucleus in mammals. These results suggest that some of the selective Y1 and Y5 antagonists developed in mammals can be used to study appetite regulation in chicken.     

Internalization studies of chimeric neuropeptide Y receptors Y1 and Y2 suggest complex interactions between cytoplasmic domains

Agonist stimulation readily internalizes neuropeptide Y receptor Y1 while there are contradictory results for the Y2 receptor. In order to explore putative functional differences between the Y1 and Y2 receptors we generated reciprocal chimeras by swapping the third intracellular loop, the carboxy terminus or both between human Y1 and Y2. Internalization was studied in a quantitative radioligand binding assay with removal of surface-bound ligand in an acidic-wash procedure. The internalization assay revealed a lower degree of internalization as well as slower kinetics for the Y2 receptor. Generally, reciprocal exchange of receptor segments did not convey properties of the donor receptor but tended to enhance internalization. Surprisingly, insertion of the Y2 carboxy terminus into Y1 gave almost complete internalization (92%), rather than reduced internalization, while the insertion of both segments resulted in internalization equal to the native Y1 receptor. These findings were confirmed by fluorescence microscopy of immuno-stained receptors tagged with a C-terminal FLAG epitope. However, after exposure to high agonist concentrations (100 nM) Y2 was internalized. Studies of Y2 and the closely related Y7 receptor confirmed low internalization for Y2 from chicken and teleost fishes as well as Y7 from two teleosts. The conservation across species of low internalization at physiological concentrations suggests that this is an ancient feature and of vital importance for Y2 function. We propose that amino acid motifs in the third intracellular loop as well as the C terminus of both Y1 and Y2 are able to drive agonist-promoted internalization and that there may be constraining motifs in the Y2 receptor.     

The antiparallel pancreatic polypeptide fold in the binding of neuropeptide Y to Y1 and Y2 receptors

Neuropeptide Y (NPY) belongs to the pancreatic polypeptide fold (PP-fold) family of regulatory peptides. Analysis of circular dicroic spectra of NPY showed that it has a high degree of secondary structure in aqueous solution which is in agreement with the globular, folded crystal structure of PP. Using three different approaches with synthetic peptides, we have probed the importance of the PP-fold structure in the interaction of NPY with two types of binding sites, Y1 and Y2 receptors. First, stepwise construction of the NPY molecule from the C-terminal amidated end, showed that although C-terminal fragments encompassing most of the long alpha-helix reacted reasonably well with the Y2 receptor, both Y1 and Y2 receptors required the presence of both ends of the PP-fold for full activity. Second, perturbation of the PP-fold by substitution with a helix-breaking proline residue, resulted in the loss of recognition of the N-terminal segment of the molecule by both types of receptors. Finally, a hybrid analog was constructed in which the essential, but by itself inactive, C-terminal segment of NPY was joined with the PP-fold motif of PP. This segment of PP is only 43% homologous to the similar motif in NPY, and most of the common residues cluster in the hydrophobic core of the fold. Nevertheless, the hybrid analog reacted with almost full potency on the Y2 receptors. It is concluded that the antiparallel PP-fold is of structural importance for the receptor binding of NPY, and that its main function is to present the combined C- and N-terminal segments of the molecule to the receptors.     

Modeling of neuropeptide receptors Y1, Y4, Y5, and docking studies with neuropeptide antagonist

Neuropeptide Y (NPY), receptors belong to the G-protein coupled receptor superfamily. NPY mediates several physiological responses, such as blood pressure, food intake, sedation. These actions of NPY are mediated by six receptor subtypes denoted as Y1-Y5 and y6. Modeling of receptor subtypes and binding site identification is an important step in developing new therapeutic agents. We have attempted to model the three NPY receptor types, Y1, Y4, and Y5 using homology modeling and threading methods. The models are consistent with previously reported experimental evidence. To understand the interaction and selectivity of NPY analogues with different neuropeptide receptors, docking studies of two neuropeptide analogues (BVD10 and BVD15) with receptors Y1 and Y4 were carried out. Results of the docking studies indicated that the interaction of ligands BVD10 and BVD15 with Y1 and Y4 receptors are different. These results were evaluated for selectivity of peptide analogues BVD10 and BVD15 towards the receptors.     

Molecular characterization of the human neuropeptide Y Y2-receptor.

Five neuropeptide Y receptors, the Y1-, Y2-, Y4-, Y5- and y6-subtypes, have been cloned, which belong to the rhodopsin-like G-protein-coupled, 7-transmembrane helix-spanning receptors and bind the 36-mer neuromodulator NPY (neuropeptide Y) with nanomolar affinity. In this study, the Y2-receptor subtype expressed in a human neuroblastoma cell line (SMS-KAN) and in transfected Chinese hamster ovary cells (CHO-hY2) was characterized on the protein level by using photoaffinity labeling and antireceptor antibodies. Two photoactivatable analogues of NPY were synthesized, in which a Tyr residue was substituted by the photoreactive amino acid 4-(3-trifluoromethyl)-3H-diazirin-3-ylphenylalanine ((Tmd)Phe), [Nalpha-biotinyl-Ahx2,(Tmd)Phe36]NPY (Tmd36), and the Y2-receptor subtype selective [Nalpha-biotinyl-Ahx2,Ahx5-24,(Tmd)Phe27]N PY (Tmd27). Both analogues were labeled with [3H]succinimidyl-propionate at Lys4 and bind to the Y2-receptor with affinity similar to that of the native ligand. A synthetic fragment of the second (E2) extracellular loop was used to generate subtype selective antireceptor antibodies against the Y2-receptor. Photoaffinity labeling of the receptor followed by SDS-PAGE and detection of bound radioactivity and SDS-PAGE of solubilized receptors and subsequent Western blotting revealed the same molecular masses. Two proteins correspondingly have been detected for each cell line with molecular masses of 58 +/- 4 and 50 +/- 4 kDa, respectively.     

Structure–activity relationships of neuropeptide Y analogues with respect to Y1 and Y2 receptors

Secondary structure investigations, affinities, and activities of neuropeptide Y analogues with respect to the Y₁ and the Y₂ receptor are reviewed. The results are discussed with respect to the different prerequisites for affinities to both receptor subtypes. The results from a systematic scanning of the hormone using L -alanine and from a large variety of discontinuous and cyclic analogs suggest that two different conformations of neuropeptide Y are adopted at the Y₁ and Y₂ receptors. Whereas a C-terminal turn structure is suggested for Y₁ receptor affinity, an α-helical conformation of the C-terminus is afforded for good binding to the Y₂ receptor. © 1994 John Wiley & Sons, Inc.