Fluorescent Labelled Analogues of Neuropeptide Y for the Characterization of Cells Expressing NPY Receptor Subtypes

Abstract

Porcine neuropeptide Y (NPY), a 36 amino acid hormone of the pancreatic polypeptide family, and subtype selective analogues have been synthesized by solid phase peptide synthesis. The peptides were labelled with Cy3^TM, a commercially available fluorescent marker based on a cyanine dye, by solid phase strategy. During the cleavage α partial fragmentation of the fluorescent marker occurred. This has been investigated by means of HPLC and electrospray mass spectrometry. The labelled analogues of NPY showed high affinity to the NPY receptor subtypes Y₁ and Y₂. Thus, Cy3-NPY. Y₁-selective Cy3-[Pro³⁴] NPY and Y₂ selective Cy3-[Ahx^5–24] NPY were used to label SK-N-MC- and SMS-KAN-cells, which are stably expressing the Y₁-(SK-N-MC) and the Y₂-receptor subtype (SMS-KAN). The binding of the labelled analogues to the receptors was reversible and specific. The photoactivatable analogue, [(Tmd)Phe²⁷] NPY, which showed high affinity to both receptor subtypes was labelled with Cy3 in solution. Whereas the fluorescent labelling of the cells with analogues without photoactivatable amino acid was reversible, successful photocrosslinking could be investigated by the irreversible staining of the cells using Cy3-[(Tmd)Phe²⁷] NPY. These subtype selective analogues are exciting tools to trace receptors in tissues and to identify the pharmacologically characterized subtypes without radioactivity.     

Novel analogues of neuropeptide Y with a preference for the Y1-receptor.

Neuropeptide Y (NPY) is one of the most abundant neuropeptides in the mammalian brain and acts in humans via at least three receptor subtypes: Y1, Y2, and Y5. Whereas selective agonists and antagonists are known for the Y2- and Y5-receptors, the Y1-receptor still lacks a highly selective agonist. This work presents the first NPY-based analogues with Y1-receptor preference and agonistic properties. Furthermore, the importance of specific amino acids of NPY for binding to the Y-receptor subtypes is presented. Amongst the analogues tested, [Phe7,Pro34]pNPY (where pNPY is porcine neuropeptide Y) showed the most significant Y1-receptor preference (> 1 : 3000-fold), with subnanomolar affinity to the Y1-receptor, and Ki values of approximately 30 nM for the Y2- and Y5-subtype, respectively. Variations of position 6, especially [Arg6,Pro34]pNPY and variations within positions 20-23 of NPY were found to result in further analogues with significant Y1-receptor preference (1 : 400-1 : 2000). In contrast, cyclo S-S [Cys20,Cys24]pNPY was found to be a highly selective ligand at the Y2-receptor, binding only threefold less efficiently than NPY. Analogues containing variations of positions 31 and 32 showed highly reduced affinity to the Y1-receptor, while binding to the Y5-receptor was affected less. Inhibition of cAMP-accumulation of selected peptides with replacements within position 20-23 of NPY showed preserved agonistic properties. The NPY analogues tested give insights into ligand-receptor interaction of NPY at the Y1-, Y2- and Y5-receptor and contribute to our understanding of subtype selectivity. Furthermore, the Y1-receptor-preferring peptides are novel tools that will provide insight into the physiological role of the Y1-receptor.     

Cardiorespiratory responses to intracerebroventricular injection of neuropeptide Y in anaesthetised dogs.

Cardiovascular and respiratory effects of intracerebroventricular (icv) administration of neuropeptide Y (NPY) and separate, preferential agonists for NPY Y1 and Y2 receptors were observed in anaesthetised dogs. Central injections of NPY resulted in significant cardiac slowing and decreases in arterial pressure. These cardiovascular effects were blocked by central injection of the NPY Y1- preferring antagonist 1229U91. Central injection of NPY did not have a significant effect on ventilation, but the NPY Y1 antagonist 1229U91 administered alone caused a significant increase in ventilation. The NPY Y1-receptor agonist [Leu31Pro34] NPY significantly decreased ventilation while the NPY Y2 receptor agonist N-acetyl [Leu28Leu31] NPY 24--36 significantly increased it. A similar inverse relationship was seen with respect to blood pressure, with the NPY Y1-receptor agonist [Leu31Pro34] NPY significantly decreasing blood pressure, while the NPY Y2 receptor agonist N-acetyl [Leu28Leu31] NPY 24-36 significantly increased it. These findings suggest a role for NPY Y1 receptors in pathways mediating decreases in ventilation and blood pressure, and for NPY Y2 receptors in those mediating increased ventilation and blood pressure.     

2-36[K4,RYYSA(19-23)]PP a novel Y5-receptor preferring ligand with strong stimulatory effect on food intake

Members of the neuropeptide Y (NPY) family regulate many physiological processes via interaction with at least four functional, pharmacologically distinct Y-receptors. However, selective antagonists developed for several subtypes have not been useful in defining particular Y-receptor functions in vivo. To identify critical residues within members of the NPY family required for Y-receptor subtype-selectivity we have determined the contribution of each residue within NPY to receptor binding by replacing them with L-alanine. In a second study, chimeric peptides where single or stretches of residues were interchanged between members of the NPY family were generated and tested in radioligand binding studies. Overall, substituted alanine analogues exhibited similar orders of affinities at each Y-receptor subtype with no obvious subtype-selectivity. Residues of particular interest are Leu30 which exhibited selectivity for the Y4-receptor, whereas Asp16 does not appear to play any role in ligand binding. Several chimeric peptides, e.g., [K4]pancreatic polypeptide ([K4]PP) and [RYYSA(19-23)]PP clearly showed higher affinity at the Y4 and Y5 subtypes compared to the Y1 and Y2 subtypes. In addition, the transfer of a proline residue from position 14 to 13 in peptide YY decreases its affinity at the Y1-, Y4- and Y5-receptors but is unchanged at the Y2 subtype. Combining these results, and with the help of molecular modelling, second generation chimeras were designed. The most significant improvement was achieved in chimera 2-36[K4,RYYSA(19-23)]PP where the affinity for the Y5 subtype increased by ninefold over that from NPY. Several of these compounds were also tested for their ability to stimulate food intake in a rat model. Interestingly, again 2-36[K4,RYYSA(19-23)]PP showed the most dramatic effect with a major increase on food intake over a range of doses compared to NPY suggesting a possible synergistic effect of several Y-receptors on feeding behaviour.     

Comparison of antibodies directed against receptor segments of NPY-receptors

The Y1-, Y2-, Y4- and Y5-receptor, which belong to the rhodopsin-like G-protein coupled, 7 transmembrane helix spanning receptors, bind the 36-mer neuromodulator NPY (neuropeptide Y) with nanomolar affinity. Synthetic fragments of the second (E2) and third (E3) extracellular loop were used to generate subtype selective anti-receptor antibodies against the Y-receptors. As investigated on intact receptors by ELISA and on solubilized receptors by SDS-PAGE and subsequent Western blotting, subtype selectivity was only partly achieved. Nevertheless, selectivity can be obtained by using several antisera in combination. These antibodies represent tools for molecular mass determination, receptor purification by affinity chromatography with antibody-columns and receptor localization studies.     

Design of the Y1-receptor-selective cyclic peptide based on the C-terminal sequence of neuropeptide Y.

We designed four cyclic peptides which are mimics of the C-terminal region of human neuropeptide Y (NPY) on the basis of the structural model of NPY. One of these cyclic peptides, c[D-Cys29-L-Cys34]NPY Ac-29-36 (YM-42454), exhibited significantly higher affinity for the Y1-receptor than the corresponding C-terminal linear fragment, NPY Ac-28-36. Interestingly, YM-42454 showed binding affinity for the Y1-receptor in spite of the lack of the N-terminal sequence of NPY, whereas it did not show any binding affinity for the Y2-receptor. This conformationally restricted Y1-selective peptide would provide some insights into the bioactive conformation of the C-terminal region of NPY.     

Physiological role of neuropeptide Y in the regulation of the ascending phase of the peristaltic reflex

The physiological role of neuropeptide Y (NPY) and of specific NPY receptors in regulating the intestinal peristaltic reflex was examined in three-compartment flat-sheet preparations of rat colon. Graded muscle stretch or mucosal stimulation applied to the central compartment inhibited NPY release in the orad compartment where ascending contraction was measured. NPY and the Y1-receptor agonist [Leu31, Pro34]NPY inhibited, whereas the selective Y1-receptor antagonist BIBP 3226 augmented ascending contraction and substance P (SP) release in the orad compartment induced by muscle stretch or mucosal stimulation. Neither agonist nor antagonist had any effect on descending relaxation or VIP release in the caudad compartment. The Y2-receptor agonist NPY13-36 and antagonist BIIE 0246 had no effect on peptide release or mechanical response. The results indicate that suppression of a tonic inhibitory influence of NPY neurons on excitatory neurotransmitter release contributes substantially to the orad contractile phase of the peristaltic reflex. The effect of NPY on neurotransmitter release is mediated by Y1 receptors.     

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.     

Ala31-Aib32: identification of the key motif for high affinity and selectivity of neuropeptide Y at the Y5-receptor

The turn-inducing sequence Ala-Aib introduced into positions 31 and 32 of neuropeptide Y (NPY) and its analogues has been identified as the key structure for Y(5)-receptor selectivity. Analogues of NPY and PP/NPY chimera containing the motif Ala-Aib were prepared; these peptides turned out to be selective for the Y(5)-receptor. The affinity of the NPY-based peptides was in the range of 6-150 nM, while the affinity of three (Ala-Aib)-containing PP/NPY chimera was in the range of 0.2-0.9 nM. The circular dichroism spectra of the Aib analogues in aqueous solution were all characteristic of an alpha helix; however, they had different intensities of the two negative bands at 220 and 208 nm. Affinity and selectivity for the Y(5)-receptor were correlated with the ratio of the ellipticity at 220 nm versus the one at 208 nm (R), which indicates the presence of a pronounced helix (R > 1) versus a less stabile one (R < 1). When R was in the range 0.74-0.96, the affinity at the Y(5)-receptor was in the range >5 nM, while there was complete loss of affinity at the Y(4)-receptor. R > 1.15 was associated with very high affinity at the Y(5)-receptor and weak affinity at the Y(4)-receptor. These results suggest that the selectivity of the Ala(31)-Aib(32) motif for the Y(5)-receptor derives from a specific conformation that must be correlated with the bioactive conformation of NPY at this subtype.     

Neuropeptide Y 16-36 inhibits mucociliary activity but does not affect blood flow in the rabbit maxillary sinus in vivo.

Recent investigations have shown neuropeptide Y (NPY) to be present in the rabbit maxillary sinus, and NPY is known to be released upon sympathetic nerve stimulation. To study, in vivo, the effect on mucociliary activity and blood flow, NPY 1-36 and some of its analogues were injected intra-arterially. The effects of the Y1/Y2 agonist NPY 1-36 was compared with the ones of the Y2 agonist NPY 16-36, the Y1-agonist [Leu31,Pro34]NPY and the Y1/Y2 agonist peptide YY. Mucociliary response was recorded photoelectrically and expressed as a percentage of the basal mucociliary activity immediately prior to challenge. The effect on blood flow was measured with laser Doppler flowmetry and expressed as a percentage of the mean blood flow during the 60 s preceding challenge. NPY 1-36 and NPY 16-36 both reduced mucociliary activity dose-dependently at equimolar dosages (0.024-1.2 nmol/kg). The greatest effect was seen after the highest dosage tested. NPY 1-36 reduced mucociliary activity by 14.6 +/- 1.8%, and NPY 16-36 by 13.2 +/- 1.4%. At the highest dosage tested the Y1 receptor agonist [Leu31,Pro34]NPY did not significantly reduce mucociliary activity, whereas PYY reduced mucociliary activity by 15.0 +/- 1.8%. Injections of NPY 16-36 had no effect on blood flow whereas NPY 1-36, [Leu31,Pro34]NPY and PYY all reduced blood flow dose-dependently. Maximal decrease was seen at the highest dosage tested and was 47.1 +/- 5.4%, 70.4 +/- 7.4% and 58.2 +/- 8.4%, respectively. These findings suggest the mucociliary effects to be mediated via Y2 receptors whereas blood flow is regulated via Y1 receptors.     

Neuropeptide Y receptor in bovine hippocampus is a Y2 receptor.

[125I]NPY bound to a single class of saturable binding sites on bovine hippocampus membranes with a KD of 0.1 mM and Bmax of 165 fmol/mg of protein. The rank order of potency of NPY fragments and other structurally related peptides to inhibit [125I]NPY binding was: PYY greater than or equal to NPY much greater than BPP greater than or equal to APP and NPY greater than NPY-(13-36) greater than NPY-(18-36) greater than or equal to NPY-(20-36) much greater than NPY-(26-36) greater than NPY-(free acid). The identity of the NPY binding site was investigated by affinity labeling. Gel electrophoresis followed by autoradiography revealed a band with a mol mass of 50 kDa. Unlabeled NPY or PYY, but not BPP, HPP and APP, inhibited labeling of [125I]NPY to the 50 kDa protein band. Moreover, labeling was inhibited by NPY greater than NPY-(18-36) greater than or equal to NPY-(13-36) greater than or equal to NPY-(20-36) greater than NPY-(26-36) greater than NPY-(free acid). The binding of [125I]NPY and the intensity of the cross-linked band were reduced in parallel by increasing concentrations of unlabeled NPY (IC50 = 0.7 nM and 0.6 mM, respectively). These studies demonstrate that bovine hippocampal membranes contain a 50 kDa [125I]NPY binding site that has the ligand specificity characteristic of the Y2 receptor subtype.     

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.     

Melanotropin release inhibiting activity of neuropeptide Y: structure-activity relationships

We have recently shown that the release of alpha-MSH by the intermediate lobe of the frog pituitary is inhibited by neuropeptide Y (NPY). Using the perifusion technique, we have compared in the present study, the alpha-MSH release inhibiting activities of NPY, various NPY short chain analogues and two other members of the pancreatic polypeptide family, peptide YY (PYY) and avian pancreatic polypeptide (APP). The order of biological potency was NPY greater than NPY[2-36] greater than NPY[16-36] greater than NPY[25-36] greater than NPY[1-15]. Among the two pancreatic polypeptides tested, PYY appeared to be almost as potent as NPY while APP was 6 times less active than NPY. Neither NPY[1-15] nor NPY[16-36] could antagonize the inhibitory effect of NPY on alpha-MSH release. The structure-activity relationship study suggests that the bioactive determinant of NPY is located in the C-terminal part of the molecule.     

Existence of both neuropeptide Y, Y1 and Y2 receptors in pig spleen: evidence using subtype-selective antagonists in vivo

The effects of the first selective, non-peptide, NPY Y2 receptor antagonist (S)-N2-[[1-[2-[4-[(R,S)-5,11-dihydro-6(6h)-oxodibenz[b,e]azepin-11-yl]-1-piperazinyl]-2-oxoethyl]cyclopentyl]acetyl]-N-[2-[1,2-dihydro-3,5 (4H)-dioxo-1,2-diphenyl-3H-1,2,4-triazol-4-yl]ethyl]-argininamid (BIIE0246) were studied on splenic vascular responses evoked in the pig in vivo. BIIE0246 abolished the splenic vasoconstrictor response to the NPY Y2 receptor agonist N-acetyl[Leu25Leu31]NPY(24-36), but did not affect the response to the NPY Y1 receptor agonist [Leu31Pro34]NPY, which in turn was abolished by the selective NPY Y1 receptor antagonist (2R)-5-([amino(imino)methyl]amino)-2-[(2,2-diphenylacetyl)amino]-N-[(IR)-1-(4-hydroxyphenyl)ethyl]-pentanamide (H 409/22). Furthermore, the PYY-evoked splenic vasoconstrictor response was partially antagonized by BIIE0246 and subsequently almost abolished by the addition of H 409/22. It is concluded that BIIE0246 exerts selective (vs the NPY Y1 receptor) NPY Y2 receptor antagonism, and thus represents an interesting tool for classification of NPY receptors, in vivo. In addition, evidence for NPY Y2 receptor mediated vasoconstriction was presented. Furthermore, both NPY Y1 and Y2 receptors are involved in the splenic vasoconstrictor response to PYY.     

Novel cell line selectively expressing neuropeptide Y-Y2 receptors

Neuropeptide Y (NPY) recognition by the human neuroblastoma cell lines SiMa, Kelly, SH-SY5Y, CHP-234, and MHH-NB-11 was analyzed in radioactive binding assays using tritiated NPY. For the cell lines CHP-234 and MHH-NB-11 binding of [3H]propionyl-NPY was observed with Kd-values of 0.64 +/- 0.07 nM and 0.53 +/- 0.12 nM, respectively, determined by saturation analysis with non-linear regression. The receptor subtype was determined by competition analysis using the subtype selective NPY analogues [Leu31, Pro34]-NPY (NPY-Y1, NPY-Y5), [Ahx(5-24)]-NPY (NPY-Y2), [Ala31, Aib32]-NPY (NPY-Y5), NPY [3-36] (NPY-Y2, NPY-Y5), and NPY [13-36] (NPY-Y2). Both cell lines, CHP-234 and MHH-NB-11, the latter one being characterized for NPY receptors for the first time, showed exclusive expression of NPY-Y2 receptors. In both cell lines binding of NPY induced signal transduction, which was monitored as reduction of forskolin-induced cAMP production in an ELISA.     

Modulation of intracellular calcium changes and glutamate release by neuropeptide Y1 and Y2 receptors in the rat hippocampus: differential effects in CA1, CA3 and dentate gyrus

In the present work, we investigated the role of pre- and post-synaptic neuropeptide Y1 (NPY1) and Y2 receptors on the calcium responses and on glutamate release in the rat hippocampus. In cultured hippocampal neurones, we observed that only NPY1 receptors are involved in the modulation of intracellular free calcium concentration ([Ca(2+)](i)). In 88% of the neurones analysed, the increase in the [Ca(2+)](i), in response to depolarization with 50 mM KCl, was inhibited by 1 microM [Leu31,Pro34]NPY, whereas 300 nM NPY13-36 was without effect. However, studies with hippocampal synaptosomes showed that both NPY1 and Y2 receptors can modulate the [Ca(2+)](i) and glutamate release. The pharmacological characterization of the NPY-induced inhibition of glutamate release indicated that Y2 receptors play a predominant role, both in the modulation of Ca(2+)-dependent and -independent glutamate release. However, we could distinguish between Y1 and Y2 receptors by using [Leu31,Pro34]NPY and NPY13-36. Active pre-synaptic Y1 receptors are present in the dentate gyrus (DG) as well as in the CA3 subregion, but its activity was not revealed by using the endogenous agonist, NPY. Concerning the Y2 receptors, they are present in the three subregions (CA1, CA3 and DG) and were activated by either NPY13-36 or NPY. The present data support a predominant role for NPY2 receptors in mediating NPY-induced inhibition of glutamate release in the hippocampus, but the physiological relevance of the presently described DG and CA3 pre-synaptic NPY1 receptors remains to be clarified.     

Novel chemically modified analogues of neuropeptide Y for tumor targeting

The successful use of peptides as potential radiopharmaceuticals essentially requires the modification of the bioactive peptide hormones to introduce chelators for radiolabeling. In this study, four Y 1/Y 2 receptor-selective NPY analogues with different receptor subtype specificities have been investigated. For in vitro studies, the cold metal surrogate was used. Gallium and indium complexes were introduced by using 1,4,7,10-tetraazacyclododecane-1,4,7,10-tetraacetic acid as bifunctional chelator. The peptides were synthesized by solid-phase peptide synthesis (SPPS), the chelator was coupled either at the N-terminus or at the N(epsilon) side chain of Lys(4) of the resin-bound peptide, and the labeling was performed in solution after cleavage. Competitive binding assays showed high binding affinity of the receptor-selective analogues at NPY receptor expressing cells. To test internalization of the novel peptide analogues and the metabolic stability in human blood plasma, the corresponding 5(6)-carboxyfluorescein (CF) analogues were prepared and investigated. One of the most promising analogues, the Y 1-receptor selective [Lys(DOTA)(4), Phe(7), Pro(34)]NPY was labeled with (111)In and injected into nude mice that bear MCF-7 breast cancer xenografts, and biodistribution studies were performed. In vitro and in vivo studies suggest that receptor-selective analogues of NPY have promising characteristics for future applications in nuclear medicine for breast tumor diagnosis and therapy.     

Studies of the human, rat, and guinea pig Y4 receptors using neuropeptide Y analogues and two distinct radioligands

The neuropeptide Y-family receptor Y4 differs extensively between human and rat in sequence, receptor binding, and anatomical distribution. We have investigated the differences in binding profile between the cloned human, rat, and guinea pig Y4 receptors using NPY analogues with single amino acid replacements or deletion of the central portion. The most striking result was the increase in affinity for the rat receptor, but not for human or guinea pig, when amino acid 34 was replaced with proline; [Ahx(8-20),Pro(34)]NPY bound to the rat Y4 receptor with 20-fold higher affinity than [Ahx(8-20)]NPY. Also, the rat Y4 tolerates alanine in position 34 since p[Ala(34)]NPY bound with similar affinity as pNPY while the affinity for hY4 and gpY4 decreased about 50-fold. Alanine substitutions in position 33, 35, and 36 as well as the large loop-deletion, [Ahx(5-24)]NPY, reduced the binding affinity to all three receptors more than 100-fold. NPY and PYY competed with (125)I-hPP at Y4 receptors expressed in CHO cells according to a two-site model. This was investigated for gpY4 by saturation with either radiolabeled hPP or pPYY. The number of high-affinity binding-sites for (125)I-pPYY was about 60% of the receptors recognized by (125)I-hPP. Porcine [Ala(34)]NPY and [Ahx(8-20)]NPY bound to rY4 (but not to hY4 or gpY4) according to a two-site model. These results suggest that different full agonists can distinguish between different active conformations of the gpY4 receptor and that Y4 may display functional differences in vivo between human, guinea pig, and rat.     

Modeling of Neuropeptide Receptors Y1, Y4, Y5, and Docking Studies with Neuropeptide Antagonist Analogues: Implications for Selectivity

Abstract 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 Y(1)-Y(5) and y(6). 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.     

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.