Injection of neuropeptide W into paraventricular nucleus of hypothalamus increases food intake

Neuropeptide W (NPW) is an endogenous ligand for G protein-coupled receptor 7 (GPR7). There are two forms of the peptide, designated as neuropeptide W-23 (NPW23) and neuropeptide W-30 (NPW30). In the current study we found that intracerebroventricular administration of NPW23 increased c-Fos immunoreactivity (IR) in a variety of brain sites, many of which are involved in the regulation of feeding. In particular, we noted that c-Fos IR levels were increased in hypocretin-expressing neurons in the perifornical region of the lateral hypothalamus (LH). We then studied whether injection of NPW23 into the paraventricular nucleus of the hypothalamus (PVN) and the LH increased food intake over a 24-h time period. Intra-PVN injection of NPW23 at doses ranging from 0.1 to 3 nmol increased feeding for up to 4 h, and doses ranging from 0.3 to 3 nmol increased feeding for up to 24 h. In contrast, only the 3-nmol dose of NPW23 increased feeding after administration into the LH. Together, these data suggest a modulatory role for NPW in the control of food intake.     

Identification of a neuropeptide modified with bromine as an endogenous ligand for GPR7

We isolated a novel gene in a search of the Celera data base and found that it encoded a peptidic ligand for a G protein-coupled receptor, GPR7 (O'Dowd, B. F., Scheideler, M. A., Nguyen, T., Cheng, R., Rasmussen, J. S., Marchese, A., Zastawny, R., Heng, H. H., Tsui, L. C., Shi, X., Asa, S., Puy, L., and George, S. R. (1995) Genomics 28, 84-91; Lee, D. K., Nguyen, T., Porter, C. A., Cheng, R., George, S. R., and O'Dowd, B. F. (1999) Mol. Brain Res. 71, 96-103). The expression of this gene was detected in various tissues in rats, including the lymphoid organs, central nervous system, mammary glands, and uterus. GPR7 mRNA was mainly detected in the central nervous system and uterus. In situ hybridization showed that the gene encoding the GPR7 ligand was expressed in the hypothalamus and hippocampus of rats. To determine the molecular structure of the endogenous GPR7 ligand, we purified it from bovine hypothalamic tissue extracts on the basis of cAMP production-inhibitory activity to cells expressing GPR7. Through structural analyses, we found that the purified endogenous ligand was a peptide with 29 amino acid residues and that it was uniquely modified with bromine. We subsequently determined that the C-6 position of the indole moiety in the N-terminal Trp was brominated. We believe this is the first report on a neuropeptide modified with bromine and have hence named it neuropeptide B. In in vitro assays, bromination did not influence the binding of neuropeptide B to the receptor.     

Cardiovascular actions of central neuropeptide W in conscious rats

Neuropeptide W (NPW) is a novel hypothalamic peptide that activates the orphan G protein-coupled receptors, GPR7 and GPR8. Two endogenous molecular forms of NPW that consist of 23- and 30-amino acid residues were identified. Intracerebroventricular (i.c.v.) administration of NPW is known to suppress spontaneous-feeding at dark-phase and fasting-induced food intake and to decrease body weight and plasma growth hormone and to increase prolactin and corticosterone; however, little is known about its effect on other physiological functions. We examined the effects of i.c.v. administration of NPW30 (0.3 and 3 nmol) on the mean arterial pressure (MAP), heart rate (HR), and plasma norepinephrine and epinephrine in conscious rats. NPW30 (3 nmol) provoked increases in MAP (85.12+/-3.16 to 106.26+/-2.66 mm Hg) and HR (305.75+/-13.76 to 428.45+/-26.82 beats/min) and plasma norepinephrine (138.1+/-18.1 to 297.2+/-25.9 pg/ml) and epinephrine (194.6+/-21.4 to 274.6+/-22.7 pg/ml). Intravenously administered NPW30 (3 nmol) had no significant effects on MAP and HR. These results indicate that central NPW30 increases sympathetic nervous outflow and affects cardiovascular function.     

Molecular dynamics simulation of neuropeptide B and neuropeptide W in the dipalmitoylphosphatidylcholine membrane bilayer

GPR7 and GPR8 are recently deorphanized G-protein-coupled receptors that are implicated in the regulation of neuroendocrine function, feeding behavior, and energy homeostasis. Neuropeptide B (NPB) and neuropeptide W (NPW) are two membrane-bound hypothalamic peptides, which specifically antagonize GPR7 and GPR8. Despite years of research, an accurate estimation of structure and molecular recognition of these neuropeptide systems still remains elusive. Herein, we investigated the structure, orientation, and interaction of NPB and NPW in a dipalmitoylphosphatidylcholine bilayer using long-range molecular dynamics (MD) simulation. During 30-ns simulation, membrane-embedded helical axes of NPB and NPW tilted 30 and 15°, respectively, from the membrane normal in order to overcome possible hydrophobic mismatch with the lipid bilayer. The calculation of various structural parameters indicated that NPW is more rigid and compact as compared to NPB. Qualitatively, the peptides exhibited flexible N-terminal (residues 1–12) and rigid C-terminal α-helical parts (residues 13–21), confirming previous NMR data. A strong electrostatic attraction between C-termini and headgroup atoms caused translocation of the peptides towards lower leaflet of the bilayer. The stabilizing hydrogen bonds (H-bonds) between phosphate groups and Trp1, Lys3, and Arg15 of the peptides played important roles for membrane anchoring. MD simulations of Alanine (Ala) mutants revealed that WYK->Ala variant of NPB/NPW lacked crucial H-bond interactions with phospholipid headgroups and also caused severe misfolding in NPB. Altogether, the knowledge of preferred structural fold and interaction of neuropeptides within the membrane bilayer will be useful to develop synthetic agonist or antagonist peptides for GPR7 and GPR8.     

NMR conformational analyses on (des-bromo) neuropeptide B [1-23] and neuropeptide W [1-23]: the importance of alpha-helices, a cation-pi interaction and a beta-turn

The preferred conformations of the orphan G-protein coupled receptor agonists (des-bromo) neuropeptide B [1-23] and neuropeptide W [1-23], referred to as NPB and NPW, have been determined by (1)H NMR, CD, and molecular modeling. The sequences of NPB and NPW are WYKPAAGHSSYSVGRAAGLLSGL and WYKHVASPRYHTVGRAAGLLMGL, respectively. These are hypothalamic peptides that exert their biological actions on GPR7 and GPR8 receptors. Micellar solutions using the membrane mimetic, sodium dodecylsulphate-d(25) (SDS), were used to mimic a physiological environment for the peptides. The secondary structure of NPB consists of a type II beta-turn involving residues Lys(3) to Ala(6). The C-terminal region of NPB exists in a conformational equilibrium between different secondary structures, including an alpha-helix from residues Arg(15) to Ser(21), and a 3(10)-helix from residues Ser(12) to Ser(21). The N-terminus of NPW exhibits a cation-pi interaction between the Lys(3) side chain and the quadrupole moment of the Trp(1) indole group. At the C-terminus of NPW, a well-defined alpha-helical conformation exists from Arg(15) to Met(21). As NPB and NPW have 91% sequence homology from residues Val(13) to Leu(23), with only residue 21 differing between the two peptides, the similar C-terminal secondary structures of these two peptides are consistent with the sequences. This is supported by the similar CD spectra. The different secondary structures at the N-termini for NPB and NPW point to the importance of the N-terminus in receptor binding. This is consistent with the work of Fujii et al. [J. Biol. Chem. 277, 34010-34016 (2002)] who observed that iodination of the NPB Tyr(2) resulted in decreased agonistic activity at GPR7. In addition, Tanaka et al. [Proc. Natl. Acad. Sci. USA 100, 6251-6256 (2003)] showed that deletion of Trp(1) from NPB or NPW drastically decreased activity at GPR7 for NPB and GPR7 and GPR8 for NPW. Therefore, we postulate that the N-terminus is involved in membrane recognition and receptor binding.     

Neuropeptide W regulates proliferation and differentiation of ATDC5: Possible involvement of GPR7 activation,PKA and PKC‐dependent signalling cascades

Various neuropeptides related to the energy equilibrium affect bone growth in humans and animals. Neuropeptides W (NPW) are identical in the internal ligands of the two G‐protein receptors (GPRs) included in subtypes 7 and 8. Neuropeptides W inhibits proliferation in the cultivated rat calvarial osteoblast‐like (ROB) cells. This study examines the expression of NPW and GPR7 in murine chondrocyte and their function. An immunohistochemical analysis showed that NPW and GPR7 were expressed in the proliferative chondrocytes of the growth plates in the hind limbs of mice. The NPW mRNA quickly elevated in the early differentiation (7‐14 days) of ATDC5 cells, while NPW and GPR7 mRNA were reduced during the late stage (14‐21 days) of differentiation. Neuropeptide W‐23 (NPW‐23) promoted the proliferation of ATDC5 cells, which was attenuated by inhibiting the GPR7, protein kinase A (PKA), protein kinase C (PKC) and ERK1/2 pathways. Neuropeptide W‐23 enhanced the early cell differentiation, as evaluated by collagen type II and the aggrecan gene expression, which was unaffected by inhibiting the ERK1/2 pathway, but significantly decreased by inhibiting the PKA, PKC and p38 MAPK pathways. In contrast, NPW‐23 was not involved in the terminal differentiation of the chondrocytes, as evaluated by the mineralization of the chondrocytes and the activity of the alkaline phosphatase. Neuropeptides W stimulated the PKA, PKC, p38 MAPK and ERK1/2 activities in a dose‐ and time‐dependent manner in the ATDC5 cells. These results show that NPW promotes the proliferation and early differentiation of murine chondrocyte via GPR7 activation, as well as PKA and PKC‐dependent signalling cascades, which may be involved in endochondral bone formation.     

Development of a potent and selective GPR7 (NPBW1) agonist: a systematic structure-activity study of neuropeptide B.

Neuropeptide B (NPB) has been recently identified as an endogenous ligand for GPR7 (NPBW1) and GPR8 (NPBW2) and has been shown to possess a relatively high selectivity for GPR7. In order to identify useful experimental tools to address physiological roles of GPR7, we synthesized a series of NPB analogs based on modification of an unbrominated form of 23 amino acids with amidated C-terminal, Br(-)NPB-23-NH(2). We confirmed that truncation of the N-terminal Trp residue resulted in almost complete loss of the binding affinity of NPB for GPR7 and GPR8, supporting the special importance of this residue for binding. Br(-)NPB-23-NH2 analogs in which each amino acid in positions 4, 5, 7, 8, 9, 10, 12 and 21 was replaced with alanine or glycine exhibited potent binding affinity comparable to the parent peptide. In contrast, replacement of Tyr(11) with alanine reduced the binding affinity for both GPR7 and GPR8 four fold. Of particular interest, several NPB analogs in which the consecutive amino acids from Pro4 to Val(13) were replaced with several units of 5-aminovaleric acid (Ava) linkers retained their potent affinity for GPR7. Furthermore, these Ava-substituted NPB analogs exhibited potent agonistic activities for GPR7 expressed in HEK293 cells. Among the Ava-substituted NPB analogs, analog 15 (Ava-5) and 17 (Ava-3) exhibited potency comparable to the parent peptide for GPR7 with significantly reduced activity for GPR8, resulting in high selectivity for GPR7. These highly potent and selective NPB analogs may be useful pharmacological tools to investigate the physiological and pharmacological roles of GPR7.     

Purification and identification of neuromedin U as an endogenous ligand for an orphan receptor GPR66 (FM3)

GPR66 is an orphan G-protein-coupled receptor (GPCR) whose structure is similar to the ghrelin and motilin receptors. We have tried to purify a natural ligand for GPR66 in rat tissues and identified a 23-amino-acid peptide as the endogenous ligand. Sequence analysis revealed the peptide as neuromedin U (NMU), a smooth-muscle-contracting peptide that was first purified from porcine spinal cord by our group. NMU binds to GPR66-expressing cells with high specificity to induce intracellular calcium mobilization. When NMU was injected intracerebroventricularly (ICV) into rats, it potently suppressed food intake. In contrast, ICV injection of NMU-antibody increased food intake. These results suggest that NMU is a potent endogenous anorexic peptide.     

Neuronal interactions between neuropeptide W- and orexin- or melanin-concentrating hormone-containing neurons in the rat hypothalamus

Neuropeptide W (NPW) was recently discovered as the endogenous ligand for GPR7 and GPR8, which are orphan G protein-coupled receptors isolated from the porcine brain. These receptors are assumed to be involved in feeding regulation and/or energy homeostasis. Recent anatomical studies have revealed that high levels of GPR7 mRNA are distributed in the brain, including the hypothalamus and amygdala. However immunohistochemical studies on the distribution and localization of NPW have revealed differing results concerning whether or not NPW-containing cell bodies and their processes are present in the hypothalamus. Only a few immunohistochemical reports have been published concerning the presence of NPW-containing neurons in the brains of rodents, while there have been no anatomical studies of the co-localization of this neuropeptide with other transmitters. On this basis, we used a specific antiserum against NPW to determine immunohistochemically the presence of NPW-containing neurons in the rat hypothalamus. Many NPW-like immunoreactive cell bodies and their processes could be detected in the caudal region of the lateral hypothalamus but not in its anterior or middle regions. Given this positive identification of NPW-containing neurons in the lateral hypothalamus, we further studied the nature of interaction between NPW-containing neurons and neurons containing feeding regulating peptides such as orexin- and melanin-concentrating hormone (MCH). Very close interactions between NPW-containing nerve processes and orexin- and MCH-containing neuronal cell bodies and processes could be observed. These morphological findings strongly suggest that NPW is involved in the regulation of feeding and/or sleep/arousal behavior through orexin- and/or MCH-mediated neuronal pathways.     

A chronic high fat diet alters the homologous and heterologous control of appetite regulating peptide receptor expression

Leptin, ghrelin and neuropeptide W (NPW) modulate vagal afferent activity, which may underlie their appetite regulatory actions. High fat diet (HFD)-induced obesity induces changes in the plasma levels of these peptides and alters the expression of receptors on vagal afferents. We investigated homologous and heterologous receptor regulation by leptin, ghrelin and NPW. Mice were fed (12 weeks) a standard laboratory diet (SLD) or HFD. Nodose ganglia were cultured overnight in the presence or absence of each peptide. Leptin (LepR), ghrelin (GHS-R), NPW (GPR7) and cholecystokinin type-1 (CCK1R) receptor mRNA, and the plasma leptin, ghrelin and NPW levels were measured. SLD: leptin reduced LepR, GPR7, increased GHS-R and CCK1R mRNA; ghrelin increased LepR, GPR7, CCK1R, and decreased GHS-R. HFD: leptin decreased GHS-R and GPR7, ghrelin increased GHS-R and GPR7. NPW decreased all receptors except GPR7 which increased with HFD. Plasma leptin was higher and NPW lower in HFD. Thus, HFD-induced obesity disrupts inter-regulation of appetite regulatory receptors in vagal afferents.     

Ontogeny of a new enteric peptide, neuropeptide W (NPW), in the developing rat stomach

Neuropeptide W (NPW), a novel endogenous peptide for G protein-coupled receptors GPR7 and GPR8, is expressed in the gastric antral mucosa of rat, mouse, and human stomachs. Here, we studied the ontogeny of NPW in the developing rat stomach. Real-time RT-PCR showed that NPW gene expression was initially detectable in embryonic day 14 (E14) stomach and gradually increased during the progress of age until birth, postnatal day 1 (P1). NPW mRNA level in the stomach increased again from the weaning period (P21) until reaching adulthood. Immunohistochemistry using polyclonal antibodies raised against rat NPW revealed that NPW-positive cells were detected in the P1 antral stomach and gradually increased during the development of age. Furthermore, double immunohistochemistry demonstrated that NPW colocalized with gastrin in P1 rat stomach. These data will provide clues to physiological functions of NPW in the development of rat stomach.     

siRNA knockdown of GPR18 receptors in BV-2 microglia attenuates N-arachidonoyl glycine-induced cell migration

ABSTRACT: BACKGROUND: Neurons are known to employ the endogenous cannabinoid system to communicate with other cells of the CNS. Endocannabioid signaling recruits microglia toward neurons by engaging cannabinoid CB2 and abnormal cannabidiol (Abn-CBD) receptors. The Abn-CBD receptor is a prominent atypical cannabinoid receptor that had been discriminated by means of various pharmacological and genetic tools but remained to be identified at the molecular level. We recently introduced N-arachidonoyl glycine (NAGly) signaling via GPR18 receptors as an important novel signaling mechanism in microglial-neuronal communication. NAGly is an endogenous, enzymatically oxygenated metabolite of the endocannabinoid N-arachidonoyl ethanolamide (AEA). Our recent studies support strongly two hypotheses; first that NAGly initiates directed microglial migration in the CNS through activation of GPR18, and second that GPR18 is the Abn-CBD receptor. Here we present siRNA knockdown data in further support of these hypotheses. FINDINGS: A GPR18-targetting siRNA pSUPER GFP cDNA plasmid was created and transfected into BV-2 microglia. Successfully transfected GFP+ GPR18 siRNA BV-2 microglia displayed reduced GPR18 mRNA levels and immunocytochemical staining. Cell migration induced by 1 u(micro)M concentrations of NAGly, O-1602 and Abn-CBD were significantly attenuated in GFP+ cells. CONCLUSIONS: Our data provide definitive evidence that these compounds, characteristic of Abn-CBD receptor pharmacology, are acting via GPR18 in BV-2 microglia. A fuller understanding the hitherto unidentified cannabinoid receptors such as GPR18; their molecular interactions with endogenous ligands; and how phytocannabinoids influence their signaling is vital if we are to comprehensively assess the function of the endogenous cannabinoid signaling system in human health and disease.     

GPR55 and GPR35 and their relationship to cannabinoid and lysophospholipid receptors

This review presents a summary of what is known about the G-protein coupled receptors GPR35 and GPR55 and their potential characterization as lysophospholipid or cannabinoid receptors, respectively. Both GPR35 and GPR55 have been implicated as important targets in pain and cancer, and additional diseases as well. While kynurenic acid was suggested to be an endogenous ligand for GPR35, so was 2-arachidonoyl lysophosphatidic acid (LPA). Similarly, GPR55 has been suggested to be a cannabinoid receptor, but is quite clearly also a receptor for lysophosphatidylinositol. Interestingly, 2-arachidonyl glycerol (2-AG), an endogenous ligand for cannabinoid receptors, can be metabolized to 2-arachidonoyl LPA through the action of a monoacylglycerol kinase; the reverse reaction has also been demonstrated. Thus, it appears that mutual interconversion is possible between 2-arachidonoyl LPA and 2-AG within a cell, though the direction of the reaction may be site-dependent. The GPR55 natural ligand, 2-arachidonoyl LPI, can be degraded either to 2-AG by phospholipase C or to 2-arachidonoyl LPA by phospholipase D. Thus, GPR35, GPR55 and CB receptors are linked together through their natural ligand conversions. Additional agonists and antagonists have been identified for both GPR35 and GPR55, which will facilitate the future study of these receptors with respect to their physiological function. Potential therapeutic targets include pain, cancer, metabolic diseases and drug addiction.     

Continued discovery of ligands for G protein-coupled receptors

G protein-coupled receptors are under intense scrutiny as potential targets of drug research, which stems mostly from the sheer size and diversity of this receptor family as well as the recognized high levels of specificity and sensitivity attainable by drugs targeting these receptors. The continued discovery of genes encoding G protein-coupled receptors has provided an extensive reserve of potential therapeutic targets. However, testing experimental therapeutic agents at these receptors requires a high degree of receptor characterization, beginning with the identity of an endogenous ligand. Often, low levels of sequence identity of a newly identified receptor to previously characterized receptors preclude the prompt identification of a ligand. In such cases, innovative techniques commonly referred to as reverse pharmacology have been employed to ascertain the ligand's identity for these "orphan" receptors. To date over 30 endogenous ligands, both novel and previously known, have been paired with orphan G protein-coupled receptors. Here, we briefly summarize the recent identification of neuropeptides W and B and carboxylic acid anions for their respective receptors GPR7, GPR8 and GPR40, GPR41, GPR43.     

The orphan receptor GPR17 identified as a new dual uracil nucleotides/cysteinyl-leukotrienes receptor

Nucleotides and cysteinyl-leukotrienes (CysLTs) are unrelated signaling molecules inducing multiple effects through separate G-protein-coupled receptors: the P2Y and the CysLT receptors. Here we show that GPR17, a Gi-coupled orphan receptor at intermediate phylogenetic position between P2Y and CysLT receptors, is specifically activated by both families of endogenous ligands, leading to both adenylyl cyclase inhibition and intracellular calcium increases. Agonist-response profile, as determined by [(35)S]GTPgammaS binding, was different from that of already known CysLT and P2Y receptors, with EC(50) values in the nanomolar and micromolar range, for CysLTs and uracil nucleotides, respectively. Both rat and human receptors are highly expressed in the organs typically undergoing ischemic damage, that is, brain, heart and kidney. In vivo inhibition of GPR17 by either CysLT/P2Y receptor antagonists or antisense technology dramatically reduced ischemic damage in a rat focal ischemia model, suggesting GPR17 as the common molecular target mediating brain damage by nucleotides and CysLTs. In conclusion, the deorphanization of GPR17 revealed a dualistic receptor for two endogenous unrelated ligand families. These findings may lead to dualistic drugs of previously unexplored therapeutic potential.     

Neuropeptide W in the rat pancreas: potentiation of glucose-induced insulin release and Ca2+ influx through L-type Ca2+ channels in beta-cells and localization in islets

Neuropeptide W (NPW) is a regulatory peptide that acts via two subtypes of G protein-coupled receptors, GPR7 and GPR8. Evidence has been provided that NPW is involved in the central regulation of energy homeostasis and feeding behavior. In this study, we examined the effects of NPW on insulin release and localization of NPW in the rat pancreas. NPW (10-100 nM) significantly increased insulin release in the presence of 8.3 mM, but not 2.8 mM, glucose in the isolated rat islets. By fura-2 microfluorometry, NPW (1-100 nM) concentration-dependently increased cytosolic Ca(2+) concentration ([Ca(2+)](i)) at 8.3 mM glucose in rat single beta-cells. The NPW-induced [Ca(2+)](i) increase was abolished under external Ca(2+)-free conditions and by an L-type Ca(2+) channel blocker nifedipine (10 microM). RT-PCR analysis revealed that mRNA for NPW was expressed in the rat pancreas and hypothalamus. Double immunohistochemical analysis showed that NPW-immunoreactivity was found in islets and co-localized with insulin-containing beta-cells, but not glucagon-containing alpha-cells and somatostatin-containing delta-cells. These results suggest that NPW could serve as a local modulator of glucose-induced insulin release in rat islets. NPW directly activates beta-cells to enhance Ca(2+) influx through voltage-dependent L-type Ca(2+) channels and potentiates glucose-induced insulin release.     

Neuropeptide B and W regulate leptin and resistin secretion, and stimulate lipolysis in isolated rat adipocytes

Neuropeptide B (NPB) and W (NPW) regulate food intake and energy homeostasis in humans via two G-protein-coupled receptor subtypes, termed as GPR7 and GPR8. Rodents express GPR7 only. In animals, NPW decreases insulin and leptin levels, whereas the deletion of either NPB or GPR7 leads to obesity and hyperphagia. Metabolic and endocrine in vitro activities of NPW/NPB in adipocytes are unknown. We therefore characterize the effects of NPB and NPW on the secretion and expression of leptin and resistin, and on lipolysis, using rat adipocytes. Isolated rat adipocytes express GPR7 mRNA. NPB and NPW are expressed in macrophages and preadipocytes but are absent in mature adipocytes. Both, NPB and NPW reduce the secretion and expression of leptin from isolated rat adipocytes. NPB stimulates the secretion and expression of resistin, whereas both, NPB and NPW increase lipolysis. Our study demonstrates for the first time that NPB and NPW regulate the expression and secretion of leptin and resistin, and increase lipolysis in isolated rat adipocytes. These effects are presumably mediated via GPR7. The increase of resistin secretion, stimulation of lipolysis and the decrease of leptin secretion may represent mechanisms, through which NPB and NPW can affect glucose and lipid homeostasis, and food intake in rodents.     

Identification of structural features in the G-protein regulatory motif required for regulation of heterotrimeric G-proteins.

The G-protein regulatory (GPR) motif, a conserved 25-30 amino acid domain found in multiple mammalian proteins, stabilizes the GDP-bound conformation of Galpha(i), inhibits guanosine 5'-O-(3-thiotriphosphate) (GTPgammaS) binding to Galpha(i) and competes for Gbetagamma binding to Galpha. To define the core GPR motif and key amino acid residues within a GPR peptide (TMGEEDFFDLLAKSQSKRMDDQRVDLAG), we determined the effect of truncation, insertion, and alanine substitutions on peptide-mediated inhibition of GTPgammaS binding to purified Galpha(i1). The bioactive core GPR peptide consists of 17 amino acids ((7)F-R(23)). Within this core motif, two hydrophobic sectors ((7)FF(8) and (10)LL(11)) and Q(22) are required for bioactivity, whereas M19A and R23A increased IC(50) values by 70-fold. Disruption of spatial relationships between the required sectors in the amino and carboxyl regions of the peptide also resulted in a loss of biological activity. Mutation of three charged sectors ((4)EED(6), R(18), (20)DD(21)) within the 28-amino acid GPR decreased peptide affinity by approximately 10-fold. Alanine substitutions of selected residues within the core GPR peptide differently influenced peptide inhibition of GTPgammaS binding to Galpha(i) versus Galpha(o). These data provide a platform for the development of novel, G-protein-selective therapeutics that inhibit Galpha(i)- mediated signaling, selectively activate Gbetagamma-sensitive effectors, and/or disrupt specific regulatory input to G-proteins mediated by GPR-containing proteins.