Neuropeptide Y (NPY) is a powerful stimulant of food intake and is proposed to activate a hypothalamic 'feeding' receptor distinct from previously cloned Y-type receptors. This receptor was first suggested to explain a feeding response to NPY and related peptides, including NPY2-36, that differed from their activities at the Y1 receptor. Here we report the expression cloning of a novel Y-type receptor from rat hypothalamus, which we name Y5. The complementary DNA encodes a 456-amino-acid protein with less than 35% overall identity to known Y-type receptors. The messenger RNA is found primarily in the central nervous system, including the paraventricular nucleus of the hypothalamus. The extent to which selected peptides can inhibit adenylate cyclase through the Y5 receptor and stimulate food intake in rats correspond well. Our data support the idea that the Y5 receptor is the postulated 'feeding' receptor, and may provide a new method for the study and treatment of obesity and eating disorders.
The neuropeptide galanin is widely distributed throughout the central and peripheral nervous systems and participates in the regulation of processes such as nociception, cognition, feeding behavior, and insulin secretion. Multiple galanin receptors are predicted to underlie its physiological effects. We now report the isolation by expression cloning of a rat galanin receptor cDNA distinct from GALR1. The receptor, termed GALR2, was isolated from a rat hypothalamus cDNA library using a 125 I-porcine galanin (
The pancreatic polypeptide family includes pancreatic polypeptide (PP), neuropeptide Y (NPY), and peptide YY (PYY). Members of the PP family regulate numerous physiological processes, including appetite, gastrointestinal transit, anxiety, and blood pressure. Of the multiple Y-type receptors proposed for PP family members, only the Y1 subtype has been cloned previously. We now report the cloning of an additional Y-type receptor, designated Y4, by homology screening of a human placental genomic library with transmembrane (TM) probes derived from the rat Y1 gene. The Y4 genomic clone encodes a predicted protein of 375 amino acids that is most homologous to Y1 receptors from human, rat, and mouse (42% overall; 55% in TM).
The neuropeptide galanin mediates its effects through the receptor subtypes Gal
1
, Gal
2
, and Gal
3
and has been implicated in anxiety- and depression-related behaviors. Nevertheless, the receptor subtypes relevant to these behaviors are not known because of the lack of available galanin-selective ligands. In this article, we use behavioral, neurochemical, and electrophysiological approaches to investigate the anxiolytic- and antidepressant-like effects of two potent small-molecule, Gal
3
-selective antagonists, SNAP 37889 and the more soluble analog SNAP 398299. Acute administration of SNAP 37889 or SNAP 398299 enhanced rat social interaction. Furthermore, acute SNAP 37889 was also shown to reduce guinea pig vocalizations after maternal separation, to attenuate stress-induced hyperthermia in mice, to increase punished drinking in rats, and to decrease immobility and increase swimming time during forced swim tests with rats. Moreover, SNAP 37889 increased the social interaction time after 14 days of treatment and maintained its antidepressant effects during forced swim tests with rats after 21 days of treatment. In microdialysis studies, SNAP 37889 partially antagonized the galanin-evoked reduction in hippocampal serotonin (5-hydroxytryptamine, 5-HT), as did the 5-HT
1A
receptor antagonist WAY100635. Their combination produced a complete reversal of the effect of galanin. SNAP 398299 partially reversed the galanin-evoked inhibition of dorsal raphe cell firing and galanin-evoked hyperpolarizing currents. These results indicate that Gal
3
-selective antagonists produce anxiolytic- and antidepressant-like effects, possibly by attenuating the inhibitory influence of galanin on 5-HT transmission at the level of the dorsal raphe nucleus.
The pancreatic polypeptide family includes neuropeptide Y (NPY), one of the most abundant neuropeptides in the mammalian nervous system, as well as peptide YY (PYY) and pancreatic polypeptide (PP). This peptide family is involved in numerous physiological processes such as memory, pain, blood pressure, appetite, anxiety, and circadian rhythm. Of the multiple Y-type receptors proposed for PP family members, only the Y1 subtype was cloned previously. We now report the isolation of a human Y2 (hhY2) receptor cDNA by expression cloning from a human hippocampal cDNA library, using a 125 I-PYY binding assay. hhY2 cDNA encodes a predicted protein of 381 amino acids with low amino acid identity to the human Y1 receptor (31% overall; 41% transmembrane).
Using 125I-labeled neuropeptide Y (NPY) and peptide YY (PYY), we demonstrated the existence of specific receptors for these peptides on rat dorsal root ganglion (DRG) cells grown in primary culture. Scatchard analysis of membrane homogenates indicated that the peptides bound to 2 populations of sites, with approximate affinities of 0.08 and 6.5 nM. Only low levels of binding were detected on sympathetic neurons cultured from the same animals or on a variety of neuronal clonal cell lines. The binding of 125I-NPY and 125I-PYY to DRG cell membranes was considerably reduced by the nonhydrolyzable analog of GTP, Gpp(NH)p. The major effect of Gpp(NH)p was to reduce the number of lower-affinity NPY binding sites without altering the number of high- affinity binding sites. NPY potently inhibited Ca2+ currents recorded under voltage clamp in rat DRG cells. Both the transient and sustained portions of the Ca2+ current were inhibited. The inhibitory effects of NPY were completely blocked following treatment of the cells with pertussis toxin. Depolarization elicited a large influx of Ca2+ into DRG neurons as assessed using fura-2-based microspectrofluorimetry. This influx of Ca2+ could be partially inhibited by NPY. Furthermore, NPY effectively inhibited the depolarization-induced release of substance P from DRG cells in vitro. Thus, NPY may be an important regulator of sensory neuron function in vivo.
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