Characterization of the neuropeptide Y system in the frog Silurana tropicalis (Pipidae): three peptides and six receptor subtypes.

Neuropeptide Y and its related peptides PYY and PP (pancreatic polypeptide) are involved in feeding behavior, regulation of the pituitary and the gastrointestinal tract, and numerous other functions. The peptides act on a family of G-protein coupled receptors with 4-7 members in jawed vertebrates. We describe here the NPY system of the Western clawed frog Silurana (Xenopus) tropicalis. Three peptides, NPY, PYY and PP, were identified together with six receptors, namely subtypes Y1, Y2, Y4, Y5, Y7 and Y8. Thus, this frog has all but one of the ancestral seven gnathostome NPY-family receptors, in contrast to mammals which have lost 2-3 of the receptors. Expression levels of mRNA for the peptide and receptor genes were analyzed in a panel of 19 frog tissues using reverse transcriptase quantitative PCR. The peptide mRNAs had broad distribution with highest expression in skin, blood and small intestine. NPY mRNA was present in the three brain regions investigated, but PYY and PP mRNAs were not detectable in any of these. All receptor mRNAs had similar expression profiles with high expression in skin, blood, muscle and heart. Three of the receptors, Y5, Y7 and Y8, could be functionally expressed in HEK-293 cells and characterized with binding studies using the three frog peptides. PYY had the highest affinity for all three receptors (K(i) 0.042-0.34 nM). Also NPY and PP bound to the Y8 receptor with high affinity (0.14 and 0.50 nM). The low affinity of NPY for the Y5 receptor (100-fold lower than PYY) differs from mammals and chicken. This may suggest a less important role of NPY on Y5 in appetite stimulation in the frog compared with amniotes. In conclusion, our characterization of the NPY system in S. tropicalis with its six receptors demonstrates not only greater complexity than in mammals but also some interesting differences in ligand-receptor preferences.

Birth and death of neuropeptide Y receptor genes in relation to the teleost fish tetraploidization.

Extensive evidence exists for a genome duplication in the fish lineage leading to the species-rich clade of the teleosts, comprising > 99% of the known actinopterygian (ray-finned) fish species. Our previous studies of the neuropeptide Y receptor (NPYR) gene family suggested an ancestral gnathostome repertoire of 7 genes in 3 subfamilies. However, studies in the zebrafish have earlier identified only 5 NPYR genes, despite the expected increase in gene number due to the teleost tetraploidization. Notably, receptors Y(1), Y(5) and Y(6) were missing in the zebrafish genome database and only Y(8) had been duplicated. We report here an investigation of the evolutionary history of the Y(1) subfamily (Y(1), Y(4), Y(6) and Y(8)) and the Y(5) receptor. Seven basal actinopterygian species and a shark were investigated and a total of 22 gene fragments were cloned and analyzed. Our results show that subtypes Y(1), Y(5) and Y(6) still exist in species representing basal actinopterygian lineages (bichir, sturgeon, gar and bowfin) as well as in some basal teleost lineages. Surprisingly we identified a zebrafish Y(1) receptor, the first Y(1) receptor found in euteleosts. Thus, these findings confirm the ancestral gnathostome repertoire of 7 NPYR genes and show that many of these receptors are present in basal actinopterygians as well as some basal teleosts. NPYR losses seem to have occurred relatively recently in euteleosts because Y(1), Y(5) and Y(6) are absent in the genome databases of two pufferfishes as well as medaka and stickleback and Y(5) and Y(6) are absent in the zebrafish database. A duplicate of Y(8) seems to be the only remaining receptor gene resulting from the teleost tetraploidization. The unexpected absence of the two appetite-stimulating receptors Y(1) and Y(5) in some euteleosts, along with our discovery of duplicates of the peptide ligands NPY and PYY, has implications for the role of the NPY system in euteleost feeding behavior.

Uneven evolutionary rates of bradykinin B1 and B2 receptors in vertebrate lineages.

Bradykinin acts through two receptor subtypes in mammals and generates a variety of responses including pain, inflammation and hypotension. The evolutionary history of the bradykinin system has been unclear due to shortage of information outside mammals. We describe here two receptor subtypes and the bradykinin precursor in three species of bony fish (the zebrafish Danio rerio, the Japanese pufferfish Takifugu rubripes, and the green spotted pufferfish Tetraodon nigroviridis) and chicken and analyze the relationships to mammals by a combination of phylogeny, conserved synteny and exon-intron organization. All of these species have two receptor genes located close to each other in a tandem formation, with the B2 gene 5' to the B1 gene, in chromosomal regions displaying conserved synteny between the species (albeit conservation of synteny in zebrafish is still unclear due to poor genome assembly). The evolutionary rate differs between the two genes as well as between lineages leading to differing pharmacological properties for both B1 and B2 across vertebrate classes. Also the bradykinin precursor gene was identified in all of these species in a chromosome region with conserved synteny. The tissue distribution of mRNA in T. rubripes is similar for B1 and B2, suggesting more similar regulation for the two genes than in mammals. In conclusion, the receptor tandem duplication predates the divergence of ray-finned fish and tetrapods and no additional duplicates of the receptors or bradykinin seem to have survived the ray-finned fish tetraploidization.

Cloning and characterization of a zebrafish Y2 receptor.

The NPY receptors belong to the superfamily of G-protein coupled receptors and in mammals this family has five members, named Y1, Y2, Y4, Y5, and Y6. In bony fish, four receptors have been identified, named Ya, Yb, Yc and Y7. Yb and Y7 arose prior to the split between ray-fined fishes and tetrapods and have been lost in mammals. Yc appeared as a copy of Yb in teleost fishes. Ya may be an ortholog of Y4, but surprisingly no unambiguous receptor ortholog to any of the mammalian subtypes has yet been identified in bony fishes. Here we present the cloning and pharmacological characterization of a Y2 receptor in zebrafish, Danio rerio. To date, this is the first Y2 receptor outside mammals and birds that has been characterized pharmacologically. Phylogenetic analysis and synteny confirmed that this receptor is orthologous to mammalian Y2. We show that the receptor is pharmacologically most similar to chicken Y2 which leads to the conclusion that Y2 has acquired several novel characteristics in mammals. Y2 from zebrafish binds very poorly to the Y2-specific antagonist BIIE0246. Our pharmacological characterization supports our previous conclusions regarding the binding pocket of BIIE0246 in the human Y2 receptor.

Molecular evolution of NPY receptor subtypes.

The neuropeptide Y (NPY) system consists in mammals of three peptides and 4-5 G-protein-coupled receptors called Y receptors that are involved in a variety of physiological functions such as appetite regulation, circadian rhythm and anxiety. Both the receptor family and the peptide family display unexpected evolutionary complexity and flexibility as shown by information from different classes of vertebrates. The vertebrate ancestor most likely had a single peptide gene and three Y receptor genes, the progenitors of the Y1, Y2 and Y5 subfamilies. The receptor genes were probably located in the same chromosomal segment. Additional gene copies arose through the chromosome quadruplication that took place before the emergence of jawed vertebrates (gnathostomes) whereupon differential losses of the gene copies ensued. The inferred ancestral gnathostome gene repertoire most likely consisted of two peptide genes, NPY and PYY, and no less than seven Y receptor genes: four Y1-like (Y1, Y4/a, Y6, and Yb), two Y2-like (Y2 and Y7), and a single Y5 gene. Whereas additional peptide genes have arisen in various lineages, the most common trend among the Y receptor genes has been further losses. Mammals have lost Yb and Y7 (the latter still exists in frogs) and Y6 is a pseudogene in several mammalian species but appears to be still functional in some. One challenge is to find out if mammals have been deprived of any functions through these gene losses. Teleost fishes like zebrafish and pufferfish, on the other hand, have lost the two major appetite-stimulating receptors Y1 and Y5. Nevertheless, teleost fishes seem to respond to NPY with increased feeding why some other subtype probably mediates this effect. Another challenge is to deduce how Y2 and Y4 came to evolve an inhibitory effect on appetite. Changes in anatomical distribution of receptor expression may have played an important part in such functional switching along with changes in receptor structures and ligand preferences.

Novel neuropeptide Y Y2-like receptor subtype in zebrafish and frogs supports early vertebrate chromosome duplications.

The Y receptors comprise a family of G-protein coupled receptors with neuropeptide Y-family peptides as endogenous ligands. The Y receptor family has five members in mammals and evolutionary data suggest that it diversified in the two genome duplications proposed to have occurred early in vertebrate evolution. If this theory holds true, it allows for additional family members to be present. We describe here the cloning, pharmacological characterization, tissue distribution, and chromosomal localization of a novel subtype of the Y-receptor family, named Y7, from the zebrafish. We also present Y7 sequences from rainbow trout and two amphibians. The new receptor is most similar to Y2, with 51-54% identity. As Y2 has also been cloned from some of these species, there clearly are two separate Y2-subfamily genes. Chromosomal mapping in zebrafish supports origin of Y7 as a duplicate of Y2 by chromosome duplication in an early vertebrate. Y7 has probably been lost in the lineage leading to mammals. The pharmacological profile of the zebrafish Y7 receptor is different from mammalian Y2, as it does not bind short fragments of NPY with a high affinity. The Y7 receptor supports the theory of early vertebrate genome duplications and suggests that the Y family of receptors is a result of these early genome duplications.

Chicken neuropeptide Y-family receptor Y4: a receptor with equal affinity for pancreatic polypeptide, neuropeptide Y and peptide YY.

Within the neuropeptide Y (NPY) family of peptides, pancreatic polypeptide is the most divergent across species. It differs in 20 of 36 positions between human and chicken. In mammals, it binds primarily to the Y4 receptor, to which NPY and peptide YY (PYY) bind with lower affinities. Because of these large sequence differences in pancreatic polypeptide, we decided to characterise the chicken Y4 receptor. We report here that Y4 displays the least sequence conservation among the Y-family receptors, with only 57-60% overall amino acid identity between chicken and mammals, compared with 64-83% for the Y1, Y2 and Y5 receptors. After expression of the chicken Y4 receptor in COS-7 cells, (125)I-labelled porcine (p) PYY bound with a K(d) of 20 pM. In competition with (125)I-pPYY, chicken pancreatic polypeptide bound with high affinity at 140 pM. Interestingly, chicken PYY bound with even greater affinity at 68 pM. The affinity of NPY, 160 pM, was similar to that of pancreatic polypeptide. Chicken Y4 is less sensitive than is mammalian Y4 to truncation of the amino terminus of the NPY molecule. RT-PCR revealed expression in several peripheral organs, including adipose tissue and oviduct. In brain, Y4 mRNA was detected in the brainstem, cerebellum and hippocampus. In situ hybridisation to brain sections showed expression in the dorsal motor nucleus of the vagus in the brainstem. Thus the chicken Y4 receptor is less selective and anatomically more widespread than that in mammals, probably reflecting the original properties of the Y4 receptor.

A neuropeptide Y receptor Y1-subfamily gene from an agnathan, the European river lamprey. A potential ancestral gene.

We report here the isolation and functional expression of a neuropeptide Y (NPY) receptor from the river lamprey, Lampetra fluviatilis. The receptor displays approximately 50% amino-acid sequence identity to all previously cloned Y1-subfamily receptors including Y1, Y4, and y6 and the teleost subtypes Ya, Yb and Yc. Phylogenetic analyses point to a closer relationship with Y4 and Ya/b/c suggesting that the lamprey receptor could possibly represent a pro-orthologue of some or all of those gnathostome receptors. Our results support the notion that the Y1 subfamily increased in number by genome or large-scale chromosome duplications, one of which may have taken place prior to the divergence of lampreys and gnathostomes whereas the second duplication probably occurred in the gnathostome lineage after this split. Functional expression of the lamprey receptor in a cell line facilitated specific binding of the three endogenous lamprey peptides NPY, peptide YY and peptide MY with picomolar affinities. Binding studies with a large panel of NPY analogues revealed indiscriminate binding properties similar to those of another nonselective Y1-subfamily receptor, zebrafish Ya. RT-PCR detected receptor mRNA in the central nervous system as well as in several peripheral organs suggesting diverse functions. This lamprey receptor is evolutionarily the most distant NPY receptor that clearly belongs to the Y1 subfamily as defined in mammals, which shows that subtypes Y2 and Y5 arose even earlier in evolution.

A putative tachykinin receptor in the cockroach brain: molecular cloning and analysis of expression by means of antisera to portions of the receptor protein.

Tachykinins constitute a neuropeptide family that mediate their actions via a subfamily of structurally related G-protein-coupled receptors. Two receptors, Drosophila neurokinin receptor (NKD) and Drosophila tachykinin receptor (DTKR), with sequence similarities to mammalian tachykinin receptors have previously been cloned in Drosophila. In this study we have isolated a cockroach (Leucophaea maderae) cDNA clone by screening a brain cDNA library with a degenerate oligonucleotide probe based on a conserved sequence within the seventh transmembrane region of the Drosophila tachykinin receptors. This clone, Leucophaea tachykinin receptor (LTKR), encodes a portion of a putative receptor which could be aligned with the C-terminal half of members of the tachykinin receptor subfamily. In the fifth, sixth and seventh transmembrane regions the deduced amino acid sequence of LTKR exhibits 79% sequence identity to the DTKR receptor and 54% to that of NKD. This suggests that LTKR is orthologous to the DTKR receptor. To study the distribution of the predicted LTKR protein by immunocytochemistry, antisera were raised against synthetic peptides corresponding to a region of the third intracellular loop of LTKR. In the cockroach brain immunoreactive neuronal processes were seen in several synaptic neuropils of the protocerebrum and tritocerebrum as well as in the frontal ganglion. Some immunoreactive neuronal cell bodies were detected in the protocerebrum. Double labeling immunocytochemistry revealed that there is a substantial superposition between distribution of LTKR and processes containing tachykinin-related peptide (TRP). Some brain areas, however, only display TRP immunoreactive processes and no LTKR, suggesting the presence of at least one more TRP receptor type.

Site-directed mutagenesis of the 5-HT1B receptor increases the affinity of 5-HT for the agonist low-affinity conformation and reduces the intrinsic activity of 5-HT.

The antagonist radioligand [3H]GR125743 and the agonist radioligand [3H]5-HT were used to investigate the pharmacological characteristics of the G protein uncoupled agonist low-affinity and G protein coupled agonist high-affinity conformations of the wild-type and mutant human 5-hydroxytryptamine 1B (5-HT1B) receptors. We found that substitution of phenylalanine 185 in transmembrane region IV by alanine or methionine resulted in a reduced number of receptors in the coupled conformation, as well as a reduced affinity of 5-HT for the uncoupled conformation. In contrast, substitution of phenylalanine 331 in transmembrane region VI by alanine increased the affinity of 5-HT for the uncoupled conformation 11-fold thus reducing the agonist low-affinity to agonist high-affinity (K(il)/K(ih)) ratio 5-fold. This reduced ratio was correlated with a significantly reduced intrinsic activity of 5-HT previously determined by its ability to inhibit forskolin-stimulated cAMP production. In conclusion, these results show that single amino acid substitutions can selectively change the affinity of 5-HT for the G protein uncoupled conformation of the 5-HT1B receptor and alter the intrinsic activity of the ligand.

Neuropeptide expression in rat paraventricular hypothalamic neurons that project to the spinal cord.

The paraventricular hypothalamic nucleus (PVH) exerts many of its regulatory functions through projections to spinal cord neurons that control autonomic and sensory functions. By using in situ hybridization histochemistry in combination with retrograde tract tracing, we analyzed the peptide expression among neurons in the rat PVH that send axons to the spinal cord. Projection neurons were labeled by immunohistochemical detection of retrogradely transported cholera toxin subunit B, and radiolabeled long riboprobes were used to identify neurons containing dynorphin, enkephalin, or oxytocin mRNA. Of the spinally projecting neurons in the PVH, approximately 40% expressed dynorphin mRNA, 40% expressed oxytocin mRNA, and 20% expressed enkephalin mRNA. Taken together with our previous findings on the distribution of vasopressin-expressing neurons in the PVH (Hallbeck and Blomqvist [1999] J. Comp. Neurol. 411:201-211), the results demonstrated that the different PVH subdivisions display distinct peptide expression patterns among the spinal cord-projecting neurons. Thus, the lateral parvocellular subdivision contained large numbers of spinal cord-projecting neurons that express any of the four investigated peptides, whereas the ventral part of the medial parvocellular subdivision displayed a strong preponderance for dynorphin- and vasopressin-expressing cells. The dorsal parvocellular subdivision almost exclusively contained dynorphin- and oxytocin-expressing spinal cord-projecting neurons. This parcellation of the peptide-expressing neurons suggested a functional diversity among the spinal cord-projecting subdivisions of the PVH that provide an anatomic basis for its various and distinct influences on autonomic and sensory processing at the spinal level.

Origins of the many NPY-family receptors in mammals.

The NPY system has a multitude of effects and is particularly well known for its role in appetite regulation. We have found that the five presently known receptors in mammals arose very early in vertebrate evolution before the appearance of jawed vertebrates 400 million years ago. The genes Y(1), Y(2) and Y(5) arose by local duplications and are still present on the same chromosome in human and pig. Duplications of this chromosome led to the Y(1)-like genes Y(4) and y(6). We find evidence for two occasions where receptor subtypes probably arose before peptide genes were duplicated. These observations pertain to the discussion whether ligands or receptors tend to appear first in evolution. The roles of Y(1) and Y(5) in feeding may differ between species demonstrating the importance of performing functional studies in additional mammals to mouse and rat.

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.

Cloning and characterization of the guinea pig neuropeptide Y receptor Y5.

The Y5 receptor has been postulated to be the main receptor mediating NPY-induced food intake in rats, based on its pharmacological profile and mRNA distribution. To further characterize this important receptor subtype, we isolated the Y5 gene in the guinea pig, a widely used laboratory animal in which all other known NPY receptors (Y1, Y2, Y4, y6) [2,13,33,37] have recently been cloned by our group. Our results show that the Y5 receptor is well conserved between species; guinea pig Y5 displays 96% overall amino acid sequence identity to human Y5, the highest identity reported for any non-primate NPY receptor orthologue, regardless of subtype. Thirteen of the twenty substitutions occur in the large third cytoplasmic loop. The identities between the guinea pig Y5 receptor and the dog, rat, and mouse Y5 receptors are 93%, 89%, and 89% respectively. When transiently expressed in EBNA cells, the guinea pig Y5 receptor showed a high binding affinity to iodinated porcine PYY with a dissociation constant of 0.41 nM. Competition experiments showed that the rank order of potency for NPY-analogues was PYY = NPY = NPY2-36 > gpPP > rPP >> NPY 22-36. Thus the pharmacological profile of the guinea pig Y5 receptor agrees well with that reported for the Y5 receptor from other cloned species.

Binding of chimeric NPY/galanin peptides M32 and M242 to cloned neuropeptide Y receptor subtypes Y1, Y2, Y4, and Y5.

Ligand binding to neuropeptide Y (NPY) receptors Y1, Y2, Y4, and Y5 from guinea-pig was investigated using the two NPY-galanin hybrids M32 (galanin1-13-NPY25-36-amide) and M242 ([D-Trp(32)]M32). The affinity of M32 for Y1, Y2, and Y4 receptors was 13, 4, and 30nM, respectively, similar to that of NPY18-36 and NPY22-36 but 40-fold to 300-fold lower than the affinity of intact porcine NPY. M242 bound to the Y1, Y2, and Y4 receptors with 9-fold to 20-fold lower affinity than did M32. The affinities of M32 and M242 for Y5 were 400 and 800 nM, respectively. Thus, M32 seems to gain affinity relative to both of its constituent peptide portions although the NPY25-36 part may be sufficient for NPY-receptor recognition, especially at the Y2 receptor. This suggests that the galanin portion of M32 influences and/or stabilizes the conformation of the NPY portion, similar to the effect seen for the NPY portion of M32 in binding to galanin receptors.

Binding properties of three neuropeptide Y receptor subtypes from zebrafish: comparison with mammalian Y1 receptors.

Neuropeptide Y (NPY) and peptide YY (PYY) are two related 36-amino-acid peptides found in all vertebrates and are involved in many physiological processes. Five receptor subtypes have been cloned in mammals (Y1, Y2, Y4, Y5, and y6). We have recently cloned three NPY/PYY receptor subtypes in zebrafish, called Ya, Yb, and Yc. Here we report on a direct comparison of the pharmacological properties of these three receptors in vitro using porcine NPY with alanine substitutions in positions 33-36 as ligands and three analogues with internal deletions: [Ahx(8-20)]NPY, [Ahx(8-20), Pro(34)]NPY, and [Ahx(5-24)]NPY. In all cases, the zYc receptor was the most sensitive to the modifications of the NPY molecule and zYa was the least sensitive (except for the Arg --> Ala replacement at position 33). Our data identified zYa as a receptor that can bind ligands specific for Y1, Y2, and Y4 receptors, while zYb and zYc were more Y1-like. All peptides with internal deletions bound to the zYa receptor with affinities similar to that of intact pNPY. Neither the Y1-selective antagonists BIBP3226 and SR120819A nor the Y2-selective BIIE0246 bound to any of the zebrafish receptors, although the amino acids identified as important for BIBP3226 binding were almost completely conserved. These results may prove helpful in molecular modeling of the three-dimensional receptor structure.

Chicken neuropeptide Y receptor Y2: structural and pharmacological differences to mammalian Y2(1).

Here we report the molecular cloning of the chicken (Gallus gallus) neuropeptide Y (NPY) receptor Y2, the first non-mammalian Y2 receptor. It displays 75-80% identity to mammalian Y2 and has a surprisingly divergent cytoplasmic tail. Expression of the receptor protein in a cell line showed that the receptor did not bind the mammalian Y2 selective antagonist BIIE0246. Furthermore, porcine [Leu(31), Pro(34)]NPY, which binds poorly to mammalian Y2, exhibited an unexpectedly high affinity for chicken Y2. In situ hybridisation revealed expression in the hippocampus. Thus, the chicken Y2 receptor exhibits substantial differences with regard to sequence and pharmacological profile in comparison to mammalian Y2 receptors, while the expression pattern in the central nervous system resembles that observed in mammals.