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.

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.

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.

Monoaminergic changes associated with socially induced sex reversal in the saddleback wrasse.

The process of sex reversal in fishes is socially mediated and requires a total reorganization of the hypothalamo-pituitary-gonadal axis. When the ratio of males to females in a population of saddleback wrasse (Thalassoma dupperrey) is too low, the largest female becomes male over the course of 6 to 8 weeks. This event requires the conversion of external social cues into internal chemical cues. In an attempt to investigate the role monoamines might play in this process, two females were housed together in floating enclosures in order to induce sex reversal in the larger. Brains were sampled at various time points throughout the process of sex reversal. Monoamines were measured in the amygdala, preoptic area, ventral hypothalamus, locus coeruleus and raphe nucleus. Changes were demonstrated in monoamine metabolism for all brain regions examined. The most important changes in monoamine-system activation were seen during the first week of sex reversal. It is during this time that transitional animals undergo behavioral sex reversal. There is an increase in serotonergic activity in the amygdala which is likely related to territorial acquisition. The absence of male aggression results in a less stressful environment for the female and a reduction in serotonergic activity in the preoptic area allowing for an increase in noradrenergic activity potentially triggering the reorganization of the reproductive axis. In the ventral hypothalamus, there is a decrease in noradrenergic and increase in dopaminergic activity associated with this change from female to male. The locus coeruleus shows an increase in noradrenergic activity later in the process of sex reversal which is probably a response to more circulating androgens. In the raphe nucleus, there is a decrease in serotonergic activity at the time of behavioral sex reversal. This decrease in serotonergic activity is linked to the behavioral component of sex reversal. This study suggests that monoamines play a very important role in both behavioral and gonadal sex reversal in the saddleback wrasse, the former under the control of serotonin in the raphe and the latter mediated via serotonergic effects on norepinephrine in the preoptic area.

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.

Serotonin reverses dominant social status.

Social stress from aggressive interaction is expressed differently in specific brain regions of dominant and subordinate male Anolis carolinensis. Prior to aggressive behavior, the outcome is predictable via the celerity of postorbital coloration: Dominant males exhibit more rapid eyespot darkening. Serotonergic activation is manifest rapidly (1 h) in hippocampus, nucleus accumbens and brainstem of subordinate males, and is expressed more rapidly in dominant males. Amygdalar serotonergic activation responds rapidly (1 h) in dominant males, but is expressed slowly (1 w) and chronically in subordinate males. We hypothesized that chronic (1 w) serotonin elevation, manipulated by the selective serotonin reuptake inhibitor sertraline, would decrease aggressiveness and result in subordinate status. Dominant status was established in pairs of male A. carolinensis. The pairs were separated and treated with sertraline or vehicle. Sertraline was given in food to either the dominant or the subordinate male, both males or neither male for 1 week. Pairs were reintroduced, and behavior and social status recorded. When both dominant and subordinate males were treated with sertraline (or vehicle), or when subordinate males alone were treated with sertraline, previously established social relationships remained unchanged or became associative. However, when dominant males alone were treated with sertraline, their social status was reversed (43%) or negated (57%). Latency to eyespot darkening was significantly retarded in dominant males treated with sertraline, and aggressive displays and attacks were reduced. Chronic 5-HT elevation is consistent with subordinate status. Social status and aggressive disposition do not appear to be immutable, but may be changed by neuroendocrine mechanisms that mediate adaptation to environmental conditions like stress.

Serotonergic responses to corticosterone and testosterone in the limbic system.

Glucocorticoids secreted peripherally during stressful events act on central monoaminergic systems. In particular, serotonergic mediation of social behavior, such as aggression and reproduction, may be affected by glucocorticoids. This study was undertaken to determine if systemically administered corticosterone would rapidly affect central monoaminergic activity. Male Anolis carolinensis (N = 8 each group) were injected intraperitoneally with 10 or 100 micrograms corticosterone, 10 micrograms testosterone, or saline. Twenty minutes after treatment, brains were rapidly dissected and frozen and then microdissected (punch diameter 300 microm) and analyzed by high-performance liquid chromatography. Serotonergic turnover (estimated by 5-hydroxyindoleacetic acid/serotonin) in the hippocampus and medial amygdala was significantly enhanced by systemic corticosterone. Both of these regions of the brain have been associated with social stress. Testosterone also enhanced turnover in the hippocampus. The effect of corticosterone and testosterone may be to modulate socially induced differences in serotonergic response. Rapid, but short-lived, glucocorticoid stimulation of serotonin release suggests a possible mechanism for mediation of changing social behavioral events.

Regional and temporal separation of serotonergic activity mediating social stress.

Stressful aggressive interaction stimulates central serotonergic activation in telencephalon as well as brainstem. Social roles can be distinguished by monoamine activity following aggression. Pairs of male lizards, Anolis carolinensis, were allowed to fight and form dominant/subordinate relationships. In micropunched regions of telencephalon, the greatest serotonergic changes occur in subordinate males. In hippocampal cortex and nucleus accumbens, subordinate males have increased 5-hydroxyindoleacetic acid/serotonin at 1 h following the fight. In these areas the ratio gradually decreases over a week of cohabitation, as was previously reported for brainstem. Medial and lateral amygdala develop increased serotonergic activity more slowly, with the greatest increase being evident following a week of interaction. Turnover, serotonin and 5-hydroxyindoleacetic acid levels in amygdala escalate over the first week of interaction in subordinate males, and return to baseline by one month. In dominant males, the pattern is accelerated, with the most extensive serotonin system activity present at 1 h, then decreasing over a month. The patterns of serotonergic activation are so similar in hippocampus, nucleus accumbens and brainstem that a co-ordinated response may be involved in mediating short-term social stress and aggression. Similarly, medial and lateral amygdala exhibit corresponding, but delayed patterns in subordinate males, suggesting a co-ordinated response in these regions mediating longer-term stress responses. These data are consistent with rapid neuroendocrine stress modulation in dominant individuals, and delayed serotonergic activity changes in subordinate males.