BackgroundThe melatonin receptor subfamily contains three members Mel1a, Mel1b and Mel1c, found in all vertebrates except for Mel1c which is found only in fish, Xenopus species and the chicken. Another receptor, the melatonin related receptor known as GPR50, found exclusively in mammals and later identified as a member of the melatonin receptor subfamily because of its identity to the three melatonin receptors despite its absence of affinity for melatonin. The aim of this study was to describe the evolutionary relationships between GPR50 and the three other members of the melatonin receptor subfamily.ResultsUsing an in silico approach, we demonstrated that GPR50 is the ortholog of the high affinity Mel1c receptor. It was necessary to also study the synteny of this gene to reach this conclusion because classical mathematical models that estimate orthology and build phylogenetic trees were not sufficient. The receptor has been deeply remodelled through evolution by the mutation of numerous amino acids and by the addition of a long C-terminal tail. These alterations have modified its affinity for melatonin and probably affected its interactions with the other two known melatonin receptors MT1 and MT2 that are encoded by Mel1a and Mel1b genes respectively. Evolutionary studies provided evidence that the GPR50 group evolved under different selective pressure as compared to the orthologous groups Me11 a, b, and c.ConclusionThis study demonstrated that there are only three members in the melatonin receptor subfamily with one of them (Me11c) undergoing rapid evolution from fishes and birds to mammals. Further studies are necessary to investigate the physiological roles of this receptor.
We investigated the effects of perinatal maternal malnutrition on the hypothalamo-pituitary-adrenal (HPA) axis activity in both basal and stressful conditions in newborn rats at weaning. Mothers from the control group were fed ad libitum. Mothers exposed to food restriction received 50% (FR50) of the daily intake of pregnant dams during the last week of gestation (Pre group), lactation (Post group) or both periods (PP group) in order to compare the long-term effects of gestational and/or lactational restriction. FR50 reduced the body growth of pups from the Post and PP groups as soon as day 11 until day 21 after birth. At weaning, pups of the Post and PP groups showed reduced adrenal, thymus and liver weights. Although the plasma adrenocorticotropic hormone (ACTH) level was reduced in pups, FR50 affected neither corticotropin-releasing hormone expression and peptide synthesis in the hypothalamus nor proopiomelanocortin expression in the adenohypophysis. Basal circulating levels of corticosterone were not markedly affected by FR50, but free corticosterone concentration was increased in the PP group. Plasma corticosterone-binding globulin (CBG) was decreased in newborns from both the Post and PP groups. Mineralocorticoid receptor gene expression was significantly increased in both CA1 and CA3 hippocampal areas in the PP group. Glucocorticoid receptor gene expression was increased in CA1, CA2 and dentate gyrus hippocampal areas in the Pre group, as well as in CA1, CA3 and DG areas in the Post group. The ether inhalation-induced plasma ACTH increase was weaker in pups from the Post and PP groups. Similarly, the ether inhalation-induced plasma corticosterone increase returned to basal levels in the Post group, or to weaker values than baseline in the PP group 90 min after this stressful procedure. The present work suggests that maternal food restriction during the perinatal period (gestation and lactation) or during lactation only reduces the postnatal somatic growth of pups and disturbs the activity of the HPA axis at weaning under both resting and stress conditions. A reduction in the plasma CBG-binding capacity, associated with a probable increase in hippocampal corticosteroid receptors, could reinforce glucocorticoid-mediated negative feedback and shorten stress-induced activation of the HPA axis in pups at weaning.
In humans, an altered control of cortisol secretion was reported in adult men born with a low birth weight making the hypothalamic-pituitary-adrenal (HPA) axis a possible primary target of early life programming. In rats, we have recently shown that maternal food restriction during late pregnancy induces both an intrauterine growth retardation and an overexposure of fetuses to maternal corticosterone, which disturb the development of the HPA axis in offspring. The first aim of this work was to investigate, in adult male rats, whether perinatal malnutrition has long-lasting effects on the HPA axis activity during both basal and stressful conditions. Moreover, as the HPA axis and sympathetic nervous system are both activated by stress, the second aim of this work was to investigate, in these rats, the adrenomedullary catecholaminergic system under basal and stressful conditions. This study was conducted on 4-month-old male rats malnourished during their perinatal life and on age-matched control animals. Under basal conditions, perinatal malnutrition reduced body weight and plasma corticosteroid-binding globulin (CBG) level but increased mineralocorticoid receptor (MR) gene expression in CA1 hippocampal area. After 30 min of restraint, perinatally malnourished (PM) rats showed increased plasma noradrenaline, adrenocorticotropin hormone (ACTH) and corticosterone concentrations similarly as controls, but calculated plasma-free corticosterone concentration was significantly higher and adrenaline level lower than controls. During the phase of recovery, PM rats showed a rapid return of plasma ACTH and corticosterone concentrations to baseline levels in comparison with controls. These data suggest that in PM rats, an elevation of basal concentrations of corticosterone, in face of reduced CBG and probably increased hippocampal MR lead to a much larger impact of corticosterone on target cells that mediate the negative-feedback mechanism on the activities of both the HPA axis and sympathoadrenal one.
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