Neuropeptides regulate a wide range of animal behavior including food consumption, circadian rhythms, and anxiety. Recently, Drosophila neuropeptide F, which is the homolog of the vertebrate neuropeptide Y, was cloned, and the function of Drosophila neuropeptide F in feeding behaviors was well characterized. However, the function of the structurally related short neuropeptide F (sNPF) was unknown. Here, we report the cloning, RNA, and peptide localizations, and functional characterizations of the Drosophila sNPF gene. The sNPF gene encodes the preprotein containing putative RLRF amide peptides and was expressed in the nervous system of late stage embryos and larvae. The embryonic and larval localization of the sNPF peptide in the nervous systems revealed the larval central nervous system neural circuit from the neurons in the brain to thoracic axons and to connective axons in the ventral ganglion. In the adult brain, the sNPF peptide was localized in the medulla and the mushroom body. However, the sNPF peptide was not detected in the gut. The sNPF mRNA and the peptide were expressed during all developmental stages from embryo to adult. From the feeding assay, the gainof-function sNPF mutants expressed in nervous systems promoted food intake, whereas the loss-of-function mutants suppressed food intake. Also, sNPF overexpression in nervous systems produced bigger and heavier flies. These findings indicate that the sNPF is expressed in the nervous systems to control food intake and regulate body size in Drosophila melanogaster.Neuropeptides regulate a wide range of animal behavior. In vertebrates, neuropeptide Y (NPY) 1 regulates food consumption, circadian rhythms, anxiety, and other physiological processes (1). NPY, a 36-amino acid neuromodulator, is expressed abundantly in the mammalian brain and controls feeding (2). The NPY injection into the hypothalamus of rat brain resulted in hyperphagia and obesity, whereas the NPY-deficient mouse in the leptin mutant background (NPYϪ/Ϫ; ob/ob) showed the less obese phenotype (3).In invertebrates, neuropeptide F (NPF) peptides share structural similarity with the vertebrate NPY (4). NPF peptides isolated from various invertebrate animals have the conserved (A/L)R(P/L)RF amide sequence at their C-terminal ends (5, 6). From a completely sequenced Drosophila melanogaster genome, short NPF (sNPF; CG13968) and Drosophila NPF (dNPF; CG10342) were found. The dNPF peptide was isolated by the radioimmunoassay. The preprotein is processed to the 36-amino acid peptide containing RVRF amide in the C terminus. dNPF is considered the homolog of the vertebrate NPY. dNPF mRNA and peptide are expressed in the brain and midgut of Drosophila larvae and adults (7). The dNPF neural network in the larval central nervous system (CNS) is changed by the gustatory stimulation of sugar, indicating that dNPF is an integral part of the chemosensory system that regulates eating behavior (8). Drosophila larvae eat continuously and grow in a relatively short period. About 5 days after egg laying, they s...
Insulin and insulin growth factor have central roles in growth, metabolism and ageing of animals, including Drosophila melanogaster. In Drosophila, insulin-like peptides (Dilps) are produced by specialized neurons in the brain. Here we show that Drosophila short neuropeptide F (sNPF), an orthologue of mammalian neuropeptide Y (NPY), and sNPF receptor sNPFR1 regulate expression of Dilps. Body size was increased by overexpression of sNPF or sNPFR1. The fat body of sNPF mutant Drosophila had downregulated Akt, nuclear localized FOXO, upregulated translational inhibitor 4E-BP and reduced cell size. Circulating levels of glucose were elevated and lifespan was also extended in sNPF mutants. We show that these effects are mediated through activation of extracellular signal-related kinases (ERK) in insulin-producing cells of larvae and adults. Insulin expression was also increased in an ERK-dependent manner in cultured Drosophila central nervous system (CNS) cells and in rat pancreatic cells treated with sNPF or NPY peptide, respectively. Drosophila sNPF and the evolutionarily conserved mammalian NPY seem to regulate ERK-mediated insulin expression and thus to systemically modulate growth, metabolism and lifespan.
Feeding behavior is one of the most essential activities in animals, which is tightly regulated by neuroendocrine factors. Drosophila melanogaster short neuropeptide F (sNPF) and the mammalian functional homolog neuropeptide Y (NPY) regulate food intake. Understanding the molecular mechanism of sNPF and NPY signaling is critical to elucidate feeding regulation. Here, we found that minibrain (mnb) and the mammalian ortholog Dyrk1a target genes of sNPF and NPY signaling and regulate food intake in Drosophila melanogaster and mice. In Drosophila melanogaster neuronal cells and mouse hypothalamic cells, sNPF and NPY modulated the mnb and Dyrk1a expression through the PKA-CREB pathway. Increased Dyrk1a activated Sirt1 to regulate the deacetylation of FOXO, which potentiated FOXO-induced sNPF/NPY expression and in turn promoted food intake. Conversely, AKT-mediated insulin signaling suppressed FOXO-mediated sNPF/NPY expression, which resulted in decreasing food intake. Furthermore, human Dyrk1a transgenic mice exhibited decreased FOXO acetylation and increased NPY expression in the hypothalamus, as well as increased food intake. Our findings demonstrate that Mnb/Dyrk1a regulates food intake through the evolutionary conserved Sir2-FOXO-sNPF/NPY pathway in Drosophila melanogaster and mammals.
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