Randall S. Hewes scite author profile

Recent genetic analyses in worms, flies, and mammals illustrate the importance of bioactive peptides in controlling numerous complex behaviors, such as feeding and circadian locomotion. To pursue a comprehensive genetic analysis of bioactive peptide signaling, we have scanned the recently completed Drosophila genome sequence for G protein-coupled receptors sensitive to bioactive peptides (peptide GPCRs). Here we describe 44 genes that represent the vast majority, and perhaps all, of the peptide GPCRs encoded in the fly genome. We also scanned for genes encoding potential ligands and describe 22 bioactive peptide precursors. At least 32 Drosophila peptide receptors appear to have evolved from common ancestors of 15 monophyletic vertebrate GPCR subgroups (e.g., the ancestral gastrin/cholecystokinin receptor). Six pairs of receptors are paralogs, representing recent gene duplications. Together, these findings shed light on the evolutionary history of peptide GPCRs, and they provide a template for physiological and genetic analyses of peptide signaling in Drosophila.

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The bHLH protein Dimmed controls neuroendocrine cell differentiation inDrosophila

Hewes

et al. 2003

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Neuroendocrine cells are specialized to produce, maintain and release large stores of secretory peptides. We show that the Drosophila dimmed/Mist1 bHLH gene confers such a pro-secretory phenotype on neuroendocrine cells. dimmed is expressed selectively in central and peripheral neuroendocrine cells. In dimmed mutants, these cells survive, and adopt normal cell fates and morphology. However, they display greatly diminished levels of secretory peptide mRNAs, and of diverse peptides and proteins destined for regulated secretion. Secretory peptide levels are lowered even in the presence of artificially high secretory peptide mRNA levels. In addition, overexpression of dimmed in a wild-type background produces a complimentary phenotype: an increase in secretory peptide levels by neuroendocrine cells, and an increase in the number of cells displaying a neuroendocrine phenotype. We propose that dimmed encodes an integral component of a novel mechanism by which diverse neuroendocrine lineages differentiate and maintain the pro-secretory state. 1772 dimmed (dimm), with an expression pattern that corresponds precisely to the neuronal and endocrine cells that accumulate large amounts of secretory peptides. We present both loss-offunction and gain-of-function analyses to argue that dimm confers a pro-secretory phenotype within these diverse cells, and that its actions appear confined to that aspect of cellular differentiation. Thus, we propose a novel and general mechanism, of which dimm is an essential component, for the amplification of the regulated secretory pathway by dedicated secretory cells. MATERIALS AND METHODS StrainsFlies were cultured at 22-25°C on a standard cornmeal-yeast-agar medium. The molecular and genetic characterization of c929, R6 and Rev8 has been described previously (Hewes et al., 2000). Rev4 and Rev18 are X-ray revertants of P{PZ}l (2)k05106 S2a ) were obtained by transposase-mediated excision, and each line was characterized by PCR with primers flanking the original insertion site. Except as noted, all other strains are described elsewhere (Lindsley and Zimm, 1992;FlyBase, 1999) and were obtained from the Bloomington stock center, the BDGP Gene Disruption Project and other sources. Scoring of dimm larvaeEggs were collected on apple juice-agar plates supplemented with yeast paste. Larvae were collected from the plates, and heterozygotes (y* w* and balanced over CyO-y + ) were distinguished by mouthpart color. After scoring, size-matched pairs of y -and y + larvae were dissected and stained in parallel.

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Activity-dependent liberation of synaptic neuropeptide vesicles

et al. 2005

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Despite the importance of neuropeptide release, which is evoked by long bouts of action potential activity and which regulates behavior, peptidergic vesicle movement has not been examined in living nerve terminals. Previous in vitro studies have found that secretory vesicle motion at many sites of release is constitutive: Ca(2+) does not affect the movement of small synaptic vesicles in nerve terminals or the movement of large dense core vesicles in growth cones and endocrine cells. However, in vivo imaging of a neuropeptide, atrial natriuretic factor, tagged with green fluorescent protein in larval Drosophila melanogaster neuromuscular junctions shows that peptidergic vesicle behavior in nerve terminals is sensitive to activity-induced Ca(2+) influx. Specifically, peptidergic vesicles are immobile in resting synaptic boutons but become mobile after seconds of stimulation. Vesicle movement is undirected, occurs without the use of axonal transport motors or F-actin, and aids in the depletion of undocked neuropeptide vesicles. Peptidergic vesicle mobilization and post-tetanic potentiation of neuropeptide release are sustained for minutes.

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Multiple Amidated Neuropeptides Are Required for Normal Circadian Locomotor Rhythms inDrosophila

et al. 2001

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In Drosophila, the amidated neuropeptide pigment dispersing factor (PDF) is expressed by the ventral subset of lateral pacemaker neurons and is required for circadian locomotor rhythms. Residual rhythmicity in pdf mutants likely reflects the activity of other neurotransmitters. We asked whether other neuropeptides contribute to such auxiliary mechanisms. We used the gal4/UAS system to create mosaics for the neuropeptide amidating enzyme PHM; amidation is a highly specific and widespread modification of secretory peptides in Drosophila. Three different gal4 drivers restricted PHM expression to different numbers of peptidergic neurons. These mosaics displayed aberrant locomotor rhythms to degrees that paralleled the apparent complexity of the spatial patterns. Certain PHM mosaics were less rhythmic than pdf mutants and as severe as per mutants. Additional gal4 elements were added to the weakly rhythmic PHM mosaics. Although adding pdf-gal4 provided only partial improvement, adding the widely expressed tim-gal4 largely restored rhythmicity. These results indicate that, in Drosophila, peptide amidation is required for neuropeptide regulation of behavior. They also support the hypothesis that multiple amidated neuropeptides, acting upstream, downstream, or in parallel to PDF, help organize daily locomotor rhythms.

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Randall S. Hewes

Neuropeptides and Neuropeptide Receptors in the Drosophila melanogaster Genome

The bHLH protein Dimmed controls neuroendocrine cell differentiation inDrosophila

Activity-dependent liberation of synaptic neuropeptide vesicles

Multiple Amidated Neuropeptides Are Required for Normal Circadian Locomotor Rhythms inDrosophila

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