Ingestion of vertebrate blood is essential for egg maturation and transmission of disease-causing parasites by female mosquitoes. Prior studies with the yellow fever mosquito, Aedes aegypti, indicated blood feeding stimulates egg production by triggering the release of hormones from medial neurosecretory cells in the mosquito brain. The ability of bovine insulin to stimulate a similar response further suggested this trigger is an endogenous insulin-like peptide (ILP). A. aegypti encodes eight predicted ILPs. Here, we report that synthetic ILP3 dose-dependently stimulated yolk uptake by oocytes and ecdysteroid production by the ovaries at lower concentrations than bovine insulin. ILP3 also exhibited metabolic activity by elevating carbohydrate and lipid storage. Binding studies using ovary membranes indicated that ILP3 had an IC 50 value of 5.9 nM that was poorly competed by bovine insulin. Autoradiography and immunoblotting studies suggested that ILP3 binds the mosquito insulin receptor (MIR), whereas loss-of-function experiments showed that ILP3 activity requires MIR expression. Overall, our results identify ILP3 as a critical regulator of egg production by A. aegypti.
Omnivores, including humans, have an inborn tendency to avoid noxious or unfamiliar foods. Such defensive foraging behaviors are modifiable, however, in response to physiological needs. Here we describe a method for assessing risk-sensitive food acquisition in Drosophila melanogaster. Food-deprived fly larvae become more likely to feed on noxious foods (adulterated with quinine) as the duration of deprivation increases. The neuropeptide F receptor NPFR1, a mammalian neuropeptide Y (NPY) receptor homolog, centrally regulates the response to noxious food in D. melanogaster. Overexpression of NPFR1 was sufficient to cause nondeprived larvae to more readily take in noxious food, whereas loss of NPFR1 signaling led to the opposite phenotype. Moreover, NPFR1 neuronal activity may be directly regulated by the insulin-like signaling pathway. Upregulation of insulin-like receptor signaling in NPFR1 cells suppressed the feeding response to noxious food. Our results suggest that the coordinated activities of the conserved NPY- and insulin-like receptor signaling systems are essential for the dynamic regulation of noxious food intake according to the animal's energy state.
MicroRNA-mediated post-transcriptional regulations are increasingly recognized as important components of the circadian rhythm. Here we identify microRNA let-7, part of the Drosophila let-7-Complex, as a regulator of circadian rhythms mediated by a circadian regulatory cycle. Overexpression of let-7 in clock neurons lengthens circadian period and its deletion attenuates the morning activity peak as well as molecular oscillation. Let-7 regulates the circadian rhythm via repression of CLOCKWORK ORANGE (CWO). Conversely, upregulated cwo in cwo-expressing cells can rescue the phenotype of let-7-Complex overexpression. Moreover, circadian prothoracicotropic hormone (PTTH) and CLOCKregulated 20-OH ecdysteroid signalling contribute to the circadian expression of let-7 through the 20-OH ecdysteroid receptor. Thus, we find a regulatory cycle involving PTTH, a direct target of CLOCK, and PTTH-driven miRNA let-7.
The biochemical basis of life-history tradeoffs is a poorly studied aspect of life-history evolution. We used radiotracer and endocrine approaches to investigate the extent to which morphs of a wingpolymorphic insect differ in the biosynthesis of lipid classes important for dispersal capability vs. reproduction (ovarian growth). The flight-capable genotype of Gryllus firmus biosynthesized a greater amount of total lipid and triglyceride (main flight fuel), which was preferentially allocated to somatic tissue during early adulthood. By contrast, the flightless genotype biosynthesized a significantly greater amount of phospholipid (important in egg development), which was preferentially allocated to ovaries. Topical application of a juvenile-hormone mimic to the flight-capable morph caused it to express all aspects of lipid metabolism seen in the flightless morph. Differences in biosynthesis between morphs (i) occur coincident with 100 -400% greater ovarian growth in the flightless morph, (ii) result from alterations of both de novo biosynthesis of fatty acid and downstream partitioning of fatty acids into triglyceride vs. phospholipid, and (iii) possibly result from genetically polymorphic hormonal regulators with negative pleiotropic effects on lipid biosynthesis and ovarian growth. The present study provides direct documentation of genetically based alterations of in vivo flux through pathways of intermediary metabolism leading to the differential production of end products central to the specialization of phenotypes for alternate life histories.life history ͉ biosynthesis ͉ intermediary metabolism ͉ juvenile hormone M any life-history traits such as longevity and early-age reproduction are negatively associated with each other (1-3). During the past four decades, numerous studies have attempted to identify the functional causes of these tradeoffs, which play a central role in life-history evolution (4-7). Although most work has focused on the differential allocation of internal resources to competing life-history traits, the specific mechanisms underlying tradeoffs at the physiological level remain poorly understood (6, 7), and biochemical (metabolic) aspects of internal tradeoffs have rarely been investigated. This lack of information constitutes a major roadblock to attaining a deep understanding of the mechanisms of life-history evolution (7).Accumulation of lipid reserves seems to play a pivotal role in many life-history tradeoffs (7-11). In insects, lipid is typically more abundant in individuals adapted to live longer or to withstand stressful or energy-demanding conditions such as starvation or long-duration flight. By contrast, lipid is reduced in individuals with enhanced early-age fecundity or faster rate of juvenile development, traits that often tradeoff with the lifehistory traits mentioned above (7,10,(12)(13)(14)(15)(16). These associations suggest that the evolution of many life-history traits requires modifications of lipid metabolism to increase energy reserves, and that these modifications, ...
Sleep is important for maintenance of normal physiology in animals. In mammals, neuropeptide Y (NPY), a homolog of
Drosophila
neuropeptide F (NPF), is involved in sleep regulation, with different effects in human and rat. However, the function of NPF on sleep in Drosophila melanogaster has not yet been described. In this study, we investigated the effects of NPF and its receptor-neuropeptide F receptor (NPFR1) on
Drosophila
sleep. Male flies over-expressing NPF or NPFR1 exhibited increased sleep during the nighttime. Further analysis demonstrated that sleep episode duration during nighttime was greatly increased and sleep latency was significantly reduced, indicating that NPF and NPFR1 promote sleep quality, and their action on sleep is not because of an impact of the NPF signal system on development. Moreover, the homeostatic regulation of flies after sleep deprivation was disrupted by altered NPF signaling, since sleep deprivation decreased transcription of NPF in control flies, and there were less sleep loss during sleep deprivation and less sleep gain after sleep deprivation in flies overexpressing NPF and NPFR1 than in control flies, suggesting that NPF system auto-regulation plays an important role in sleep homeostasis. However, these effects did not occur in females, suggesting a sex-dependent regulatory function in sleep for NPF and NPFR1. NPF in D1 brain neurons showed male-specific expression, providing the cellular locus for male-specific regulation of sleep by NPF and NPFR1. This study brings a new understanding into sleep studies of a sexually dimorphic regulatory mode in female and male flies.
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