Project description:Background Insulin signaling pathway is conserved from worms to humans. In Drosophila, three insulin-like peptides (dilps) are expressed in the insulin producing cells (IPCs) in the brain. In order to identify target genes of insulin signaling, the IPCs of female flies were destroyed during development by expressing apoptosis inducing factors reaper and head involution defective under control of the promoter region of dilp3. These insulin-deficient flies were analysed using high density microarrays. Results From the genes that appeared to be regulated in the absence of IPCs, the strongest difference was found for a gene involved in carbohydrate metabolism. Sequence analysis revealed that it is an alpha-glucosidase, which is able to break down disaccharides and/or glycogen. Conclusions We could identify an alpha-glucosidase, involved in carbohydrate metabolism, to be strongly affected in the context of decreased insulin signaling. The striking feature of this regulation was not only that it was the highest regulated, but it was the only gene regulated to this degree. Nutrient Conditions and Fly handling Experimental and control female flies were collected after hatching, then kept on fly maintenance food and separated from males after 11 days. After one day of recovery from carbon dioxide treatment, females were put in cages with PBS agar plates and supplied with yeast paste as only food source for 48 hours. Flies were shock frozen in liquid nitrogen and stored at - 80°C for further handling. Keywords: IPC knockout, 14 day old female flies, 48h yeast feeding Insulin producing cell deficient flies were compared to control flies. Two independent biological repeats were performed. From the two repeats, 5 chips were hybridised, including dye swap Experimental and control female flies were collected after hatching, then kept on fly maintenance food and separated from males after 11 days. After one day of recovery from carbon dioxide treatment, females were put in cages with PBS agar plates and supplied with yeast paste as only food source for 48 hours. The microarray was scanned 3 times: low scan (suffix _L in data table) with a low amplification / intensity to avoid saturated spots for proper data analysis, high scan (suffix _H in data table) with a high amplification / intensity to detect also weak fluorescent spots which are missed in the low scan and medium scan which lies between high and low intensity and gives additional data points for subsequent calculations. Both copies and all hybridisation repeats were used for normalisation, VALUE therefore has the same value for these copies in all relevant hybridisations. For additional information see publication and web link. Keywords = insulin, aging, longevity, nutrient dependance Lot batch = FP7

Project description:Transcriptional analysis of dInR and dfoxo epistasis in Drosophila melanogaster. The experiment was performed to examine which parts of the transcriptional response to a reduction in insulin signalling in an adult female fly depend on the presence of the dfoxo transcription factor. Whole fly transcriptome was determined with flies over-expressing a dominant negative form of the insulin receptor, or the wild-type fly, in presence or absence of dfoxo.

Project description:In fasted mammals, glucose homeostasis is maintained through activation of the cAMP responsive CREB coactivator TORC2, which stimulates the gluconeogenic program in concert with the forkhead transcription factor FOXO1. Here we show that starvation also triggers TORC activation in Drosophila, where it maintains energy balance by promoting the expression of CREB target genes in the brain. TORC mutant flies have reduced glycogen and lipid stores, and they are sensitive to starvation as well as oxidative stress. Neuronal TORC expression rescued starvation and oxidative stress sensitivity as well as CREB target gene expression in TORC mutants. During refeeding, increases in insulin signaling inhibited TORC activity in wild type flies by stimulating the Salt Inducible Kinase 2 (SIK2)-mediated phosphorylation and subsequent degradation of TORC. Depletion of neuronal SIK2 increased TORC activity and enhanced resistance to starvation and oxidative stress in adult flies. As disruption of insulin signaling, either by ablation of insulin-producing cells (IPCs) or by mutation of the insulin receptor adaptor gene chico, also increased TORC activity, our results illustrate the importance of an insulin-regulated pathway in brain that promotes energy balance in Drosophila. Experiment Overall Design: Male fly heads were collected after 24h fasting, and RNA was extracted using RNAeasy kit.

Project description:Background All animals must be able to adapt to changes in nutrient quality and supply. One striking aspect of this adaptive response is the extension of lifespan when caloric intake is reduced. These animals are also more resistant to various stresses, including starvation. We have characterized the response of adult Drosophila males and females to starvation and sugar conditions using high density microarrays. Results We have organized the regulated genes into specific metabolic and physiologic pathways. Most of the highly regulated genes have a strong sex bias. In addition to expected sex specific changes, such as egg production in females, we found unexpected biases in sensory systems, amino acid and purine metabolism, and signaling pathways. Comparison of starvation to caloric restriction revealed numerous overlaps. Conclusions Our results support the notion that starvation response shares similarities to caloric restriction. They have relevance for sex specific differences in longevity and in response to nutrient conditions which alter lifespan. Nutrient Conditions and Fly handling Larvae were kept on apple juice agar plates with yeast, and the larvae were raised at 25°C. For the developmental control larvae were collected 39-41 h AEL, for the developmental time-points at 51-53 hours and every 12 hours until 99-101 hours. Adult flies were kept at 25°C in 50 ml PS-tubes flat bottom (Greiner bio-one, Frickenhausen, Germany) on standard fly food (16.5 g yeast, 81,5 g cornmeal, 8 g agar, 100 ml sugar beet sirup and 200 ml 10% Nipagin in EtOH). Flies were collected that had hatched in 24 hours and kept in groups of ~200 flies/tube. After 5 days we separated males and females and put them in groups of 80/28 ml PS-tube. We allowed for one day CO2 recovery on standard fly food before flies were moved to 1) tubes with yeast paste on PBS soaked filter paper (control) 2) tubes with only PBS soaked filter paper (starvation) or 3) tubes with filter paper soaked in PBS with 20% Sucrose (sugar). After 24 or 48 hours flies were shock frozen in liquid nitrogen and stored at - 80°C for further handling. Males and females were assayed separately. For females, we performed 24 and 48 starvation, and 24 and 48 hours sugar. For the males only 24 hour starvation was done, since most died upon 48 hour starvation; and 24 and 48 hour sugar. Briefly, flies were collected within a 24 hour period, allowed to stay together for 4 days, separated into males and females, and allowed one day recovery in normal fly food. Afterwards, the flies were placed into three conditions: fresh yeast plus PBS, PBS or PBS plus 20 % sucrose. These experiments essentially parallel the experimental set up of previous larval experiments (7). The starvation and PBS were then compared with yeast (control).

Project description:To understand how reduced insulin/IGF-1 signaling extends Drosophila lifespan through its downstream transcription factor dFOXO. We conducted ChIP analysis with a dFOXO antibody followed by Illumina high-throughput sequencing from chico heterozygous mutants, which are long-lived and normal sized, and from adult flies with ablated insulin producing cells (IPCs), which are also long-lived. dFOXO bound at promoters of 273 genes common among these genotypes, thus potentially enriching for shared factors in control of aging. Two replicates were sequenced from chico heterozygous mutants and IPC ablated flies.

Project description:A Drosophila microRNA (dme-miR-14) is involved in regulating the levels of insulin-like peptides (ilps) from the neuronal insulin-producing cells (IPCs). This is crucial for regulation of fat content in adult flies. Finding the target of this microRNA is crucial for understanding the regulation of ilp gene expression. We used microarrays to identify genes that are upregulated specifically in the neuronal IPCs in the microRNA mutants.

Project description:dFOXO targets in adult Drosophila melanogaster females, and the effect of insulin signalling and stress on binding. The experimets determined the binding locations of dFOXO in the whole adult female fly using ChIP-chip. The protocol was validated using mock conditions: pre-immune serum or IP on chromatin from foxo null flies. The response of this binding to stress induced by treatment of flies with paraquat or by their exposure to starvation, as well as the response to an insulin-signalling-reducing genetic manipulation (over-expression of dominant negative form of the insulin receptor), was determined.

Project description:A Drosophila microRNA (dme-miR-14) is involved in regulating the levels of insulin-like peptides (ilps) from the neuronal insulin-producing cells (IPCs). This is crucial for regulation of fat content in adult flies. Finding the target of this microRNA is crucial for understanding the regulation of ilp gene expression. We used microarrays to identify genes that are upregulated specifically in the neuronal IPCs in the microRNA mutants. Drosophila adult head RNA was extracted and hybridized on Affymetrix microarrays. We reared animals from early larval stages in controlled growth and feeding conditions. RNA was extracted from 5-day-old adult males. We collected RNA from control, homozygous dme-miR-14 mutants and mutants expressing dme-miR-14 microRNA specifically in the IPCs (rescue). We were interested in genes that were upregulated in the mutants and were restored or reduced to control levels in the rescue condition. Two biological replicates per sample type were performed.

Project description:The sensation of hunger after a period of fasting and the sensation of satiety after eating is crucial to behavioral regulation of food intake, but the biological mechanisms regulating these sensations are incompletely understood. We studied the behavioral and physiological adaptation to fasting in the vinegar fly (Drosophila melanogaster). Here we show that flies demonstrated increased behavioral attraction to food odor when food-deprived with no corresponding increase in sensitivity in the peripheral olfactory system. Flies increased their food intake transiently in the post-fasted state, but returned to a stable baseline feeding level within 24 hr after return to food. This modulation in feeding was accompanied by a significant increase in the size of the crop organ of the digestive system, suggesting that fasted flies responded both by increasing their food intake and storing reserve food in their crop. The post-fasting feeding response was observed in both male and female flies of diverse genetic backgrounds. Expression profiling of head, body, and chemosensory tissues by microarray analysis revealed several hundred genes that are regulated by feeding state, including 247 genes in the fly head. We performed RNA interference-mediated knockdown of, takeout, one of the genes strongly downregulated by fasting in multiple tissues. When takeout was knocked down in all neurons the post-fasting feeding response was abolished. These observations suggest that a coordinated transcriptional response to internal physiological state may regulate both ingestive behaviors and chemosensory perception of food 6 Pool of flies were used for this experiment. For each pool, samples were taken at 0,24 and 48h and separated in each body part. 56 samples were used for the analysis.

Project description:The sensation of hunger after a period of fasting and the sensation of satiety after eating is crucial to behavioral regulation of food intake, but the biological mechanisms regulating these sensations are incompletely understood. We studied the behavioral and physiological adaptation to fasting in the vinegar fly (Drosophila melanogaster). Here we show that flies demonstrated increased behavioral attraction to food odor when food-deprived with no corresponding increase in sensitivity in the peripheral olfactory system. Flies increased their food intake transiently in the post-fasted state, but returned to a stable baseline feeding level within 24 hr after return to food. This modulation in feeding was accompanied by a significant increase in the size of the crop organ of the digestive system, suggesting that fasted flies responded both by increasing their food intake and storing reserve food in their crop. The post-fasting feeding response was observed in both male and female flies of diverse genetic backgrounds. Expression profiling of head, body, and chemosensory tissues by microarray analysis revealed several hundred genes that are regulated by feeding state, including 247 genes in the fly head. We performed RNA interference-mediated knockdown of, takeout, one of the genes strongly downregulated by fasting in multiple tissues. When takeout was knocked down in all neurons the post-fasting feeding response was abolished. These observations suggest that a coordinated transcriptional response to internal physiological state may regulate both ingestive behaviors and chemosensory perception of food