Your search keyword '"Fat Body physiology"' showing total 18 results

1. Ade2 Functions in the Drosophila Fat Body To Promote Sleep.

Author

Yurgel ME, Shah KD, Brown EB, Burns C, Bennick RA, DiAngelo JR, and Keene AC

Subjects

Animals, Female, Glucose metabolism, Triglycerides metabolism, Carbon-Nitrogen Ligases physiology, Drosophila physiology, Fat Body physiology, Sleep physiology

Abstract

Metabolic state is a potent modulator of sleep and circadian behavior, and animals acutely modulate their sleep in accordance with internal energy stores and food availability. Across phyla, hormones secreted from adipose tissue act in the brain to control neural physiology and behavior to modulate sleep and metabolic state. Growing evidence suggests the fat body is a critical regulator of complex behaviors, but little is known about the genes that function within the fat body to regulate sleep. To identify molecular factors functioning in non-neuronal tissues to regulate sleep, we performed an RNAi screen selectively knocking down genes in the fat body. We found that knockdown of Phosphoribosylformylglycinamidine synthase / Pfas (Ade2 ), a highly conserved gene involved the biosynthesis of purines, sleep regulation and energy stores. Flies heterozygous for multiple Ade2 mutations are also short sleepers and this effect is partially rescued by restoring Ade2 to the Drosophila fat body. Targeted knockdown of Ade2 in the fat body does not alter arousal threshold or the homeostatic response to sleep deprivation, suggesting a specific role in modulating baseline sleep duration. Together, these findings suggest Ade2 functions within the fat body to promote both sleep and energy storage, providing a functional link between these processes., (Copyright © 2018 Yurgel et al.)

Published

2018

2. Crowding of Drosophila larvae affects lifespan and other life-history traits via reduced availability of dietary yeast.

Author

Klepsatel P, Procházka E, and Gáliková M

Subjects

Adaptation, Physiological, Animals, Body Size, Female, Longevity, Male, Starvation, Yeast, Dried, Crowding, Diet veterinary, Drosophila physiology, Fat Body physiology, Larva physiology

Abstract

Conditions experienced during development have often long-lasting effects persisting into adulthood. In Drosophila, it is well-documented that larval crowding influences fitness-related traits such as body size, starvation resistance and lifespan. However, the underlying mechanism of this phenomenon is not well understood. Here, we show that the effects of increased larval density on life-history traits can be explained by decreased yeast availability in the diet during development. Yeast-poor larval diet alters various life-history traits and mimics the effects of larval crowding. In particular, reduced amount of yeast in larval diet prolongs developmental time, reduces body size, increases body fat content and starvation resistance, and prolongs Drosophila lifespan. Conversely, the effects of larval crowding can be rescued by increasing the concentration of the dietary yeast in the diet during development. Altogether, our results show that the well-known effects of larval crowding on life-history traits are mainly caused by the reduced availability of dietary yeasts due to increased larval competition., (Copyright © 2018 Elsevier Inc. All rights reserved.)

Published

2018

3. Fat body remodeling and homeostasis control in Drosophila.

Author

Zheng H, Yang X, and Xi Y

Subjects

Animals, Drosophila anatomy & histology, Energy Metabolism, Fat Body anatomy & histology, Longevity, Signal Transduction, Drosophila physiology, Fat Body physiology, Homeostasis, Lipid Metabolism

Abstract

Remarkable advances have been made in recent years in our understanding of the Drosophila fat body and its functions in energy storage, immune response and nutrient sensing. The fat body interplays with other tissues to respond to the physiological needs of the body's growth and coordinates various metabolic processes at different developmental stages and under different environmental conditions. The identification of various conserved genetic functions and signaling pathways relating to the Drosophila fat body may provide clues to lipometabolic disease and other aspects of tissue remodeling in humans. Here, we discuss recent insights into how regulation of fat body remodeling contributes to hemostasis with a special focus on how signaling networks and internal physiological states shape different aspects of the lipid metabolism in Drosophila., (Copyright © 2016. Published by Elsevier Inc.)

Published

2016

4. Neural clocks and Neuropeptide F/Y regulate circadian gene expression in a peripheral metabolic tissue.

Author

Erion R, King AN, Wu G, Hogenesch JB, and Sehgal A

Subjects

Animals, Metabolism, Biological Clocks, Drosophila physiology, Drosophila Proteins metabolism, Fat Body physiology, Gene Expression Regulation, Nervous System Physiological Phenomena, Neuropeptides metabolism

Abstract

Metabolic homeostasis requires coordination between circadian clocks in different tissues. Also, systemic signals appear to be required for some transcriptional rhythms in the mammalian liver and the Drosophila fat body. Here we show that free-running oscillations of the fat body clock require clock function in the PDF-positive cells of the fly brain. Interestingly, rhythmic expression of the cytochrome P450 transcripts, sex-specific enzyme 1 (sxe1) and Cyp6a21, which cycle in the fat body independently of the local clock, depends upon clocks in neurons expressing neuropeptide F (NPF). NPF signaling itself is required to drive cycling of sxe1 and Cyp6a21 in the fat body, and its mammalian ortholog, Npy, functions similarly to regulate cycling of cytochrome P450 genes in the mouse liver. These data highlight the importance of neuronal clocks for peripheral rhythms, particularly in a specific detoxification pathway, and identify a novel and conserved role for NPF/Npy in circadian rhythms., Competing Interests: The author declares that no competing interests exist.

Published

2016

5. Retromer Ensures the Degradation of Autophagic Cargo by Maintaining Lysosome Function in Drosophila.

Author

Maruzs T, Lőrincz P, Szatmári Z, Széplaki S, Sándor Z, Lakatos Z, Puska G, Juhász G, and Sass M

Subjects

Animals, Carrier Proteins metabolism, Cytoplasm metabolism, Cytoplasm physiology, Drosophila physiology, Endocytosis physiology, Endosomes metabolism, Endosomes physiology, Fat Body metabolism, Fat Body physiology, Lysosomes physiology, Protein Transport physiology, Vacuoles metabolism, Vacuoles physiology, Vesicular Transport Proteins metabolism, trans-Golgi Network metabolism, trans-Golgi Network physiology, Autophagy physiology, Drosophila metabolism, Lysosomes metabolism, Sorting Nexins metabolism

Abstract

The retromer is an evolutionarily conserved coat complex that consists of Vps26, Vps29, Vps35 and a heterodimer of sorting nexin (Snx) proteins in yeast. Retromer mediates the recycling of transmembrane proteins from endosomes to the trans-Golgi network, including receptors that are essential for the delivery of hydrolytic enzymes to lysosomes. Besides its function in lysosomal enzyme receptor recycling, involvement of retromer has also been proposed in a variety of vesicular trafficking events, including early steps of autophagy and endocytosis. Here we show that the late stages of autophagy and endocytosis are impaired in Vps26 and Vps35 deficient Drosophila larval fat body cells, but formation of autophagosomes and endosomes is not compromised. Accumulation of aberrant autolysosomes and amphisomes in the absence of retromer function appears to be the consequence of decreased degradative capacity, as they contain undigested cytoplasmic material. Accordingly, we show that retromer is required for proper cathepsin L trafficking mainly independent of LERP, the Drosophila homolog of the cation-independent mannose 6-phosphate receptor. Finally, we find that Snx3 and Snx6 are also required for proper autolysosomal degradation in Drosophila larval fat body cells., (© 2015 John Wiley & Sons A/S. Published by John Wiley & Sons Ltd.)

Published

2015

6. Mmp1 and Mmp2 cooperatively induce Drosophila fat body cell dissociation with distinct roles.

Author

Jia Q, Liu Y, Liu H, and Li S

Subjects

Adipocytes metabolism, Adipocytes physiology, Animals, Basement Membrane metabolism, Basement Membrane physiology, Drosophila physiology, Fat Body physiology, RNA Interference physiology, Drosophila metabolism, Fat Body metabolism, Matrix Metalloproteinase 1 metabolism, Matrix Metalloproteinase 2 metabolism, Metamorphosis, Biological physiology

Abstract

During Drosophila metamorphosis, the single-cell layer of fat body tissues gradually dissociates into individual cells. Via a fat body-specific RNAi screen in this study, we found that two matrix metalloproteinases (MMPs), Mmp1 and Mmp2, are both required for fat body cell dissociation. As revealed through a series of cellular, biochemical, molecular, and genetic experiments, Mmp1 preferentially cleaves DE-cadherin-mediated cell-cell junctions, while Mmp2 preferentially degrades basement membrane (BM) components and thus destroy cell-BM junctions, resulting in the complete dissociation of the entire fat body tissues into individual cells. Moreover, several genetic interaction experiments demonstrated that the roles of Mmp1 and Mmp2 in this developmental process are cooperative. In conclusion, Mmp1 and Mmp2 induce fat body cell dissociation during Drosophila metamorphosis in a cooperative yet distinct manner, a finding that sheds light on the general mechanisms by which MMPs regulate tissue remodeling in animals.

Published

2014

7. Impaired proteasomal degradation enhances autophagy via hypoxia signaling in Drosophila.

Author

Lőw P, Varga Á, Pircs K, Nagy P, Szatmári Z, Sass M, and Juhász G

Subjects

Animals, Drosophila Proteins physiology, Fat Body physiology, Homeostasis physiology, Hypoxia-Inducible Factor 1, alpha Subunit physiology, Models, Animal, TATA-Binding Protein Associated Factors physiology, Transcription Factor TFIID physiology, Autophagy physiology, Cell Hypoxia physiology, Drosophila physiology, Proteasome Endopeptidase Complex physiology, Signal Transduction physiology

Abstract

Background: Two pathways are responsible for the majority of regulated protein catabolism in eukaryotic cells: the ubiquitin-proteasome system (UPS) and lysosomal self-degradation through autophagy. Both processes are necessary for cellular homeostasis by ensuring continuous turnover and quality control of most intracellular proteins. Recent studies established that both UPS and autophagy are capable of selectively eliminating ubiquitinated proteins and that autophagy may partially compensate for the lack of proteasomal degradation, but the molecular links between these pathways are poorly characterized., Results: Here we show that autophagy is enhanced by the silencing of genes encoding various proteasome subunits (α, β or regulatory) in larval fat body cells. Proteasome inactivation induces canonical autophagy, as it depends on core autophagy genes Atg1, Vps34, Atg9, Atg4 and Atg12. Large-scale accumulation of aggregates containing p62 and ubiquitinated proteins is observed in proteasome RNAi cells. Importantly, overexpressed Atg8a reporters are captured into the cytoplasmic aggregates, but these do not represent autophagosomes. Loss of p62 does not block autophagy upregulation upon proteasome impairment, suggesting that compensatory autophagy is not simply due to the buildup of excess cargo. One of the best characterized substrates of UPS is the α subunit of hypoxia-inducible transcription factor 1 (HIF-1α), which is continuously degraded by the proteasome during normoxic conditions. Hypoxia is a known trigger of autophagy in mammalian cells, and we show that genetic activation of hypoxia signaling also induces autophagy in Drosophila. Moreover, we find that proteasome inactivation-induced autophagy requires sima, the Drosophila ortholog of HIF-1α., Conclusions: We have characterized proteasome inactivation- and hypoxia signaling-induced autophagy in the commonly used larval Drosophila fat body model. Activation of both autophagy and hypoxia signaling was implicated in various cancers, and mutations affecting genes encoding UPS enzymes have recently been suggested to cause renal cancer. Our studies identify a novel genetic link that may play an important role in that context, as HIF-1α/sima may contribute to upregulation of autophagy by impaired proteasomal activity.

Published

2013

8. Fat body dSir2 regulates muscle mitochondrial physiology and energy homeostasis nonautonomously and mimics the autonomous functions of dSir2 in muscles.

Author

Banerjee KK, Ayyub C, Sengupta S, and Kolthur-Seetharam U

Subjects

Animals, Carnitine administration & dosage, Drosophila physiology, Drosophila Proteins genetics, Epoxy Compounds administration & dosage, Fatty Acids, Nonesterified metabolism, Female, Forkhead Transcription Factors genetics, Forkhead Transcription Factors metabolism, Gene Expression Regulation, Gene Knockdown Techniques, Gene Regulatory Networks, Glucose Tolerance Test, Histone Deacetylases genetics, Homeostasis, Inhibitor of Apoptosis Proteins genetics, Inhibitor of Apoptosis Proteins metabolism, Insulin metabolism, Lipid Metabolism, Membrane Potential, Mitochondrial, Real-Time Polymerase Chain Reaction, Sequence Analysis, DNA, Signal Transduction, Sirtuins genetics, Transcription Factors genetics, Transcription Factors metabolism, Drosophila genetics, Drosophila Proteins metabolism, Fat Body physiology, Histone Deacetylases metabolism, Mitochondria physiology, Muscles physiology, Sirtuins metabolism

Abstract

Sir2 is an evolutionarily conserved NAD(+)-dependent deacetylase which has been shown to play a critical role in glucose and fat metabolism. In this study, we have perturbed Drosophila Sir2 (dSir2) expression, bidirectionally, in muscles and the fat body. We report that dSir2 plays a critical role in insulin signaling, glucose homeostasis, and mitochondrial functions. Importantly, we establish the nonautonomous functions of fat body dSir2 in regulating mitochondrial physiology and insulin signaling in muscles. We have identified a novel interplay between dSir2 and dFOXO at an organismal level, which involves Drosophila insulin-like peptide (dILP)-dependent insulin signaling. By genetic perturbations and metabolic rescue, we provide evidence to illustrate that fat body dSir2 mediates its effects on the muscles via free fatty acids (FFA) and dILPs (from the insulin-producing cells [IPCs]). In summary, we show that fat body dSir2 is a master regulator of organismal energy homeostasis and is required for maintaining the metabolic regulatory network across tissues.

Published

2013

9. Drosophila Met and Gce are partially redundant in transducing juvenile hormone action.

Author

Abdou MA, He Q, Wen D, Zyaan O, Wang J, Xu J, Baumann AA, Joseph J, Wilson TG, Li S, and Wang J

Subjects

Animals, Basic Helix-Loop-Helix Transcription Factors genetics, Cell Death, Drosophila genetics, Drosophila growth & development, Drosophila Proteins genetics, Fat Body physiology, Female, Kruppel-Like Transcription Factors metabolism, Male, Mutation, Signal Transduction, Transcription Factors genetics, Basic Helix-Loop-Helix Transcription Factors metabolism, Drosophila metabolism, Drosophila Proteins metabolism, Juvenile Hormones metabolism, Transcription Factors metabolism

Abstract

The Drosophila Methoprene-tolerant (Met) and Germ cell-expressed (Gce) bHLH-PAS transcription factors are products of two paralogous genes. Both proteins potentially mediate the effect of juvenile hormone (JH) as candidate JH receptors. Here we report that Met and Gce are partially redundant in transducing JH action. Both Met and gce null single mutants are fully viable, but the Met gce double mutant, Met(27) gce(2.5k), dies during the larval-pupal transition. Precocious and enhanced caspase-dependent programmed cell death (PCD) appears in fat body cells of Met(27) gce(2.5k) during the early larval stages. Expression of Kr-h1, a JH response gene that inhibits 20-hydroxyecdysone (20E)-induced broad (br) expression, is abolished in Met(27) gce(2.5k) during larval molts. Consequently, expression of br occurs precociously in Met(27) gce(2.5k), which may cause precocious caspase-dependent PCD during the early larval stages. Defective phenotypes and gene expression changes in Met(27) gce(2.5k) double mutants are similar to those found in JH-deficient animals. Importantly, exogenous application of JH agonists rescued the JH-deficient animals but not the Met(27) gce(2.5k) mutants. Our data suggest a model in which Drosophila Met and Gce redundantly transduce JH action to prevent 20E-induced caspase-dependent PCD during larval molts by induction of Kr-h1 expression and inhibition of br expression., (Copyright © 2011 Elsevier Ltd. All rights reserved.)

Published

2011

10. Juvenile hormone counteracts the bHLH-PAS transcription factors MET and GCE to prevent caspase-dependent programmed cell death in Drosophila.

Author

Liu Y, Sheng Z, Liu H, Wen D, He Q, Wang S, Shao W, Jiang RJ, An S, Sun Y, Bendena WG, Wang J, Gilbert LI, Wilson TG, Song Q, and Li S

Subjects

Animals, Apoptosis drug effects, Caspases genetics, Corpora Allata growth & development, Corpora Allata physiology, Drosophila growth & development, Drosophila metabolism, Drosophila Proteins genetics, Ecdysone analogs & derivatives, Ecdysone pharmacology, Fat Body growth & development, Fat Body physiology, Gene Expression Regulation, Developmental, Juvenile Hormones pharmacology, Larva growth & development, Larva physiology, Metamorphosis, Biological, Methoprene metabolism, Apoptosis physiology, Basic Helix-Loop-Helix Transcription Factors metabolism, Caspases metabolism, Drosophila physiology, Drosophila Proteins metabolism, Juvenile Hormones physiology, Receptors, Steroid metabolism, Transcription Factors metabolism

Abstract

Juvenile hormone (JH) regulates many developmental and physiological events in insects, but its molecular mechanism remains conjectural. Here we report that genetic ablation of the corpus allatum cells of the Drosophila ring gland (the JH source) resulted in JH deficiency, pupal lethality and precocious and enhanced programmed cell death (PCD) of the larval fat body. In the fat body of the JH-deficient animals, Dronc and Drice, two caspase genes that are crucial for PCD induced by the molting hormone 20-hydroxyecdysone (20E), were significantly upregulated. These results demonstrated that JH antagonizes 20E-induced PCD by restricting the mRNA levels of Dronc and Drice. The antagonizing effect of JH on 20E-induced PCD in the fat body was further confirmed in the JH-deficient animals by 20E treatment and RNA interference of the 20E receptor EcR. Moreover, MET and GCE, the bHLH-PAS transcription factors involved in JH action, were shown to induce PCD by upregulating Dronc and Drice. In the Met- and gce-deficient animals, Dronc and Drice were downregulated, whereas in the Met-overexpression fat body, Dronc and Drice were significantly upregulated leading to precocious and enhanced PCD, and this upregulation could be suppressed by application of the JH agonist methoprene. For the first time, we demonstrate that JH counteracts MET and GCE to prevent caspase-dependent PCD in controlling fat body remodeling and larval-pupal metamorphosis in Drosophila.

Published

2009

11. An RGS-containing sorting nexin controls Drosophila lifespan.

Author

Suh JM, Stenesen D, Peters JM, Inoue A, Cade A, and Graff JM

Subjects

5' Untranslated Regions, Animals, Animals, Genetically Modified, Carrier Proteins chemistry, Drosophila genetics, Fat Body physiology, Larva physiology, Mutation, Sorting Nexins, Vesicular Transport Proteins chemistry, Carrier Proteins physiology, Drosophila physiology, Longevity, Oligopeptides chemistry, Vesicular Transport Proteins physiology

Abstract

The pursuit of eternal youth has existed for centuries and recent data indicate that fat-storing tissues control lifespan. In a D. melanogaster fat body insertional mutagenic enhancer trap screen designed to isolate genes that control longevity, we identified a regulator of G protein signaling (RGS) domain containing sorting nexin, termed snazarus (sorting nexin lazarus, snz). Flies with insertions into the 5' UTR of snz live up to twice as long as controls. Transgenic expression of UAS-Snz from the snz Gal4 enhancer trap insertion, active in fat metabolic tissues, rescued lifespan extension. Further, the lifespan extension of snz mutants was independent of endosymbiont, e.g., Wolbachia, effects. Notably, old snz mutant flies remain active and fertile indicating that snz mutants have prolonged youthfulness, a goal of aging research. Since mammals have snz-related genes, it is possible that the functions of the snz family may be conserved to humans.

Published

2008

12. Drosophila immunity: is antigen processing the first step?

Author

Hultmark D and Borge-Renberg K

Subjects

Animals, Antigen Presentation physiology, Drosophila immunology, Fat Body physiology, Hemocytes physiology, Phagocytosis physiology

Abstract

A new genetic study has shown that the phagocytic ability of Drosophila blood cells, the hemocytes, may be important for the further induction of an antibacterial response in other tissues.

Published

2007

13. Loss of glial lazarillo, a homolog of apolipoprotein D, reduces lifespan and stress resistance in Drosophila.

Author

Sanchez D, López-Arias B, Torroja L, Canal I, Wang X, Bastiani MJ, and Ganfornina MD

Subjects

Animals, Apoptosis, Behavior, Animal, Carrier Proteins genetics, Carrier Proteins metabolism, Drosophila cytology, Drosophila genetics, Drosophila Proteins genetics, Drosophila Proteins metabolism, Fat Body cytology, Fat Body physiology, Hemocytes cytology, Hemocytes metabolism, Lipid Metabolism, Lipid Peroxidation, Membrane Glycoproteins genetics, Membrane Glycoproteins metabolism, Motor Activity genetics, Motor Activity physiology, Mutation, Neuroglia cytology, Neuroglia metabolism, Oxidative Stress, Promoter Regions, Genetic, Recombinant Fusion Proteins metabolism, Starvation, Carrier Proteins physiology, Drosophila metabolism, Drosophila Proteins physiology, Longevity genetics, Membrane Glycoproteins physiology

Abstract

The vertebrate Apolipoprotein D (ApoD) is a lipocalin secreted from subsets of neurons and glia during neural development and aging . A strong correlation exists between ApoD overexpression and numerous nervous system pathologies as well as obesity, diabetes, and many forms of cancer . However, the exact relationship between the function of ApoD and the pathophysiology of these diseases is still unknown. We have generated loss-of-function Drosophila mutants for the Glial Lazarillo (GLaz) gene , a homolog of ApoD in the fruit fly, mainly expressed in subsets of adult glial cells. The absence of GLaz reduces the organism's resistance to oxidative stress and starvation and shortens male lifespan. The mutant flies exhibit a smaller body mass due to a lower amount of neutral lipids stored in the fat body. Apoptotic neural cell death increases in aged flies or upon paraquat treatment, which also impairs neural function as assessed by behavioral tests. The higher sensitivity to oxidative stress and starvation and the reduced fat storage revert to control levels when a GFP-GLaz fusion protein is expressed under the control of the GLaz natural promoter. Finally, GLaz mutants have a higher concentration of lipid peroxidation products, pointing to a lipid peroxidation protection or scavenging as the mechanism of action for this lipocalin. In agreement with Walker et al. (, in this issue of Current Biology), who analyze the effects of overexpressing GLaz, we conclude that GLaz has a protective role in stress situations and that its absence reduces lifespan and accelerates neurodegeneration.

Published

2006

14. Role and regulation of starvation-induced autophagy in the Drosophila fat body.

Author

Scott RC, Schuldiner O, and Neufeld TP

Subjects

Animals, Autophagy-Related Proteins, Cell Division, Cell Survival, Cytoplasm metabolism, Drosophila Proteins physiology, Drosophila melanogaster, Food Deprivation, Gene Expression Regulation, Developmental, Lysosomes metabolism, Microscopy, Electron, Models, Biological, Phagocytosis, Phenotype, Phosphatidylinositol 3-Kinases metabolism, Phosphatidylinositol 3-Kinases physiology, Protein Kinases physiology, Ribosomal Protein S6 Kinases metabolism, Saccharomyces cerevisiae Proteins physiology, Signal Transduction, TOR Serine-Threonine Kinases, Time Factors, Autophagy, Drosophila physiology, Fat Body physiology

Abstract

In response to starvation, eukaryotic cells recover nutrients through autophagy, a lysosomal-mediated process of cytoplasmic degradation. Autophagy is known to be inhibited by TOR signaling, but the mechanisms of autophagy regulation and its role in TOR-mediated cell growth are unclear. Here, we show that signaling through TOR and its upstream regulators PI3K and Rheb is necessary and sufficient to suppress starvation-induced autophagy in the Drosophila fat body. In contrast, TOR's downstream effector S6K promotes rather than suppresses autophagy, suggesting S6K downregulation may limit autophagy during extended starvation. Despite the catabolic potential of autophagy, disruption of conserved components of the autophagic machinery, including ATG1 and ATG5, does not restore growth to TOR mutant cells. Instead, inhibition of autophagy enhances TOR mutant phenotypes, including reduced cell size, growth rate, and survival. Thus, in cells lacking TOR, autophagy plays a protective role that is dominant over its potential role as a growth suppressor.

Published

2004

15. Programmed autophagy in the Drosophila fat body is induced by ecdysone through regulation of the PI3K pathway.

Author

Rusten TE, Lindmo K, Juhász G, Sass M, Seglen PO, Brech A, and Stenmark H

Subjects

Amino Acids metabolism, Animals, Animals, Genetically Modified, Brain metabolism, Down-Regulation, Food Deprivation, Gene Library, Green Fluorescent Proteins, Humans, Immunosuppressive Agents pharmacology, Luminescent Proteins metabolism, Microscopy, Fluorescence, Models, Biological, Signal Transduction, Sirolimus pharmacology, Time Factors, Autophagy, Drosophila embryology, Drosophila physiology, Ecdysone metabolism, Fat Body physiology, Gene Expression Regulation, Developmental, Phosphatidylinositol 3-Kinases metabolism

Abstract

Eukaryotic cells catabolize their own cytoplasm by autophagy in response to amino acid starvation and inductive signals during programmed tissue remodeling and cell death. The Tor and PI3K signaling pathways have been shown to negatively control autophagy in eukaryotes, but the mechanisms that link these effectors to overall animal development and nutritional status in multicellular organisms remain poorly understood. Here, we reveal a complex regulation of programmed and starvation-induced autophagy in the Drosophila fat body. Gain-of-function genetic analysis indicated that ecdysone receptor signaling induces programmed autophagy whereas PI3K signaling represses programmed autophagy. Genetic interaction studies showed that ecdysone signaling downregulates PI3K signaling and that this represents the effector mechanism for induction of programmed autophagy. Hence, these studies link hormonal induction of autophagy to the regulatory function of the PI3K signaling pathway in vivo.

Published

2004

16. Control of fat storage by a Drosophila PAT domain protein.

Author

Grönke S, Beller M, Fellert S, Ramakrishnan H, Jäckle H, and Kühnlein RP

Subjects

Animals, Blotting, Northern, Carrier Proteins, Chromosome Mapping, Drosophila Proteins genetics, Gene Expression Profiling, Perilipin-1, Phosphoproteins physiology, Phylogeny, Drosophila genetics, Drosophila physiology, Drosophila Proteins physiology, Fat Body physiology

Abstract

In Drosophila, the masses and sheets of adipose tissue that are distributed throughout the fly are collectively called the fat body. Like mammalian adipocytes, insect fat body cells provide the major energy reserve of the animal organism. Both cell types accumulate triacylglycerols (TAG) in intracellular lipid droplets; this finding suggests that the strategy of energy storage as well as the machinery and the control to achieve fat storage might be evolutionarily conserved. Studies addressing the control of lipid-based energy homeostasis of mammals identified proteins of the PAT domain family, such as Perilipin, which reside on lipid droplets. Perilipin knockout mice are lean and resistant to diet-induced obesity. Conversely, Perilipin expression in preadipocyte tissue culture increases lipid storage by reducing the rate of TAG hydrolysis. Factors that mediate corresponding processes in invertebrates are still unknown. We examined the function of Lsd2, one of only two PAT domain-encoding genes in the Drosophila genome. Lsd2 acts in a Perilipin-like manner, suggesting that components regulating homeostasis of lipid-based energy storage at the lipid droplet membrane are evolutionarily conserved.

Published

2003

17. The Drosophila takeout gene is regulated by the somatic sex-determination pathway and affects male courtship behavior.

Author

Dauwalder B, Tsujimoto S, Moss J, and Mattox W

Subjects

Amino Acid Sequence, Animals, Animals, Genetically Modified, Brain physiology, Circadian Rhythm genetics, DNA-Binding Proteins genetics, DNA-Binding Proteins metabolism, Drosophila Proteins genetics, Fat Body physiology, Female, Gene Expression Regulation, Developmental, Insect Proteins genetics, Male, Molecular Sequence Data, Mutation, Nerve Tissue Proteins genetics, Nerve Tissue Proteins metabolism, Ribonucleoproteins genetics, Ribonucleoproteins metabolism, Sequence Homology, Amino Acid, Transcription Factors genetics, Transcription Factors metabolism, Behavior, Animal physiology, Courtship, Drosophila physiology, Drosophila Proteins metabolism, Insect Proteins metabolism, Sex Determination Processes

Abstract

The Drosophila somatic sex-determination regulatory pathway has been well studied, but little is known about the target genes that it ultimately controls. In a differential screen for sex-specific transcripts expressed in fly heads, we identified a highly male-enriched transcript encoding Takeout, a protein related to a superfamily of factors that bind small lipophilic molecules. We show that sex-specific takeout transcripts derive from fat body tissue closely associated with the adult brain and are dependent on the sex determination genes doublesex (dsx) and fruitless (fru). The male-specific Doublesex and Fruitless proteins together activate Takeout expression, whereas the female-specific Doublesex protein represses takeout independently of Fru. When cells that normally express takeout are feminized by expression of the Transformer-F protein, male courtship behavior is dramatically reduced, suggesting that male identity in these cells is necessary for behavior. A loss-of-function mutation in the takeout gene reduces male courtship and synergizes with fruitless mutations, suggesting that takeout plays a redundant role with other fru-dependent factors involved in male mating behavior. Comparison of Takeout sequences to the Drosophila genome reveals a family of 20 related secreted factors. Expression analysis of a subset of these genes suggests that the takeout gene family encodes multiple factors with sex-specific functions.

Published

2002

18. Suppression of food intake and growth by amino acids in Drosophila: the role of pumpless, a fat body expressed gene with homology to vertebrate glycine cleavage system.

Author

Zinke I, Kirchner C, Chao LC, Tetzlaff MT, and Pankratz MJ

Subjects

Amino Acid Oxidoreductases metabolism, Amino Acid Sequence, Amino Acids metabolism, Amino Acids pharmacology, Animals, Carrier Proteins metabolism, Drosophila embryology, Drosophila growth & development, Embryo, Nonmammalian, Gene Expression Regulation, Developmental, Larva, Molecular Sequence Data, Multienzyme Complexes metabolism, Mutation, Sequence Homology, Amino Acid, Starvation, Transferases metabolism, Vertebrates physiology, Amino Acid Oxidoreductases genetics, Carrier Proteins genetics, Drosophila genetics, Drosophila Proteins, Eating genetics, Fat Body physiology, Insect Proteins genetics, Insect Proteins metabolism, Multienzyme Complexes genetics, Transferases genetics

Abstract

We have isolated a Drosophila mutant, named pumpless, which is defective in food intake and growth at the larval stage. pumpless larvae can initially feed normally upon hatching. However, during late first instar stage, they fail to pump the food from the pharynx into the esophagus and concurrently begin moving away from the food source. Although pumpless larvae do not feed, they do not show the typical physiologic response of starving animals, such as upregulating genes involved in gluconeogenesis or lipid breakdown. The pumpless gene is expressed specifically in the fat body and encodes a protein with homology to a vertebrate enzyme involved in glycine catabolism. Feeding wild-type larvae high levels of amino acids could phenocopy the feeding and growth defects of pumpless mutants. Our data suggest the existence of an amino acid-dependent signal arising from the fat body that induces cessation of feeding in the larva. This signaling system may also mediate growth transition from larval to the pupal stage during Drosophila development.

Published

1999