Your search keyword '"Tennessen, Jason M."' showing total 22 results

1. Auxin exposure disrupts feeding behavior and fatty acid metabolism in adult Drosophila .

Author

Fleck SA, Biswas P, DeWitt ED, Knuteson RL, Eisman RC, Nemkov T, D'Alessandro A, Tennessen JM, Rideout E, and Weaver LN

Subjects

Animals, Drosophila melanogaster physiology, Indoleacetic Acids metabolism, Feeding Behavior physiology, Fatty Acids metabolism, Drosophila metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism

Abstract

The ease of genetic manipulation in Drosophila melanogaster using the Gal4/UAS system has been beneficial in addressing key biological questions. Current modifications of this methodology to temporally induce transgene expression require temperature changes or exposure to exogenous compounds, both of which have been shown to have detrimental effects on physiological processes. The recently described auxin-inducible gene expression system (AGES) utilizes the plant hormone auxin to induce transgene expression and is proposed to be the least toxic compound for genetic manipulation, with no obvious effects on Drosophila development and survival in one wild-type strain. Here, we show that auxin delays larval development in another widely used fly strain, and that short- and long-term auxin exposure in adult Drosophila induces observable changes in physiology and feeding behavior. We further reveal a dosage response to adult survival upon auxin exposure, and that the recommended auxin concentration for AGES alters feeding activity. Furthermore, auxin-fed male and female flies exhibit a significant decrease in triglyceride levels and display altered transcription of fatty acid metabolism genes. Although fatty acid metabolism is disrupted, auxin does not significantly impact adult female fecundity or progeny survival, suggesting AGES may be an ideal methodology for studying limited biological processes. These results emphasize that experiments using temporal binary systems must be carefully designed and controlled to avoid confounding effects and misinterpretation of results., Competing Interests: SF, PB, ED, RK, RE, TN, AD, JT, ER, LW No competing interests declared, (© 2023, Fleck et al.)

Published

2024

2. Perspectives on the Drosophila melanogaster Model for Advances in Toxicological Science.

Author

Rand MD, Tennessen JM, Mackay TFC, and Anholt RRH

Subjects

Animals, Humans, Environmental Exposure, Genomics, Drosophila, Drosophila melanogaster genetics

Abstract

The use of Drosophila melanogaster for studies of toxicology has grown considerably in the last decade. The Drosophila model has long been appreciated as a versatile and powerful model for developmental biology and genetics because of its ease of handling, short life cycle, low cost of maintenance, molecular genetic accessibility, and availability of a wide range of publicly available strains and data resources. These features, together with recent unique developments in genomics and metabolomics, make the fly model especially relevant and timely for the development of new approach methodologies and movements toward precision toxicology. Here, we offer a perspective on how flies can be leveraged to identify risk factors relevant to environmental exposures and human health. First, we review and discuss fundamental toxicologic principles for experimental design with Drosophila. Next, we describe quantitative and systems genetics approaches to resolve the genetic architecture and candidate pathways controlling susceptibility to toxicants. Finally, we summarize the current state and future promise of the emerging field of Drosophila metabolomics for elaborating toxic mechanisms. © 2023 The Authors. Current Protocols published by Wiley Periodicals LLC., (© 2023 The Authors. Current Protocols published by Wiley Periodicals LLC.)

Published

2023

3. Assessment of Chemical Toxicity in Adult Drosophila Melanogaster.

Author

Holsopple JM, Smoot SR, Popodi EM, Colbourne JK, Shaw JR, Oliver B, Kaufman TC, and Tennessen JM

Subjects

Animals, Adult, Humans, Genomics, Feeding Behavior, Risk Assessment, Mammals, Drosophila melanogaster, Drosophila

Abstract

Human industries generate hundreds of thousands of chemicals, many of which have not been adequately studied for environmental safety or effects on human health. This deficit of chemical safety information is exacerbated by current testing methods in mammals that are expensive, labor-intensive, and time-consuming. Recently, scientists and regulators have been working to develop new approach methodologies (NAMs) for chemical safety testing that are cheaper, more rapid, and reduce animal suffering. One of the key NAMs to emerge is the use of invertebrate organisms as replacements for mammalian models to elucidate conserved chemical modes of action across distantly related species, including humans. To advance these efforts, here, we describe a method that uses the fruit fly, Drosophila melanogaster, to assess chemical safety. The protocol describes a simple, rapid, and inexpensive procedure to measure the viability and feeding behavior of exposed adult flies. In addition, the protocol can be easily adapted to generate samples for genomic and metabolomic approaches. Overall, the protocol represents an important step forward in establishing Drosophila as a standard model for use in precision toxicology.

Published

2023

4. The oncometabolite L-2-hydroxyglutarate is a common product of dipteran larval development.

Author

Mahmoudzadeh NH, Fitt AJ, Schwab DB, Martenis WE, Nease LM, Owings CG, Brinkley GJ, Li H, Karty JA, Sudarshan S, Hardy RW, Moczek AP, Picard CJ, and Tennessen JM

Subjects

Aedes growth & development, Animals, Calliphoridae growth & development, Drosophila growth & development, Larva growth & development, Larva metabolism, Aedes metabolism, Calliphoridae metabolism, Drosophila metabolism, Glutarates metabolism

Abstract

The oncometabolite L-2-hydroxyglutarate (L-2HG) is considered an abnormal product of central carbon metabolism that is capable of disrupting chromatin architecture, mitochondrial metabolism, and cellular differentiation. Under most circumstances, mammalian tissues readily dispose of this compound, as aberrant L-2HG accumulation induces neurometabolic disorders and promotes renal cell carcinomas. Intriguingly, Drosophila melanogaster larvae were recently found to accumulate high L-2HG levels under normal growth conditions, raising the possibility that L-2HG plays a unique role in insect metabolism. Here we explore this hypothesis by analyzing L-2HG levels in 18 insect species. While L-2HG was present at low-to-moderate levels in most of these species (<100 pmol/mg; comparable to mouse liver), dipteran larvae exhibited a tendency to accumulate high L-2HG concentrations (>100 pmol/mg), with the mosquito Aedes aegypti, the blow fly Phormia regina, and three representative Drosophila species harboring concentrations that exceed 1 nmol/mg - levels comparable to those measured in mutant mice that are unable to degrade L-2HG. Overall, our findings suggest that one of the largest groups of animals on earth commonly generate high concentrations of an oncometabolite during juvenile growth, hint at a role for L-2HG in the evolution of dipteran development, and raise the possibility that L-2HG metabolism could be targeted to restrict the growth of key disease vectors and agricultural pests., (Copyright © 2020 Elsevier Ltd. All rights reserved.)

Published

2020

5. Drosophila macrophages switch to aerobic glycolysis to mount effective antibacterial defense.

Author

Krejčová G, Danielová A, Nedbalová P, Kazek M, Strych L, Chawla G, Tennessen JM, Lieskovská J, Jindra M, Doležal T, and Bajgar A

Subjects

Aerobiosis, Animals, Drosophila immunology, Glycolysis, Macrophages immunology, Macrophages metabolism, Streptococcal Infections immunology, Streptococcus immunology

Abstract

Macrophage-mediated phagocytosis and cytokine production represent the front lines of resistance to bacterial invaders. A key feature of this pro-inflammatory response in mammals is the complex remodeling of cellular metabolism towards aerobic glycolysis. Although the function of bactericidal macrophages is highly conserved, the metabolic remodeling of insect macrophages remains poorly understood. Here, we used adults of the fruit fly Drosophila melanogaster to investigate the metabolic changes that occur in macrophages during the acute and resolution phases of Streptococcus -induced sepsis. Our studies revealed that orthologs of Hypoxia inducible factor 1α (HIF1α) and Lactate dehydrogenase (LDH) are required for macrophage activation, their bactericidal function, and resistance to infection, thus documenting the conservation of this cellular response between insects and mammals. Further, we show that macrophages employing aerobic glycolysis induce changes in systemic metabolism that are necessary to meet the biosynthetic and energetic demands of their function and resistance to bacterial infection., Competing Interests: GK, AD, PN, MK, LS, GC, JT, JL, MJ, TD, AB No competing interests declared, (© 2019, Krejčová et al.)

Published

2019

6. Preparation of Drosophila Larval Samples for Gas Chromatography-Mass Spectrometry (GC-MS)-based Metabolomics.

Author

Li H and Tennessen JM

Subjects

Animals, Drosophila metabolism, Drosophila melanogaster metabolism, Gas Chromatography-Mass Spectrometry methods, Metabolomics methods

Abstract

Recent advances in the field of metabolomics have established the fruit fly Drosophila melanogaster as a powerful genetic model for studying animal metabolism. By combining the vast array of Drosophila genetic tools with the ability to survey large swaths of intermediary metabolism, a metabolomics approach can reveal complex interactions between diet, genotype, life-history events, and environmental cues. In addition, metabolomics studies can discover novel enzymatic mechanisms and uncover previously unknown connections between seemingly disparate metabolic pathways. In order to facilitate more widespread use of this technology among the Drosophila community, here we provide a detailed protocol that describes how to prepare Drosophila larval samples for gas chromatography-mass spectrometry (GC-MS)-based metabolomic analysis. Our protocol includes descriptions of larval sample collection, metabolite extraction, chemical derivatization, and GC-MS analysis. Successful completion of this protocol will allow users to measure the relative abundance of small polar metabolites, including amino acids, sugars, and organic acids involved in glycolysis and the TCA cycles.

Published

2018

7. Metabolomic Studies in Drosophila .

Author

Cox JE, Thummel CS, and Tennessen JM

Subjects

Animals, Drosophila metabolism, Drosophila Proteins genetics, Drosophila Proteins metabolism, Metabolomics trends, Drosophila genetics, Metabolome genetics, Metabolomics methods

Abstract

Metabolomic analysis provides a powerful new tool for studies of Drosophila physiology. This approach allows investigators to detect thousands of chemical compounds in a single sample, representing the combined contributions of gene expression, enzyme activity, and environmental context. Metabolomics has been used for a wide range of studies in Drosophila , often providing new insights into gene function and metabolic state that could not be obtained using any other approach. In this review, we survey the uses of metabolomic analysis since its entry into the field. We also cover the major methods used for metabolomic studies in Drosophila and highlight new directions for future research., (Copyright © 2017 by the Genetics Society of America.)

Published

2017

8. Methods for studying metabolism in Drosophila.

Author

Tennessen JM, Barry WE, Cox J, and Thummel CS

Subjects

Animals, Drosophila genetics, Drosophila metabolism, Gas Chromatography-Mass Spectrometry methods, Metabolomics

Abstract

Recent research using Drosophila melanogaster has seen a resurgence in studies of metabolism and physiology. This review focuses on major methods used to conduct this work. These include protocols for dietary interventions, measurements of triglycerides, cholesterol, glucose, trehalose, and glycogen, stains for lipid detection, and the use of gas chromatography-mass spectrometry (GC-MS) to detect major polar metabolites. It is our hope that this will provide a useful framework for both new and current researchers in the field., (Copyright © 2014 Elsevier Inc. All rights reserved.)

Published

2014

9. Coordinated metabolic transitions during Drosophila embryogenesis and the onset of aerobic glycolysis.

Author

Tennessen JM, Bertagnolli NM, Evans J, Sieber MH, Cox J, and Thummel CS

Subjects

Amino Acids metabolism, Animals, Cluster Analysis, Drosophila genetics, Energy Metabolism, Fatty Acids metabolism, Female, Gene Expression Profiling, Gene Expression Regulation, Developmental, Glycolysis, Male, Metabolomics, Mitochondria genetics, Mitochondria metabolism, Transcriptional Activation, Tricarboxylic Acids metabolism, Drosophila embryology, Drosophila metabolism, Embryonic Development physiology, Metabolome

Abstract

Rapidly proliferating cells such as cancer cells and embryonic stem cells rely on a specialized metabolic program known as aerobic glycolysis, which supports biomass production from carbohydrates. The fruit fly Drosophila melanogaster also utilizes aerobic glycolysis to support the rapid growth that occurs during larval development. Here we use singular value decomposition analysis of modENCODE RNA-seq data combined with GC-MS-based metabolomic analysis to analyze the changes in gene expression and metabolism that occur during Drosophila embryogenesis, spanning the onset of aerobic glycolysis. Unexpectedly, we find that the most common pattern of co-expressed genes in embryos includes the global switch to glycolytic gene expression that occurs midway through embryogenesis. In contrast to the canonical aerobic glycolytic pathway, however, which is accompanied by reduced mitochondrial oxidative metabolism, the expression of genes involved in the tricarboxylic cycle (TCA cycle) and the electron transport chain are also upregulated at this time. Mitochondrial activity, however, appears to be attenuated, as embryos exhibit a block in the TCA cycle that results in elevated levels of citrate, isocitrate, and α-ketoglutarate. We also find that genes involved in lipid breakdown and β-oxidation are upregulated prior to the transcriptional initiation of glycolysis, but are downregulated before the onset of larval development, revealing coordinated use of lipids and carbohydrates during development. These observations demonstrate the efficient use of nutrient stores to support embryonic development, define sequential metabolic transitions during this stage, and demonstrate striking similarities between the metabolic state of late-stage fly embryos and tumor cells., (Copyright © 2014 Tennessen et al.)

Published

2014

10. The Drosophila estrogen-related receptor directs a metabolic switch that supports developmental growth.

Author

Tennessen JM, Baker KD, Lam G, Evans J, and Thummel CS

Subjects

Animals, Carbohydrate Metabolism genetics, Drosophila embryology, Drosophila growth & development, Drosophila Proteins genetics, Embryonic Development, Gene Expression Regulation, Developmental, Glycolysis genetics, Larva metabolism, Mutation, Receptors, Estrogen genetics, Drosophila metabolism, Drosophila Proteins metabolism, Receptors, Estrogen metabolism

Abstract

Metabolism must be coordinated with development to provide the appropriate energetic needs for each stage in the life cycle. Little is known, however, about how this temporal control is achieved. Here, we show that the Drosophila ortholog of the estrogen-related receptor (ERR) family of nuclear receptors directs a critical metabolic transition during development. dERR mutants die as larvae with low ATP levels and elevated levels of circulating sugars. The expression of active dERR protein in mid-embryogenesis triggers a coordinate switch in gene expression that drives a metabolic program normally associated with proliferating cells, supporting the dramatic growth that occurs during larval development. This study shows that dERR plays a central role in carbohydrate metabolism, demonstrates that a proliferative metabolic program is used in normal developmental growth, and provides a molecular context to understand the close association between mammalian ERR family members and cancer., (Copyright © 2011 Elsevier Inc. All rights reserved.)

Published

2011

11. Renal L-2-hydroxyglutarate dehydrogenase activity promotes hypoxia tolerance and mitochondrial metabolism in Drosophila melanogaster.

Author

Mahmoudzadeh, Nader H., Heidarian, Yasaman, Tourigny, Jason P., Fitt, Alexander J., Beebe, Katherine, Li, Hongde, Luhur, Arthur, Buddika, Kasun, Mungcal, Liam, Kundu, Anirban, Policastro, Robert A., Brinkley, Garrett J., Zentner, Gabriel E., Nemkov, Travis, Pepin, Robert, Chawla, Geetanjali, Sudarshan, Sunil, Rodan, Aylin R., D'Alessandro, Angelo, and Tennessen, Jason M.

Abstract

The mitochondrial enzyme L-2-hydroxyglutarate dehydrogenase (L2HGDH) regulates the abundance of L-2-hydroxyglutarate (L-2HG), a potent signaling metabolite capable of influencing chromatin architecture, mitochondrial metabolism, and cell fate decisions. Loss of L2hgdh activity in humans induces ectopic L-2HG accumulation, resulting in neurodevelopmental defects, altered immune cell function, and enhanced growth of clear cell renal cell carcinomas. To better understand the molecular mechanisms that underlie these disease pathologies, we used the fruit fly Drosophila melanogaster to investigate the endogenous functions of L2hgdh. L2hgdh mutant adult male flies were analyzed under normoxic and hypoxic conditions using a combination of semi-targeted metabolomics and RNA-seq. These multi-omic analyses were complemented by tissue-specific genetic studies that examined the effects of L2hgdh mutations on the Drosophila renal system (Malpighian tubules; MTs). Our studies revealed that while L2hgdh is not essential for growth or viability under standard culture conditions, L2hgdh mutants are hypersensitive to hypoxia and expire during the reoxygenation phase with severe disruptions of mitochondrial metabolism. Moreover, we find that the fly renal system is a key site of L2hgdh activity, as L2hgdh mutants that express a rescuing transgene within the MTs survive hypoxia treatment and exhibit normal levels of mitochondrial metabolites. We also demonstrate that even under normoxic conditions, L2hgdh mutant MTs experience significant metabolic stress and are sensitized to aberrant growth upon Egfr activation. These findings present a model in which renal L2hgdh activity limits systemic L-2HG accumulation, thus indirectly regulating the balance between glycolytic and mitochondrial metabolism, enabling successful recovery from hypoxia exposure, and ensuring renal tissue integrity. • Drosophila L2hgdh is not essential for growth or viability under standard culture conditions. • L2hgdh mutants are hypersensitive to hypoxia and expire during the reoxygenation phase with severe disruptions of mitochondrial metabolism. • The Drosophila renal system is a key site of L2hgdh activity. • L2hgdh mutant MTs experience significant metabolic stress and are sensitized to aberrant growth upon Egfr activation. [ABSTRACT FROM AUTHOR]

Published

2024

12. Balancing energy expenditure and storage with growth and biosynthesis during Drosophila development.

Author

Gillette, Claire M., Tennessen, Jason M., and Reis, Tânia

Subjects

*ENERGY storage, *DROSOPHILA, *DROSOPHILA melanogaster, *BIOSYNTHESIS, *NUTRITIONAL requirements, *CALORIC expenditure

Abstract

Sustaining life requires efficient uptake of nutrients and conversion to useable forms. Almost everything about this process is dynamic. Nutrient availability fluctuates and changing environmental conditions impose new demands that can tip the metabolic equilibrium from biosynthesis and macromolecule storage to energy expenditure. At the same time, the organism itself changes, particularly during the rapid growth and differentiation in early development and also later in life as the adult ages. Here we review what has been learned from Drosophila melanogaster as an experimental model about the connections between external signals, signaling pathways, tissues and organs that allow animals to balance energy storage with expenditure in the face of change, both intrinsic and extrinsic. • Drosophila melanogaster is a powerful experimental system to study energy balance. • Communication between different organs/tissues is key for maintaining energy balance. • Nutritional requirements vary between different stages of organismal development. • Conserved signaling pathways link energy expenditure and storage to availability. [ABSTRACT FROM AUTHOR]

Published

2021

13. Reclaiming Warburg: using developmental biology to gain insight into human metabolic diseases.

Author

Drummond-Barbosa, Daniela and Tennessen, Jason M.

Subjects

*METABOLIC disorders, *CYTOLOGY, *BIOLOGISTS, *CELL cycle, *DEVELOPMENTAL biology, *CELL death

Abstract

Developmental biologists have frequently pushed the frontiers of modern biomedical research. From the discovery and characterization of novel signal transduction pathways to exploring the molecular underpinnings of genetic inheritance, transcription, the cell cycle, cell death and stem cell biology, studies of metazoan development have historically opened new fields of study and consistently revealed previously unforeseen avenues of clinical therapies. From this perspective, it is not surprising that our community is now an integral part of the current renaissance in metabolic research. Amidst the global rise in metabolic syndrome, the discovery of novel signaling roles for metabolites, and the increasing links between altered metabolism and many human diseases, we as developmental biologists can contribute skills and expertise that are uniquely suited for investigating the mechanisms underpinning humanmetabolic health and disease. Here, we summarize the opportunities and challenges that our community faces, and discuss how developmental biologists canmake unique and valuable contributions to the field of metabolism and physiology. [ABSTRACT FROM AUTHOR]

Published

2020

14. Drosophila larvae synthesize the putative oncometabolite L-2-hydroxyglutarate during normal developmental growth.

Author

Hongde Li, Chawla, Geetanjali, Hurlburt, Alexander J., Sterrett, Maria C., Zaslaver, Olga, Cox, James, Karty, Jonathan A., Rosebrock, Adam P., Caudy, Amy A., and Tennessen, Jason M.

Subjects

DROSOPHILA, CELL differentiation, GLYCOLYSIS, DEHYDROGENASE genetics, DNA methylation

Abstract

L-2-hydroxyglutarate (L-2HG) has emerged as a putative oncometabolite that is capable of inhibiting enzymes involved in metabolism, chromatin modification, and cell differentiation. However, despite the ability of L-2HG to interfere with a broad range of cellular processes, this molecule is often characterized as a metabolic waste product. Here, we demonstrate that Drosophila larvae use the metabolic conditions established by aerobic glycolysis to both synthesize and accumulate high concentrations of L-2HG during normal developmental growth. A majority of the larval L-2HG pool is derived from glucose and dependent on the Drosophila estrogen-related receptor (dERR), which promotes L-2HG synthesis by up-regulating expression of the Drosophila homolog of lactate dehydrogenase (dLdh). We also show that dLDH is both necessary and sufficient for directly synthesizing L-2HG and the Drosophila homolog of L-2-hydroxyglutarate dehydrogenase (dL2HGDH), which encodes the enzyme that breaks down L-2HG, is required for stage-specific degradation of the L-2HG pool. In addition, dLDH also indirectly promotes L-2HG accumulation via synthesis of lactate, which activates a metabolic feedforward mechanism that inhibits dL2HGDH activity and stabilizes L-2HG levels. Finally, we use a genetic approach to demonstrate that dLDH and L-2HG influence position effect variegation and DNA methylation, suggesting that this compound serves to coordinate glycolytic flux with epigenetic modifications. Overall, our studies demonstrate that growing animal tissues synthesize L-2HG in a controlled manner, reveal a mechanism that coordinates glucose catabolism with L-2HG synthesis, and establish the fly as a unique model system for studying the endogenous functions of L-2HG during cell growth and proliferation. [ABSTRACT FROM AUTHOR]

Published

2017

15. Drosophila HNF4 Regulates Lipid Mobilization and β-Oxidation.

Author

Palanker, Laura, Tennessen, Jason M., Lam, Geanette, and Thummel, Carl S.

Subjects

LIPID metabolism, NUCLEAR receptors (Biochemistry), DNA microarrays, DROSOPHILA

Abstract

Summary: Drosophila HNF4 (dHNF4) is the single ancestral ortholog of a highly conserved subfamily of nuclear receptors that includes two mammalian receptors, HNFα and HNFγ, and 269 members in C. elegans. We show here that dHNF4 null mutant larvae are sensitive to starvation. Starved mutant larvae consume glycogen normally but retain lipids in their midgut and fat body and have increased levels of long-chain fatty acids, suggesting that they are unable to efficiently mobilize stored fat for energy. Microarray studies support this model, indicating reduced expression of genes that control lipid catabolism and β-oxidation. A GAL4-dHNF4;UAS-lacZ ligand sensor can be activated by starvation or exogenous long-chain fatty acids, suggesting that dHNF4 is responsive to dietary signals. Taken together, our results support a feed-forward model for dHNF4, in which fatty acids released from triglycerides activate the receptor, inducing enzymes that drive fatty acid oxidation for energy production. [Copyright &y& Elsevier]

Published

2009

16. Coordinating Growth and Maturation — Insights from Drosophila

Author

Tennessen, Jason M. and Thummel, Carl S.

Subjects

*DROSOPHILA, *ENVIRONMENTAL engineering, *DEVELOPMENTAL biology, *METABOLIC disorders, *GENETIC engineering, *LIFE history interviews

Abstract

Adult body size in higher animals is dependent on the amount of growth that occurs during the juvenile stage. The duration of juvenile development, therefore, must be flexible and responsive to environmental conditions. When immature animals experience environmental stresses such as malnutrition or disease, maturation can be delayed until conditions improve and normal growth can resume. In contrast, when animals are raised under ideal conditions that promote rapid growth, internal checkpoints ensure that maturation does not occur until juvenile development is complete. Although the mechanisms that regulate growth and gate the onset of maturation have been investigated for decades, the emerging links between childhood obesity, early onset puberty, and adult metabolic disease have placed a new emphasis on this field. Remarkably, genetic studies in the fruit fly Drosophila melanogaster have shown that the central regulatory pathways that control growth and the timing of sexual maturation are conserved through evolution, and suggest that this aspect of animal life history is regulated by a common genetic architecture. This review focuses on these conserved mechanisms and highlights recent studies that explore how Drosophila coordinates developmental growth with environmental conditions. [ABSTRACT FROM AUTHOR]

Published

2011

17. Developmental Timing: let-7 Function Conserved through Evolution

Author

Tennessen, Jason M. and Thummel, Carl S.

Subjects

*ANIMAL genetics, *BIOLOGICAL evolution, *PHYSIOLOGY, *RNA, *DROSOPHILA, *FRUIT flies

Abstract

Summary: Expression of the heterochronic microRNA let-7 is tightly correlated with the onset of adult development in many animals, suggesting that it functions as an evolutionarily conserved developmental timer. This hypothesis has now been confirmed by studies in Drosophila. [Copyright &y& Elsevier]

Published

2008

18. The Drosophila melanogaster enzyme glycerol-3-phosphate dehydrogenase 1 is required for oogenesis, embryonic development, and amino acid homeostasis.

Author

Rai, Madhulika, Carter, Sarah M., Shefali, Shefali A., Mahmoudzadeh, Nader H., Pepin, Robert, and Tennessen, Jason M.

Subjects

*DROSOPHILA melanogaster, *EMBRYOLOGY, *OOGENESIS, *BIOCHEMICAL genetics, *AMINO acids, *FRUIT flies

Abstract

As the fruit fly, Drosophila melanogaster, progresses from one life stage to the next, many of the enzymes that compose intermediary metabolism undergo substantial changes in both expression and activity. These predictable shifts in metabolic flux allow the fly meet stagespecific requirements for energy production and biosynthesis. In this regard, the enzyme glycerol-3-phosphate dehydrogenase 1 (GPDH1) has been the focus of biochemical genetics studies for several decades and, as a result, is one of the most well-characterized Drosophila enzymes. Among the findings of these earlier studies is that GPDH1 acts throughout the fly lifecycle to promote mitochondrial energy production and triglyceride accumulation while also serving a key role in maintaining redox balance. Here, we expand upon the known roles of GPDH1 during fly development by examining how depletion of both the maternal and zygotic pools of this enzyme influences development, metabolism, and viability. Our findings not only confirm previous observations that Gpdh1 mutants exhibit defects in larval development, lifespan, and fat storage but also reveal that GPDH1 serves essential roles in oogenesis and embryogenesis. Moreover, metabolomics analysis reveals that a Gpdh1 mutant stock maintained in a homozygous state exhibits larval metabolic defects that significantly differ from those observed in the F1 mutant generation. Overall, our findings highlight unappreciated roles for GPDH1 in early development and uncover previously undescribed metabolic adaptations that could allow flies to survive the loss of this key enzyme. [ABSTRACT FROM AUTHOR]

Published

2022

19. miR-125-chinmo pathway regulates dietary restriction-dependent enhancement of lifespan in Drosophila.

Author

Pandey, Manish, Bansal, Sakshi, Bar, Sudipta, Yadav, Amit Kumar, Sokol, Nicholas S., Tennessen, Jason M., Kapahi, Pankaj, and Chawla, Geetanjali

Subjects

*NON-coding RNA, *DROSOPHILA, *SMALL molecules, *DROSOPHILA melanogaster, *FAT, *LONGEVITY

Abstract

Dietary restriction (DR) extends healthy lifespan in diverse species. Age and nutrient- related changes in the abundance of microRNAs (miRNAs) and their processing factors have been linked to organismal longevity. However, the mechanisms by which they modulate lifespan and the tissue-specific role of miRNA-mediated networks in DR-dependent enhancement of lifespan remains largely unexplored. We show that two neuronally enriched and highly conserved microRNAs, miR-125 and let-7 mediate the DR response in Drosophila melanogaster. Functional characterization of miR-125 demonstrates its role in neurons while its target chinmo acts both in neurons and the fat body to modulate fat metabolism and longevity. Proteomic analysis revealed that Chinmo exerts its DR effects by regulating the expression of FATP, CG2017, CG9577, CG17554, CG5009, CG8778, CG9527, and FASN1. Our findings identify miR-125 as a conserved effector of the DR pathway and open the avenue for this small RNA molecule and its downstream effectors to be considered as potential drug candidates for the treatment of late-onset diseases and biomarkers for healthy aging in humans. [ABSTRACT FROM AUTHOR]

Published

2021

20. Adapting Drosophila melanogaster Cell Lines to Serum-Free Culture Conditions.

Author

Luhur, Arthur, Mariyappa, Daniel, Klueg, Kristin M., Buddika, Kasun, Tennessen, Jason M., and Zelhof, Andrew C.

Subjects

*DROSOPHILA melanogaster, *CELL lines, *SERUM-free culture media, *CELL communication, *CELL culture, *SOMATIC embryogenesis

Abstract

Successful Drosophila cell culture relies on media containing xenogenic components such as fetal bovine serum to support continuous cell proliferation. Here, we report a serum-free culture condition that supports the growth and proliferation of Drosophila S2R+ and Kc167 cell lines. Importantly, the gradual adaptation of S2R+ and Kc167 cells to a media lacking serum was supported by supplementing the media with adult Drosophila soluble extract, commonly known as fly extract. The utility of these adapted cells lines is largely unchanged. The adapted cells exhibited robust proliferative capacity and a transfection efficiency that was comparable to control cells cultured in serum-containing media. Transcriptomic data indicated that the S2R+ cells cultured with fly extract retain their hemocyte-specific transcriptome profile, and there were no global changes in the transcriptional output of cell signaling pathways. Our metabolome studies indicate that there were very limited metabolic changes. In fact, the cells were likely experiencing less oxidative stress when cultured in the serum-free media supplemented with fly extract. Overall, the Drosophila cell culture conditions reported here consequently provide researchers with an alternative and physiologically relevant resource to address cell biological research questions. [ABSTRACT FROM AUTHOR]

Published

2020

21. A Genetic Screen Using the Drosophila melanogaster TRiP RNAi Collection To Identify Metabolic Enzymes Required for Eye Development.

Author

Pletcher, Rose C., Hardman, Sara L., Intagliata, Sydney F., Lawson, Rachael L., Page, Aumunique, and Tennessen, Jason M.

Subjects

*DROSOPHILA melanogaster, *GENETIC testing, *KREBS cycle, *CARBON metabolism, *AMINO acid metabolism, *IMAGINAL disks, *GLYCOLYSIS

Abstract

The metabolic enzymes that compose glycolysis, the citric acid cycle, and other pathways within central carbon metabolism have emerged as key regulators of animal development. These enzymes not only generate the energy and biosynthetic precursors required to support cell proliferation and differentiation, but also moonlight as regulators of transcription, translation, and signal transduction. Many of the genes associated with animal metabolism, however, have never been analyzed in a developmental context, thus highlighting how little is known about the intersection of metabolism and development. Here we address this deficiency by using the Drosophila TRiP RNAi collection to disrupt the expression of over 1,100 metabolism-associated genes within cells of the eye imaginal disc. Our screen not only confirmed previous observations that oxidative phosphorylation serves a critical role in the developing eye, but also implicated a host of other metabolic enzymes in the growth and differentiation of this organ. Notably, our analysis revealed a requirement for glutamine and glutamate metabolic processes in eye development, thereby revealing a role of these amino acids in promoting Drosophila tissue growth. Overall, our analysis highlights how the Drosophila eye can serve as a powerful tool for dissecting the relationship between development and metabolism. [ABSTRACT FROM AUTHOR]

Published

2019

22. Metabolomic Analysis Reveals That the Drosophila melanogaster Gene lysine Influences Diverse Aspects of Metabolism.

Author

St. Clair, Samantha L., Hongde Li, Ashraf, Usman, Karty, Jonathan A., and Tennessen, Jason M.

Subjects

*LYSINE, *DROSOPHILA melanogaster genetics, *METABOLOMICS, *GAS chromatography/Mass spectrometry (GC-MS), *METABOLISM

Abstract

The fruit fly Drosophila melanogaster has emerged as a powerful model for investigating the molecular mechanisms that regulate animal metabolism. However, a major limitation of these studies is that many metabolic assays are tedious, dedicated to analyzing a single molecule, and rely on indirect measurements. As a result, Drosophila geneticists commonly use candidate gene approaches, which, while important, bias studies toward known metabolic regulators. In an effort to expand the scope of Drosophila metabolic studies, we used the classic mutant lysine (lys) to demonstrate how a modern metabolomics approach can be used to conduct forward genetic studies. Using an inexpensive and well-established gas chromatography-mass spectrometry-based method, we genetically mapped and molecularly characterized lys by using free lysine levels as a phenotypic readout. Our efforts revealed that lys encodes the Drosophila homolog of Lysine Ketoglutarate Reductase/Saccharopine Dehydrogenase, which is required for the enzymatic degradation of lysine. Furthermore, this approach also allowed us to simultaneously survey a large swathe of intermediate metabolism, thus demonstrating that Drosophila lysine catabolism is complex and capable of influencing seemingly unrelated metabolic pathways. Overall, our study highlights how a combination of Drosophila forward genetics and metabolomics can be used for unbiased studies of animal metabolism, and demonstrates that a single enzymatic step is intricately connected to diverse aspects of metabolism. [ABSTRACT FROM AUTHOR]

Published

2017