Project description:Intracellular Ca2+ release through the Inositol 1,4,5-Triphosphate Receptor (InsP3R) is a feature of all multicellular organisms in which it shapes the temporal and spatial aspects of calcium signaling in cells, affecting several developmental and physiological processes. Mutants in the InsP3R gene of Drosophila (itpr) exhibit a range of defects which include growth defects and larval lethality.The Drosophila Insulin-like peptides (ILPs) are encoded by multigene families that are expressed in the brain and other tissues. Upon secretion, these peptides likely serve as hormones, neurotransmitters, and growth factors. In Drosophila melanogaster, molecular genetic studies have revealed Drosophila ILPs as elements of a conserved insulin signaling pathway, and as in other animal models, it appears to play a key role in metabolism, growth, reproduction, and aging. Previous work from our group has shown that InsP3R function can be rescued by ectopically expressing InsP3R in dilp cells or can be compensated by altering the activity of Sarco-Endoplasmic Reticulum Calcium-ATPase (SERCA). To understand the molecular basis of larval lethality and growth defect in Drosophila InsP3R mutants and to decipher possible cross talk of itpr gene with other signaling pathways we have carried out genome wide microarray experiments. We have compared the transcript profiles of i) itpr mutant larvae and wild type larvae, ii) dilp rescue larvae with itpr mutant larvae iii) itpr and SERCA double mutant larvae with itpr mutant larvae. By this we have identified genes whose levels are altered in itpr mutants and are restored towards wild type in dilp rescue larvae with itpr mutant larvae and itpr and SERCA double mutants. Our experiments help in identify genes that are regulated by changes in intracellular Ca2+ in the context of larval viability may contribute to the better understanding of the major human pathologies caused by calcium misbalance or by dysregulation of the insulin/IGF pathway. The 8x60k array AMADID: 27326 slide was scanned immediately by PerkinElmer Scan array Gx Microarray scanner. The Scan array software (PerkinElmer) was used for grid wise normalization of array images. Three were used with Mutant, three for Dilp Rescue and two for Kum Rescue experiments . The data was analysed by GeneSpring GX Agilent . The differential expression was considered if the Log 2 mean of at least -1 for the down regulated genes and +1 for the upregulated genes. We considered only the genes that were reproducible from biological triplicates for Mutant, biological treplicates for Dilp Rescue and biological duplicates for Kum Rescue.

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 Poly mutant was identified as a previously uncharacterised, but essential gene in Drosphila. Loss of Poly reults in lethality at the third larval instar stage, but only after a stage of extreme larval longevity. We aimed to assess the consequences of loss of the Poly gene on glocal gene expression by microarray analysis. Metabolism is altered in Poly mutants and here we find altered gene expression in insulin signaling pathways. Four biological replicates each of Poly mutant and wild-type larvae were used to assess gene expression on FL002 microarrays (GPL5135) . These data reveal that Poly is a mediatior of insulin receptor/TOR signaling. Four biological replicates of poly mutant and wild-type Drosophila. Two arrays had wild-type in Cy5 channel and poly in Cy3 channel, the other two were reversed.

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:The Poly mutant was identified as a previously uncharacterised, but essential gene in Drosphila. Loss of Poly reults in lethality at the third larval instar stage, but only after a stage of extreme larval longevity. We aimed to assess the consequences of loss of the Poly gene on glocal gene expression by microarray analysis. Metabolism is altered in Poly mutants and here we find altered gene expression in insulin signaling pathways. Four biological replicates each of Poly mutant and wild-type larvae were used to assess gene expression on FL002 microarrays (GPL5135) . These data reveal that Poly is a mediatior of insulin receptor/TOR signaling.

Project description:Muscle contraction depends on strictly controlled Ca2+ transients within myocytes. A major player maintaining these transients is the sarcoplasmic/endoplasmic reticulum Ca2+ ATPase, SERCA. Activity of SERCA is regulated by binding of micropeptides and impaired expression or function of these peptides results in cardiomyopathy. To date, it is not known how homeostasis or turnover of the micropeptides is regulated. We found that the Drosophila endopeptidase Neprilysin 4 hydrolyzes SERCA-inhibitory Sarcolamban peptides in membranes of the sarcoplasmic reticulum, thereby ensuring proper regulation of SERCA. Cleavage was necessary and sufficient to maintain homeostasis and function of the micropeptides. Analyses on human Neprilysin, sarcolipin, and ventricular cardiomyocytes indicated that the regulatory mechanism is evolutionarily conserved. By identifying a neprilysin as essential regulator of SERCA activity and Ca2+ homeostasis in cardiomyocytes, these data contribute to a more comprehensive understanding of the complex mechanisms that control muscle contraction and heart function in health and disease.

Project description:WT and dDP-/- mutant larvae RNAs were analyzed on Drosophila 12 x 135 Nimbelgen gene expression microarrays. dDP-/- mutants are described in Frolov et al., 2001. Genes Dev. Aug 15;15(16):2146-60. PMID: 11511545 The complete elimination of E2F/DP function in Drosophila results in upregulation of DNA damage responses. The net effect of E2F regulation in larval tissues is that all classes of E2F target genes are reppressed by E2F/DP complexes.

Project description:Quantitative MS analysis was performed on ten 4 day-old Drosophila larval fat bodies homogenized in 50µl D-PBS (Dulbecco’s Phosphate Buffered Saline without Mg2+ and Ca2+) by Lipotype using previously described methods (Grillet et al, 2016).

Project description:Pathways modulating glucose homeostasis independently of insulin would open new avenues to combat insulin resistance and diabetes. Here, we report the establishment, characterization and use of a vertebrate 'insulin-free' model to identify insulin-independent modulators of glucose metabolism. insulin knockout zebrafish recapitulate core characteristics of diabetes and survive only up to larval stages. Utilizing a highly efficient endoderm transplant technique, we generated viable chimeric adults that provide the large numbers of insulin mutant larvae required for our screening platform. Using glucose as a disease-relevant readout, we screened 2233 molecules and identified 3 that consistently reduced glucose levels in insulin mutants. Most significantly, we uncovered an insulin-independent beneficial role for androgen receptor antagonism in hyperglycemia, mostly by reducing fasting glucose levels. Our study proposes therapeutic roles for androgen signaling in diabetes and, more broadly, offers a novel in vivo model for rapid screening and decoupling of insulin-dependent and -independent mechanisms.

Project description:Activation of innate immune responses in the Drosophila larval fat body affects the physiological host responses. In order to characterize the effect of the activated immune responses in the fat body on the Drosophila, we used whole-genome microarray analysis and found that activation of the immune deficieny pathway (Imd) in the fat body alters the transcriptional profiles of Drosophila larvae. As we expected many of genes involved in regulation of antimicrobial peptides were upregulated in the larvae with elevated Imd activity in the fat body. Notably, we found activatioan of Imd in the fat body negatively affects expression of genes involved in glycolysis, energy production and insulin signaling pathway. Overall, our analysis showed that activation of innate immune signaling in the larval fat body significantly affects cellular pathways that regulate metabolism.