Project description:We sequenced the genomes of 32 isofemale fly lines from two divergent microclimates at 'Evolution Canyon' in Israel (16 fly lines from each microclimate).

Project description:Expression data in wt or mutant Drosophila melanogaster embryos

Project description:Genome wide binding of trr (ChIP-seq) and expression analysis (RNA-seq) of trr- and G9a mutant fly heads

Project description:Transcriptional profiling of WT and XBP1 Mutant Larvae

Project description:Drosophila melanogaster is a well-studied genetic model organism with several large-scale transcriptome resources. Here we investigate 7,952 proteins during the fly life cycle from embryo to adult and also provide a high-resolution temporal time course proteome of 5,458 proteins during embryogenesis. We use our large scale data set to compare transcript/protein expression, uncovering examples of extreme differences between mRNA and protein abundance. In the embryogenesis proteome, the time delay in protein synthesis after transcript expression was determined. For some proteins, including the transcription factor lola, we monitor isoform specific expression levels during early fly development. Furthermore, we obtained firm evidence of 268 small proteins, which are hard to predict by bioinformatics. We observe peptides originating from non-coding regions of the genome and identified Cyp9f3psi as a protein-coding gene. As a powerful resource to the community, we additionally created an interactive web interface (http://www.butterlab.org) advancing the access to our data.

Project description:RNA-seq analyses of kdm5 mutant flies and wt flies under normal condition and oxidative stress

Project description:micro RNA (miR) expression profile of developing fly eye in different Ago-1 expressing condition

Project description:RNA sequencing in fly heads to examine the effect of spermidine feeding on transcription in the ageing fly brain.

Project description:In animals studied to date, the crucial process of egg activation, by which an arrested mature oocyte transits into an actively developing embryo, initiates with an increase of Ca2+ in the oocyte’s cytoplasm. This Ca2+ rise sets off a series of downstream events, including the completion of meiosis and the dynamic remodeling of the oocyte transcriptome and proteome, which prepare the oocyte to undertake embryogenesis. Calcineurin is a highly conserved phosphatase that is activated directly by Ca2+ upon egg activation and that is required for the resumption of meiosis in Xenopus, ascidians and Drosophila. The molecular mechanisms by which calcineurin transduces the calcium signal to regulate meiosis and other downstream events are still unclear. In this study, we investigate the regulatory role of calcineurin during egg activation in Drosophila melanogaster. Using mass spectrometry, we quantify the phosphoproteomic and proteomic changes that occur during egg activation, and we examine how these events are affected when calcineurin function is perturbed in female germ cells. Our results show that calcineurin regulates hundreds of phosphosites and also influences the abundance of numerous proteins during egg activation. We find calcineurin-dependent changes in cell cycle regulators including Fzy, Greatwall (Gwl) and Endosulfine (Endos), protein translation modulators including PNG, NAT, eIF4G and eIF4B, and important components of signaling pathways including GSK3β and Akt1. Our results help elucidate the events that occur during the transition from oocyte to embryo.

Project description:In animals studied to date, the crucial process of egg activation, by which an arrested mature oocyte transits into an actively developing embryo, initiates with an increase of Ca2+ in the oocyte’s cytoplasm. This Ca2+ rise sets off a series of downstream events, including the completion of meiosis and the dynamic remodeling of the oocyte transcriptome and proteome, which prepare the oocyte to undertake embryogenesis. Calcineurin is a highly conserved phosphatase that is activated directly by Ca2+ upon egg activation and that is required for the resumption of meiosis in Xenopus, ascidians and Drosophila. The molecular mechanisms by which calcineurin transduces the calcium signal to regulate meiosis and other downstream events are still unclear. In this study, we investigate the regulatory role of calcineurin during egg activation in Drosophila melanogaster. Using mass spectrometry, we quantify the phosphoproteomic and proteomic changes that occur during egg activation, and we examine how these events are affected when calcineurin function is perturbed in female germ cells. Our results show that calcineurin regulates hundreds of phosphosites and also influences the abundance of numerous proteins during egg activation. We find calcineurin-dependent changes in cell cycle regulators including Fzy, Greatwall (Gwl) and Endosulfine (Endos), protein translation modulators including PNG, NAT, eIF4G and eIF4B, and important components of signaling pathways including GSK3β and Akt1. Our results help elucidate the events that occur during the transition from oocyte to embryo