Project description:We have found that oncogenic Ras combined with loss of the Hippo tumour-suppressor pathway reactivates a primary piRNA pathway in Drosophila somatic cells, coincident with oncogenic transformation. In these cells, Piwi becomes loaded with piRNAs derived from generative loci, which are normally restricted to either the germline or the somatic follicle cells. Negating the pathway leads to increases in the expression of a wide variety of transposons and also to altered expression of some protein coding genes. This correlates with a reduction in the proliferation of the transformed cells in culture, suggesting that at least in this context, the piRNA pathway may play a functional role in cancer. Small RNAs cloned from whole cells, Piwi-bound small RNAs and long RNA-Seq were performed in wts-RNAi;RasV12 cells to identify piRNAs and gene expression changes compared to RasV12 cells, somatic OSS cells, and germline UAS-wts-RNAi;UAS-RasV12 control ovaries. After knock-down of components of the piRNA machinery in WRR-1 cells ([piwi, zuchini, armitage, aubergine, argonaute3) and GFP and/or dsRED control knock-downs, small RNAs were cloned and gene expression (RNA-Seq) profiles were established.

Project description:This SuperSeries is composed of the SubSeries listed below. Refer to individual Series

Project description:The timing of behavior under natural light-dark conditions is a function of circadian clocks and photic input pathways. Yet a mechanistic understanding of how these pathways collaborate in animals is lacking. Here we demonstrate in Drosophila that the Phosphatase of Regenerating Liver-1 (PRL-1) sets period length and behavioral phase gated by photic signals. PRL-1 knockdown in PDF clock neurons dramatically lengthens circadian period. PRL-1 mutants exhibit allele-specific interactions with the light- and clock-regulated gene timeless (tim). Moreover, we show that PRL-1 promotes TIM accumulation and dephosphorylation. Interestingly, the PRL-1 mutant period lengthening is suppressed in constant light and PRL-1 mutants display a delayed phase under short, but not long, photoperiod conditions. Thus, our studies reveal that PRL-1 dependent dephosphorylation of TIM is a core mechanism of the clock that sets period length and phase in darkness, enabling the behavioral adjustment to changing day-night cycles.

Project description:Aedes aegypti mosquitoes vector several arboviruses of global health significance, including dengue viruses and chikungunya virus. RNA interference (RNAi) plays an important role in antiviral immunity, gene regulation and protection from transposable elements. Double-stranded RNA binding proteins (dsRBPs) are important for efficient RNAi; in Drosophila functional specialization of the miRNA, endo-siRNA and exo-siRNA pathway is aided by the dsRBPs Loqs-PB, Loqs-PD and R2D2, respectively. However, this functional specialization has not been investigated in other dipterans. Characterization of the gene structure, expression pattern and interactions with other RNAi/miRNA components revealed that mosquito Loqs/R3D1 isoform -PA, but not -PB interacted readily with both AeAGO1 and AeAGO2. This interaction was mapped to a 32 a.a. region predicted to be structurally similar to the unique 22 a.a. tail of Drosophila Loqs-PD. No -PD isoforms could be detected in Ae. aegypti; analysis of other dipteran genomes demonstrated that this isoform is not conserved outside of Drosophila. Overexpression experiments indicated that Loqs/R3D1-PA participates in endo-siRNA, but not exo-siRNA based silencing. We conclude that the functional specialization of Loqs-PD in Drosophila is a recently derived trait, and that in other dipterans, including the medically important mosquitoes, Loqs/R3D1-A participates in both the miRNA and endo-siRNA based pathways. 12 samples, 3 replicates of each type of sample. The GFP sample is the reference sample

Project description:RNA silencing pathways are conserved gene regulation mechanisms that lead to degradation, translational repression or transcriptional silencing of target-transcripts selected based on complementarity with small RNA molecules. The fraction of the genome regulated by these pathways has not been established. Argonaute proteins play fundamental roles in RNA silencing. To identify their physiological targets at the genomic level, we examined expression profiles in Drosophila cells depleted of 4 Argonaute paralogs (i.e. AGO1, AGO2, PIWI or Aubergine). We also profiled cells depleted of the microRNA (miRNA)-processing enzyme Drosha.

Project description:Transcription profiling by RNA-seq of Drosophila S2 cells after knock down of strongest cell cycle regulators to map their genome-wide transcriptional targets (155 assays). RNA samples used for this experiment are a subset of the 200 samples used in Affymetrix microarray experiment E-MTAB-453. E-MTAB-1648, E-MTAB-1364 and E-MTAB-453 are all data from: Bonke M, et al. (2013) Transcriptional networks controlling the cell cycle. G3 (Bethesda) 3, 75-90, PMID: 23316440.

Project description:In this work, we use RNAi and subsequent RNA isolation and Affymetrix Expression array analysis to map the genome-wide transcriptional targets of 107 of the strongest cell cycle regulators. Drosophila S2 cells were used with RNAi target gene knockdown compared to control (GFP dsRNA). RMA normalized data re-annotated using a custom CDF is available on the FTP site for this experiment. E-MTAB-1648, E-MTAB-1364 and E-MTAB-453 are all data from: Bonke M, et al. (2013) Transcriptional networks controlling the cell cycle. G3 (Bethesda) 3, 75-90, PMID: 23316440.

Project description:This study examines the regulatory capacity of the Piwi protein in the Drosophila OSS cell. Piwi CLIP-Seq, mRNA-Seq and nascent RNAseq datasets were integrated to determine how Piwi proteins where using piRNAs and binding interactions to regulate the expression of transcripts. We also sequenced the genomes of various OSS cell lines. We first performed several replicates of a Piw CLIP-Seq experiment to isolate RNA fragments as CLIP-tags to discover which transcripts are preferentially bound by the Piwi protein. Then we performed several types of mRNA expression profiling experiments using several forms of mRNA-Seq library construction formats. Finally, we sequenced the genomes from various OSS cell lines. The genomic sequencing component of the study is represented by BioProject PRJNA240323. The genomic sequencing raw data have been deposited at SRA (SRP039565).

Project description:In Drosophila, PIWI proteins and bound PIWI interacting RNAs (piRNAs) form the core of a small RNA mediated defense system against selfish genetic elements. Within germline cells piRNAs are processed from piRNA clusters and transposons to be loaded into Piwi/Aubergine/AGO3 and a subset of piRNAs undergoes target dependent amplification. In contrast, gonadal somatic support cells express only Piwi, lack signs of piRNA amplification and exhibit primary piRNA biogenesis from piRNA clusters. Neither piRNA processing/loading nor Piwi mediated target silencing is understood at the genetic, cellular or molecular level. We developed an in vivo RNAi assay for the somatic piRNA pathway and identified the RNA helicase Armitage, the Tudor domain containing RNA helicase Yb and the putative nuclease Zucchini as essential factors for primary piRNA biogenesis. Lack of any of these proteins leads to transposon de-silencing, to a collapse in piRNA levels and to a failure in Piwi nuclear accumulation. We show that Armitage and Yb interact physically and co-localize in cytoplasmic Yb-bodies, which flank P-bodies. Loss of Zucchini leads to an accumulation of Piwi and Armitage in Yb-bodies indicating that Yb-bodies are sites of primary piRNA biogenesis. small RNA libraries were prepared from Piwi immuno-precipitates of five different genotypes

Project description:In this study we have used ChIP followed by high throughput sequencing to profile the genome-wide recruitment of wildtype and non-oligomerizing Groucho (Gro) at high resolution in single cell types (Kc167 and S2R+) using Drosophila cell culture. Our results reveal that Gro is typically recruited to discrete peaks in active chromatin and that blocking Gro oligomerization does not change the width of the peaks to which it is recruited. We have also investigated acetylated histone H3 and H4 and RNA polymerase II profiles around Gro binding sites, along with gene expression, in wildtype, Gro knockdown, Gro-GFP transfected, and non-oligomerizing Gro-GFP transfected Kc167 cells and found that Gro associates with chromatin containing hypoacetylated histones and frequently overlaps the transcription start sites of expressed genes that exhibit strong RNA polymerase pausing.