Project description:Steroid hormones act as important developmental switches and their nuclear receptors regulate many genes. However, few hormone-dependent enhancers have been characterized and important aspects of their sequence architecture, cell type-specific activating and repressing functions, or the regulatory roles of their chromatin structure have remained unclear. We used STARR-seq, a recently developed enhancer-screening assay, and ecdysone signaling in two different Drosophila cell types to derive the first genome-wide hormone-dependent enhancer activity maps. We demonstrate that enhancer activation depends on cis-regulatory motif combinations that differ between cell types and can predict cell type-specific ecdysone targeting. Activated enhancers are often not accessible prior to induction. Enhancer repression following hormone treatment is independent of receptor motifs and receptor binding to the enhancer as we show using ChIP-seq, but appears to rely on motifs for other factors, including Eip74. Our strategy is applicable to study signal-dependent enhancers for different pathways and across organisms. STARR-seq was performed in S2 and OSC cells treated with ecdysone in two replicates. DHS-seq before and after treatment was done with single-end sequencing in two replicates. RNA-seq (with and without ecdysone) was performed with a strand-specific protocol using single-end sequencing in two replicates in S2. ChIP-seq (with and without ecdysone) was performed single-end sequencing in two replicates in S2 cells.

Project description:Phenotypic differences between closely related species are thought to arise primarily from changes in gene expression due to mutations in cis-regulatory sequences (enhancers). However, it has remained unclear, how frequently mutations alter enhancer activity or create functional enhancers de novo. Here, we use STARR-seq, a recently developed quantitative enhancer assay, to determine genome-wide enhancer activity profiles for five Drosophila species in the constant trans-regulatory environment of D. melanogaster S2 cells. We find that the function of a large fraction of D. melanogaster enhancers is conserved in their orthologous sequences due to selection and stabilizing turnover of transcription factor motifs. Moreover, hundreds of enhancers have been gained since the D. melanogaster M-bM-^@M-^S D. yakuba split about 11 million years ago without apparent adaptive selection and can contribute to gene expression changes in vivo. Our finding that enhancer activity is often deeply conserved and frequently gained provides important functional insights into regulatory evolution. STARR-seq was performed in S2 cells with paired-end sequencing in two replicates and respective inputs using genomic DNA from different Drosophila species. RNA-seq was performed in a non-stranded manner without replicates for two Drosophila species.

Project description:Hox homeodomain transcription factors are key regulators of animal development. They specify the identity of segments along the anterior-posterior body axis in metazoans by controlling the expression of diverse downstream targets, including transcription factors and signaling pathway components. The Drosophila melanogaster Hox factor Ultrabithorax (Ubx) directs the development of thoracic and abdominal segments and appendages, and loss of Ubx function can lead for example to the transformation of third thoracic segment appendages (e.g. halters) into second thoracic segment appendages (e.g. wings), resulting in a characteristic four-wing phenotype. Here we present a Drosophila melanogaster strain with a V5-epitope tagged Ubx allele, which we employed to obtain a high quality genome-wide map of Ubx binding sites using ChIP-seq. We confirm the sensitivity of the V5 ChIP-seq by recovering 7/8 of well-studied Ubx-dependent cis-regulatory regions. Moreover, we show that Ubx binding is predictive of enhancer activity as suggested by comparison with a genome-scale resource of in vivo tested enhancer candidates. We observed densely clustered Ubx binding sites at 12 extended genomic loci that included ANTP-C, BX-C, Polycomb complex genes, and other regulators and the clustered binding sites were frequently active enhancers. Furthermore, Ubx binding was detected at known Polycomb response elements (PREs) and was associated with significant enrichments of Pc and Pho ChIP signals in contrast to binding sites of other developmental TFs. Together, our results show that Ubx targets developmental regulators via strongly clustered binding sites and allow us to hypothesize that regulation by Ubx might involve Polycomb group proteins to maintain specific regulatory states in cooperative or mutually exclusive fashion, an attractive model that combines two groups of proteins with prominent gene regulatory roles during animal development. Ubx was endogenously tagged with V5 epitope in Drosophila melanogaster (Ubx-V5). ChIP-seq was performed with chromatin from 0-16 hrs wild type and Ubx-V5 embryos. The samples were subjected to single-end sequencing in two replicates.

Project description:Gene expression is determined by genomic elements called enhancers, which contain short motifs bound by different transcription factors (TFs). However, how enhancer sequences and TF motifs relate to enhancer activity is unknown and general sequence requirements for enhancers or comprehensive sets of important enhancer sequence elements have remained elusive. Here, we computationally dissect thousands of functional enhancer sequences from three different Drosophila cell lines. We find that the enhancers display distinct cis-regulatory sequence signatures, which are predictive of the enhancersM-bM-^@M-^Y cell type-specific or broad activities. These signatures contain transcription factor motifs and a novel class of enhancer sequence elements, dinucleotide repeat motifs (DRMs). DRMs are highly enriched in enhancers, particularly in enhancers that are broadly active across different cell types. We experimentally validate the importance of the identified TF motifs and DRMs for enhancer function and show that they can be sufficient to create an active enhancer de novo from non-functional sequence. The function of DRMs as a novel class of general enhancer features that are also enriched in human regulatory regions might explain their implication in several diseases and provides important insights into gene regulation. STARR-seq was performed in BG3 cells with paired-end sequencing in two replicates and respective inputs.

Project description:Collier, the single Drosophila COE (Collier/EBF/Olf-1) transcription factor, is required in several developmental processes, including head patterning and specification of muscle and neuron identity during embryogenesis. To identify direct Collier (Col) targets in different cell types, we used ChIP-seq to map Col binding sites throughout the genome, at mid-embryogenesis. In vivo Col binding peaks were associated to 415 potential direct target genes. Gene Ontology analysis revealed a strong enrichment in proteins with DNA binding and/or transcription-regulatory properties. Characterization of a selection of candidates, using transgenic CRM-reporter assays, identified direct Col targets in dorso-lateral somatic muscles and specific neuron types in the central nervous system. These data brought new evidence that Col direct control of the expression of the transcription regulators apterous and eyes-absent (eya) is critical to specifying neuronal identities. They also showed that cross-regulation between col and eya in muscle progenitor cells is required for specification of muscle identity, revealing a new parallel between the myogenic regulatory networks operating in Drosophila and vertebrates. Col regulation of eya, both in specific muscle and neuronal lineages, may illustrate one mechanism behind the evolutionary diversification of Col biological roles. Fixed nuclear extract of stage 13-14 whole drosophila embryo were submit to Chromatine Immunoprecipitation with a mix of three COL monoclonal antibodies. As control a non relevent antibody (anti-HA) was used. Precipitated DNA was submit to Illumina high-throughput sequencing.

Project description:DNA methylation mediated by the combined action of three DNA methyltransferases, DNMT1, DNMT3A, and DNMT3B, is essential for mammalian development and is also a major contributor to transformation. To elucidate how DNA methylation is targeted, we map the genome-wide localization of all DNMTs and methylation, and examine relationships between these markers and histone modifications and nucleosome structure. Our findings reveal a strong link between DNA methylation/DNMTs and transcribed loci and that these marks exhibit both overlapping and unique localization patterns. Comparisons with the epigenome of embryonic stem cells demonstrate that DNMT binding is associated with transformation-associated changes in methylation. Taken together, this study sheds important new light on determinants of DNA methylation and how it may become disrupted in cancer cells. Examination of different marks in undifferentiated and differentiatial NCCIT cells

Project description:GAGA associated transcription factor (GAF) is a highly abundant and essential protein in Drosophila. GAF recognizes and binds arrays of GA dinucleotides via a zinc finger DNA binding domain to regulate transcription by binding to general TF machinery or recruit nucleosome remodeling factors. We performed GAF ChIP-seq to quantify the intensity of GAF binding at high resolution in S2 cells. In addition, we performed GAF ChIP-seq in S2 cells that were depleted of GAF by RNAi. By quantifying the degree to which all GAF binding sites are susceptible to GAF depletion, we found the cellular degree of depletion does not translate equally to the depletion of GAF at individual chromatin bound sites. For example, some high intensity GAF binding sites were completely unaffected by GAF depletion, while lower affinity binding sites were often ablated upon GAF depletion. These data sets will serve as a valuable resource to others who study the dynamic interplay between GAF and chromatin. We also compared the GAF binding sites to the full set of genomic ChIP data that is available for S2 cells and compared the intensity for each factor and histone modification/variant. Lastly, we investigated the influence that GAF had upon inducible transcription factor binding using the heat shock system. A single mock immunoprecipitation (IP) using non-specific IgG was used as a background dataset for this study (see PMID: 20844575; GSM470838). We performed two independent GAF-ChIP-seq experiments in untreated S2 cells and two replicates in S2 cells that were depleted of GAF by RNAi.

Project description:We mapped the localization of insulator proteins in Drosophila S2 cells in the presence or absence of 12mM of 3AB. We found that inhibition of PARylation affects DNA binding of insulator proteins only at a small subsets of genomic sites. Examination of genomic occupancy for insulator proteins in S2 cells with or without 3AB inhibition.

Project description:The animal piRNA pathway is a small RNA silencing system that acts in gonads and protects the genome against the deleterious influence of transposons. A major bottleneck in the field is the lack of comprehensive knowledge of the factors and molecular processes that constitute this pathway. We conducted an RNAi screen in Drosophila and identified ~50 genes that strongly impact the ovarian somatic piRNA pathway. Many identified genes fall into functional categories that indicate essential roles for mitochondrial metabolism, RNA export, the nuclear pore, transcription elongation and chromatin regulation in the pathway. Follow-up studies on two factors demonstrate the identification of components acting at distinct hierarchical levels of the pathway. Finally, we define CG2183/Gasz as a novel primary piRNA biogenesis factor in somatic and germline cells. Based on the similarities between insect and vertebrate piRNA pathways our results have far-reaching implications for the understanding of this conserved genome defense system. Steady-state RNA levels in wild-type ovarian somatic cells (OSC) and RNAi knock-downs of the piRNA pathway components.

Project description:Broadly expressed transcriptions factors (TFs) control tissue-specific programs of gene expression through interactions with local TF networks. Prime examples are the circadian clock TFs CLOCK (CLK) and CYCLE (CYC or BMAL1): while they control a core transcriptional circuit throughout animal bodies, downstream clock target genes and circadian physiology are tissue-specific. Here, we use ChIP-seq to determine the regulatory targets of Drosophila CLK and CYC, which we epitope-tagged by homologous recombination. Both TFs have distinct binding sites in heads versus bodies, suggesting that they directly control tissue-specific downstream target genes. Analysis of these context-specific binding sites revealed distinct sequence motifs for putative clock partner factors, including a motif for the GATA factor SERPENT (SRP). SRP indeed synergistically enhances CLK/CYC-mediated activity of a cis-regulatory region bound by CLK/CYC specifically in bodies. These results reveal how universal clock circuits can generate tissue-specific outputs and demonstrate an approach to dissect regulatory interactions more generally. We sequenced ChIP and input samples, as well as M-bM-^@M-^\mockM-bM-^@M-^] samples for which we performed ChIP with the V5 antibody from wildtype w- flies (not carrying the V5 tag) for two independent biological replicates each, summing to 24 libraries in total.