Project description:The Notch pathway is a well conserved cell to cell communication mechanism that is normally involved in many developmental processes and when aberrantly activated it leads to diseases such as cancer. One such example is the neural stem cell tumours that arise from constitutive Notch activity in Drosophila neuroblasts from the larval Central Nervous System (CNS). To investigate how hyper-activation of Notch in larval neuroblasts leads to tumours, we mapped genome-widely the regions that are bound by Su(H) (the core Notch pathway transcription factor, known as CSL in mammals). We combined these results with the profiling of upregulated mRNAs in CNSs where Notch is hyper-activated for 24h vs control CNSs and identified 127 putative direct Notch targets in the hyperplastic CNSs. Included were genes associated with the neuroblast maintenance and self-renewal programme and genes coding for temporal transcription factors, which are involved in neuroblast progression and generation of progeny with specific identity over time. Thus, Notch induces neural stem cell tumors by promoting the expression of genes that contribute to stem cell identity and by reprogramming expression of temporal factors that regulate maturity. Su(H) binding profile in Drosophila larval CNSs where Notch is constitutively active for 24 hours. In total there are 3 samples of Su(H) ChIP in Notch hyper-activated larval CNSs.

Project description:The Notch pathway is a well conserved cell to cell communication mechanism that is normally involved in many developmental processes and when aberrantly activated it leads to diseases such as cancer. One such example is the neural stem cell tumours that arise from constitutive Notch activity in Drosophila neuroblasts from the larval Central Nervous System (CNS). To investigate how hyper-activation of Notch in larval neuroblasts leads to tumours, we mapped genome-widely the regions that are bound by Su(H) (the core Notch pathway transcription factor, known as CSL in mammals). We combined these results with the profiling of upregulated mRNAs in CNSs where Notch is hyper-activated for 24h vs control CNSs and identified 127 putative direct Notch targets in the hyperplastic CNSs. Included were genes associated with the neuroblast maintenance and self-renewal programme and genes coding for temporal transcription factors, which are involved in neuroblast progression and generation of progeny with specific identity over time. Thus, Notch induces neural stem cell tumors by promoting the expression of genes that contribute to stem cell identity and by reprogramming expression of temporal factors that regulate maturity.

Project description:CCCTC-binding factor (CTCF) is a conserved protein able to block communication between regulatory elements and gene promoters in flies and mammals. Here, we studied CTCF function in the Drosophila central nervous system (CNS) in which we find CTCF plays a vital role. RNA-sequencing of CNSs of CTCF[0] mutants that completely lack CTCF identified putative targets that are expressed in altered patterns. We find that CTCF recruits Centrosomal protein 190 kDa (Cp190) to CTCF's binding sites to co-regulate a substantial fraction of common genes that we find are also altered in CNSs of Cp190[KO] mutants carrying a CRISPR/Cas9-mediated deletion of the Cp190 open reading frame.

Project description:Gene order, or microsynteny, is generally thought not to be conserved across metazoan phyla. Only a handful of exceptions, typically of tandemly duplicated genes such as Hox genes, have been discovered. Here, we performed a systematic survey for microsynteny conservation in 17 genomes and identified nearly 600 pairs of unrelated genes that have remained together across over 600 million years of evolution. Using multiple genome-wide resources, including several genomic features, epigenetic marks, sequence conservation and microarray expression data, we provide extensive evidence that many of these ancient microsyntenic arrangements have been conserved in order to preserve either (i) the coordinated transcription of neighboring genes, or (ii) Genomic Regulatory Blocks (GRBs), in which transcriptional enhancers controlling key developmental genes are contained within nearby “bystander” genes. In addition, we generated ChIP-seq data for key histone modifications in zebrafish embryos to further investigate putative GRBs in embryonic development. Finally, using chromosome conformation capture (3C) assays and stable transgenic experiments, we demonstrate that enhancers within bystander genes drive the expression of genes such as Otx and Islet, critical regulators of central nervous system development across bilaterians. These results show that ancient genomic associations are far more common in modern metazoans than previously thought – likely involving over 12% of the ancestral bilaterian genome – and that cis-regulatory constraints have played a major role in conserving the architecture of metazoan genomes. ChIP-seq H3K27me3 of 24hpf zebrafish embryos

Project description:CCCTC-binding factor (CTCF) is a conserved protein able to block communication between regulatory elements and gene promoters in flies and mammals. Here, we studied CTCF function in the Drosophila central nervous system (CNS) in which we find CTCF plays a vital role. Hi-C experiments on dissected larval CNSs of wildtype controls and CTCF[0] mutants that completely lack CTCF revealed that CTCF forms hundreds of physical boundaries in fly chromosomes.

Project description:Gene order, or microsynteny, is generally thought not to be conserved across metazoan phyla. Only a handful of exceptions, typically of tandemly duplicated genes such as Hox genes, have been discovered. Here, we performed a systematic survey for microsynteny conservation in 17 genomes and identified nearly 600 pairs of unrelated genes that have remained together across over 600 million years of evolution. Using multiple genome-wide resources, including several genomic features, epigenetic marks, sequence conservation and microarray expression data, we provide extensive evidence that many of these ancient microsyntenic arrangements have been conserved in order to preserve either (i) the coordinated transcription of neighboring genes, or (ii) Genomic Regulatory Blocks (GRBs), in which transcriptional enhancers controlling key developmental genes are contained within nearby “bystander” genes. In addition, we generated ChIP-seq data for key histone modifications in zebrafish embryos to further investigate putative GRBs in embryonic development. Finally, using chromosome conformation capture (3C) assays and stable transgenic experiments, we demonstrate that enhancers within bystander genes drive the expression of genes such as Otx and Islet, critical regulators of central nervous system development across bilaterians. These results show that ancient genomic associations are far more common in modern metazoans than previously thought – likely involving over 12% of the ancestral bilaterian genome – and that cis-regulatory constraints have played a major role in conserving the architecture of metazoan genomes.

Project description:Conserved pleiotropy of an ancient plant homeobox gene uncovered by cis-regulatory dissection

Project description:CCCTC-binding factor (CTCF) is a conserved protein able to block communication between regulatory elements and gene promoters in flies and mammals. Here, we studied CTCF function in the Drosophila central nervous system (CNS) in which we find CTCF plays a vital role. Chromatin immunoprecipitation (ChIP)-sequencing of CTCF and its partner protein Centrosomal protein 190 kDa (Cp190) in CNSs of wildtype (WT), CTCF[0] mutants completely lacking CTCF and Cp190[KO] mutants with a CRISPR/Cas9-mediated deletion of the Cp190 open reading frame identified CTCF and Cp190 peaks defined as enriched in WT relative to each respective mutant control. These experiments also revealed that CTCF recruits Cp190 to CTCF's binding sites, but Cp190 is dispensable for CTCF binding to most of CTCF's sites.

Project description:Arabidopsis gene expression is regulated by more than 1,900 transcription factors (TFs), which have been identified genome-wide by the presence of well-conserved DNA binding domains. Activator TFs contain activation domains (ADs) that recruit coactivator complexes; however, for most Arabidopsis TFs, we lack knowledge about the presence, location, and transcriptional strength of their ADs. To address this gap, we experimentally identified Arabidopsis ADs on a proteome-wide scale, finding that over half of Arabidopsis TFs carry an AD. We annotated 1,553 ADs, the vast majority of which were previously unknown. We used the dataset generated to develop a neural network to accurately predict ADs and to identify sequence features necessary to recruit coactivator complexes. We uncovered six distinct sequence feature combinations that resulted in activation activity, providing a framework to interrogate activation domain sub-functionalization. Furthermore, we identified activation domains within the ancient AUXIN RESPONSE FACTOR (ARF) family of transcription factors, finding conservation of AD positioning in distinct clades. Our findings provide a deep resource for understanding transcriptional activation, a framework for examination of function within intrinsically disordered regions, and a predictive model of activation domains.

Project description:The binding patterns of some transcription factors have been shown to diverge substantially between closely related species. Here, we show that the binding pattern of the developmental transcription factor Twist is highly conserved across six Drosophila species, revealing strong functional constraints at developmental enhancers. Conserved binding correlates with sequence motifs for Twist and its partners, permitting the de novo discovery of their cooperative binding. It also includes over 10,000 low-occupancy sites near the detection limit, which tend to mark enhancers of later developmental stages. We predict that conservation, dynamic occupancy, and combinatorial regulation will be generally true for developmental enhancers.