Project description:Previous work in the developing Drosophila wing revealed that cell cycle genes are subject to two types of chromatin regulation. The majority of cell cycle genes exhibit a simple regulatory landscape, with promoters that remain accessible even after cell cycle exit. A few critical, rate-limiting cell cycle genes show a more complex and dynamic landscape, and enhancers near these genes show evidence of decomissioning after cell cycle exit has occurred. Here we address whether the findings made in the wing are applicable to other postmitotic tissues that persist for the lifetime of the animal: the eye and the brain. We find that these tissues show similar chromatin accessibility profiles at cell cycle genes, suggesting that these modes of regulation are shared across tissues and that multiple strategies support cell cycle gene repression in the postmitotic state. These include stable repression at the promoters of most cell cycle genes, combined with enhancer decommissioning at a few select, rate-limiting genes.

Project description:Many postmitotic tissues coordinate robust cell cycle exit with the progression of terminal differentiation. While the signals involved in initiating cell cycle exit during terminal differentiation for some tissues have been described, less is known about the mechanisms that maintain a stable, non-cycling state. We previously found that chromatin accessibility changes at a subset of rate-limiting cell cycle genes occurs during maintenance of cell cycle exit, suggesting chromatin remodelers may play a key role in maintaining a robust postmitotic state during terminal differentiation. Here we show that the chromatin remodeler Mi-2 is required to ensure a stable, postmitotic state in Drosophila eyes and wings. Mi-2 alters chromatin accessibility and gene expression during cell cycle exit and terminal differentiation. Mi-2 and a transcription factor involved in tissue maturation, E93, close chromatin accessibility at an overlapping subset of potential enhancers that include the rate-limiting mitotic regulator string (cdc25c) and genes involved in the progression of terminal differentiation. E93 is also required for a stable, postmitotic state and we verified in vivo that Mi-2 and E93 cooperate to decommission an enhancer for the essential mitotic regulator string, to coordinate the transition to a postmitotic state with terminal differentiation. Enhancer decommissioning at the string locus provides a molecular explanation for the long-term, nearly irreversible postmitotic state observed in many tissues as terminal differentiation progresses.

Project description:Many postmitotic tissues coordinate robust cell cycle exit with the progression of terminal differentiation. While the signals involved in initiating cell cycle exit during terminal differentiation for some tissues have been described, less is known about the mechanisms that maintain a stable, non-cycling state. We previously found that chromatin accessibility changes at a subset of rate-limiting cell cycle genes occurs during maintenance of cell cycle exit, suggesting chromatin remodelers may play a key role in maintaining a robust postmitotic state during terminal differentiation. Here we show that the chromatin remodeler Mi-2 is required to ensure a stable, postmitotic state in Drosophila eyes and wings. Mi-2 alters chromatin accessibility and gene expression during cell cycle exit and terminal differentiation. Mi-2 and a transcription factor involved in tissue maturation, E93, close chromatin accessibility at an overlapping subset of potential enhancers that include the rate-limiting mitotic regulator string (cdc25c) and genes involved in the progression of terminal differentiation. E93 is also required for a stable, postmitotic state and we verified in vivo that Mi-2 and E93 cooperate to decommission an enhancer for the essential mitotic regulator string, to coordinate the transition to a postmitotic state with terminal differentiation. Enhancer decommissioning at the string locus provides a molecular explanation for the long-term, nearly irreversible postmitotic state observed in many tissues as terminal differentiation progresses.

Project description:Transcriptional repression and enhancer decommissioning silence cell cycle genes in postmitotic tissues

Project description:Transcriptional repression and enhancer decommissioning silence cell cycle genes in postmitotic tissues: RNA-Seq Timecourse from Developing Drosophila Eye

Project description:Transcriptional repression and enhancer decommissioning silence cell cycle genes in postmitotic tissues: ATAC-Seq Timecourse from Drosophila Eye and Brain

Project description:Cell cycle exit is usually enforced during terminal differentiation in various organisms and tissues. To understand how this is achieved molecularly, we exained the genome-wide profiles of chromatin accessibility and transcriptomes at normal development stages of fly wings as well as situations where we uncoupled cell cylce exit from terminal differentiation with genetic manipulations. We found that developmentally programmed, temporal changes in chromatin accessibility at a small subset of critical cell cycle genes act to enforce cell cycle exit during terminal differentiation.

Project description:Principal neurons in the mammalian brain exit cell cycle and execute a complex and prolonged differentiation program that continues into early adult life. Although high levels of 5-hydroxymethylcytosine (5hmC) accumulate in neurons, it is not known whether 5hmC can serve as an intermediate in DNA demethylation in postmitotic neurons. Here we report high resolution mapping of DNA methylation and hydroxymethylation, chromatin accessibility, and activating and repressive histone marks in developing postmitotic Purkinje cells (PCs). Our data reveal new relationships between PC transcriptional and epigenetic programs, and identify a class of late expressed genes that lose both 5mC and 5hmC during terminal differentiation. Deletion of the 5hmC writers Tet1, Tet2, and Tet3 from postmitotic Purkinje cells prevents loss of 5mC and 5hmC in regulatory domains and gene bodies and hinders transcriptional and epigenetic developmental transitions, resulting in hyper-excitability and increased susceptibility to excitotoxic drugs. Our data demonstrate that Tet-mediated active DNA demethylation occurs in vivo, and that acquisition of the precise molecular and electrophysiological properties of adult PCs requires continued oxidation of 5mC to 5hmC during the final phases of differentiation.

Project description:The eukaryotic cell cycle, driven by both transcriptional and post-translational mechanisms, is the central molecular oscillator underlying tissue growth throughout animals. While genome-wide studies have investigated cell cycle-associated transcription in unicellular systems, global patterns of periodic transcription in multicellular tissues remain largely unexplored. Here we define the cell cycle-associated transcriptome of the developing Drosophila wing epithelium and compare it with that of cultured Drosophila S2 cells, revealing a core set of periodic genes as well as a surprising degree of context-specificity in periodic transcription. We further employ RNAi-mediated phenotypic profiling to define functional requirements for over 300 periodic genes, with a focus on those required for cell proliferation in vivo. Finally, we investigate the role of novel genes required for interkinetic nuclear migration. Combined, these findings provide a global perspective on cell cycle control in vivo, and highlight a critical need to understand the context-specific regulation of cell proliferation. Cells from developing Drosophila wing epithelium, and cultured S2 cells are FACS sorted into G1 and G2 populations based on DNA content and compared in triplicate on Affymetrix microarrays to identify differences in the transcriptional program of the cell cycle by cell type.

Project description:Differentiation of multipotent stem cells into mature cells is fundamental for development and homeostasis of mammalian tissues. However, how this temporal process of cell cycle exit and induction of lineage-specific transcription programs is coordinated remains largely unknown. To understand the underlying mechanisms, we investigated how the tissue-specific transcription factors CEBPA and CEBPE coordinate cell cycle exit and lineage-specification during granulocytic differentiation. We demonstrate that CEBPA promotes lineage-commitment by launching an enhancer-primed differentiation program and direct activation of CEBPE expression. Subsequently, CEBPE confers promoter-driven cell cycle exit by sequential repression of MYC target gene expression at the G1/S transition and E2F-meditated G2/M gene expression, as well as by the up-regulation of Cdk1/2/4 inhibitors. Following cell cycle exit, CEBPE unleashes the CEBPA-primed differentiation program to generate mature granulocytes. These findings highlight how tissue-specific transcription factors coordinate cell cycle exit with terminal differentiation through the use of distinct gene regulatory elements.