Project description:Rev-Erba and Rev-Erbb are nuclear receptors that regulate the expression of genes involved in the control of circadian rhythm, metabolism, and inflammatory responses. Rev-Erbs function as transcriptional repressors by recruiting NCoR/HDAC3 co-repressor complexes to Rev-Erb response elements in enhancers and promoters of target genes, but the molecular basis for cell-specific programs of repression is not known. Here, we present evidence that in macrophages, Rev-Erbs regulate target gene expression by inhibiting the functions of distal enhancers that are selected by macrophage lineage-determining factors, thereby establishing a macrophage-specific program of repression. Remarkably, the repressive functions of Rev-Erbs are associated with their ability to inhibit the transcription of enhancer-derived RNAs (eRNAs). Furthermore, targeted degradation of eRNAs at two enhancers subject to negative regulation by Rev-Erbs resulted in reduced expression of nearby mRNAs, implying a direct role of these eRNAs in enhancer function. By precisely defining eRNA start sites using a method that quantifies nascent 5' ends (5'-GRO-Seq), we show that transfer of full enhancer activity to a target promoter requires both the sequences mediating transcription factor binding and the specific sequences encoding the eRNA transcript. These studies provide evidence for direct roles of eRNAs in contributing to enhancer functions and suggest that Rev-Erbs act to suppress gene expression at a distance by repressing eRNA transcription. Using ChIPseq, GRO-seq, and 5'GRO-seq to determine mechanism of RevErb in transcriptional regulation in macrophages

Project description:The circadian clock regulates behavioural and physiological processes in a 24-h cycle. The nuclear receptors REV-ERBa and REV-ERBb are involved in the cell-autonomous circadian transcriptional/translational feedback loops as transcriptional repressors. A number of studies have also demonstrated a pivotal role of REV-ERBs in regulation of metabolic, neuronal, and inflammatory functions including bile acid metabolism, lipid metabolism, and production of inflammatory cytokines. Given the multifunctional role of REV-ERBs, it is important to elucidate the mechanism through which REV-ERBs exert their functions. To this end, we established a Rev-erba/Rev-erbb double-knockout mouse embryonic stem (ES) cell model and analyzed the circadian clock and clock-controlled output gene expressions. A comprehensive mRNA-seq analysis revealed that the complete knockout of both Rev-erba and Rev-erbb does not abrogate expression rhythms of E-box-regulated core clock genes but drastically changes a diverse set of other rhythmically-expressed output genes. Of note, REV-ERBa/b deficiency does not compromise circadian expression rhythms of PER2, while REV-ERB target genes, Bmal1 and Npas2, are significantly upregulated. This study emphasizes REV-ERBs function to form an essential link between the circadian clock and a wide variety of cellular physiological functions.

Project description:The functional importance of gene enhancers in regulated gene expression is well established. In addition to widespread transcription of long non-coding RNA (ncRNA) transcripts in mammalian cells, bidirectional ncRNAs referred to as eRNAs are present on enhancers. However, it has remained unclear whether these eRNAs are functional, or merely a reflection of enhancer activation. Here, we report that 17 ?-estradiol (E2)-bound estrogen receptor alpha (ER?) on enhancers causes a global increase in eRNA transcription on enhancers adjacent to E2 upregulated coding genes. These induced eRNAs, as functional transcripts, appear to exert important roles for the observed ligand-dependent induction of target coding genes, causing an increased strength of specific enhancer:promoter looping initiated by ER? binding. Cohesin, present on many ER?-regulated enhancers even prior to ligand treatment, apparently contributes to E2-dependent gene activation by stabilizing E2/ER?/eRNA-induced enhancer:promoter looping. Our data indicate that eRNAs are likely to exert important functions in many regulated programs of gene transcription. The ChIP-seqs in this study measure the binding landscape of master transcription regulator of estrogen signaling - ER?, together with common histone marks including H3K27ac and H3K4me1 in MCF7 cells. These data serve as the basis to understand the enhancer map and subsequent analysis of eRNA expression using GRO-seq. The GRO-seq measures the trancription of nascent RNAs in the genome. From MCF7 cells treated with veichle or estrodial, we could identify estrogen-regulated eRNAs and subsequently could study their functions.

Project description:Enhancer RNAs (eRNAs) play critical roles in diverse biological processes by mediating the activation of their target genes. However, the systematic landscape and potential regulations and functions of eRNAs during mammalian early embryo development remains elusive. Here, we present the comprehensive detection and characterization of eRNAs during mouse early embryo development. We demonstrated the spatiotemporal and allelic landscape of eRNA expression. We found the asymmetric activation of paternal-specific eRNAs during zygotic genome activation (ZGA). We identified TFs and their cooperation in regulating dynamic eRNA expression. eRNA are involved in multiple developmental signaling pathways through putatively regulating their target genes. Interestingly, we observed that the transcriptions of enhancers themselves are also widely modulated by eRNAs during mouse early embryo development. Critically, we de novo identified a novel eRNA transcribed from a super-enhancer region exclusively expressed at 2-cell stage of mouse early embryos and experimentally validated its key functional role in regulating ZGA and early embryo development.

Project description:The functional importance of gene enhancers in regulated gene expression is well established. In addition to widespread transcription of long non-coding RNA (ncRNA) transcripts in mammalian cells, bidirectional ncRNAs referred to as eRNAs are present on enhancers. However, it has remained unclear whether these eRNAs are functional, or merely a reflection of enhancer activation. Here, we report that 17 β-estradiol (E2)-bound estrogen receptor alpha (ERα) on enhancers causes a global increase in eRNA transcription on enhancers adjacent to E2 upregulated coding genes. These induced eRNAs, as functional transcripts, appear to exert important roles for the observed ligand-dependent induction of target coding genes, causing an increased strength of specific enhancer:promoter looping initiated by ERα binding. Cohesin, present on many ERα-regulated enhancers even prior to ligand treatment, apparently contributes to E2-dependent gene activation by stabilizing E2/ERα/eRNA-induced enhancer:promoter looping. Our data indicate that eRNAs are likely to exert important functions in many regulated programs of gene transcription.

Project description:Enhancers are transcription factor platforms that also bind RNA polymerase II and generate enhancer RNAs (eRNA). Although eRNAs have been suggested as predictors of enhancer activities and possibly key components facilitating transcription, there is little genetic evidence to support this. We address the biology of eRNAs in vivo and investigate eRNA patterns, expression levels and possible functions within a mammary-specific super-enhancer that is composed of three units with distinct transcriptional capacities. We show that eRNA levels do not correspond with the activities of their respective enhancer units. However, changes in eRNA expression upon deletion of individual enhancer units reflect the change in overall super-enhancer activity. These data provide genetic evidence that eRNA levels are not a reliable readout of individual enhancers, but they predict superenhancer activity in the absence of constituent elements.

Project description:The heart is a highly metabolic organ that uses multiple energy sources to meet its demand for ATP production. Diurnal feeding-fasting cycles result in substrate availability fluctuations which, together with increased energetic demand during the active period, impose a need for rhythmic cardiac metabolism. The nuclear receptors REV-ERBa and b are essential repressive components of the molecular circadian clock and major regulators of metabolism. To investigate their role in the heart, we generated mice with cardiomyocyte (CM)-specific deletion of both Rev-erbs, which died prematurely due to dilated cardiomyopathy. Loss of Rev-erbs markedly downregulated fatty acid oxidation genes prior to overt pathology, which was mediated by induction of the transcriptional repressor E4BP4, a direct target of cardiac REV-ERBs. E4BP4 directly controls circadian expression of Nampt and its biosynthetic product NAD+ via distal cis-regulatory elements. Thus, REV-ERB-mediated E4BP4 repression is required for Nampt expression and NAD+ production by the salvage pathway. Together, these results highlight the indispensable role of circadian REV-ERBs in cardiac gene expression, metabolic homeostasis and function.

Project description:We used genome-wide sequencing methods to study stimulus-dependent enhancer function in neurons. We identified ~12,000 neuronal activity-regulated enhancers that are bound by the general transcriptional co-activator CBP in an activity-dependent manner. A function of CBP at enhancers may be to recruit RNA polymerase II (RNAPII), as we also observed activity-regulated RNAPII binding to thousands of enhancers. Remarkably, RNAPII at enhancers transcribes bi-directionally a novel class of enhancer RNAs (eRNAs) within enhancer domains defined by the presence of histone H3 that is mono-methylated at lysine 4 (H3K4me1). The level of eRNA expression at neuronal enhancers positively correlates with the level of mRNA synthesis at nearby genes, suggesting that eRNA synthesis occurs specifically at enhancers that are actively engaged in promoting mRNA synthesis. These findings reveal that a widespread mechanism of enhancer activation involves RNAPII binding and eRNA synthesis. Examination of genome-wide binding of three types of modified histones, four transcription factors, and RNA polymerase II (ChIP-Seq), as well as RNA expression (RNA-Seq) before and after membrane depolarization via application of extracellular potassium.

Project description:Evidence of widespread transcription at active enhancers became apparent. However, our understanding about the functions of enhancer RNAs (eRNAs) and their mechanistic roles remains incomplete. Here, we study eRNA regulation and function using skeletal myoblast differentiation as a paradigm. We provide a panoramic view of enhancer transcription and uncover reprogramming in enhancer transcription occurring during myogenic differentiation. We demonstrate the critical role of MyoD in activating eRNAs production. Results from in depth dissection of two eRNAs transcribed from super enhancers (seRNA-1 and -2) suggest that seRNAs can promote myogenic differentiation in vitro and in vivo; the induction of the seRNAs is in coordination with the activation of the neighboring genes and seRNA loss largely impairs their expression. Mechanistically, we elucidate these seRNAs specifically bind to heterogeneous nuclear ribonucleoprotein L (hnRNPL) and modulate hnRNPL binding to the target promoter. A CAAA tract on the seRNA was identified to be essential in mediating the interaction between seRNA-1 and hnRNPL. Disruption of seRNA-hnRNPL interaction attenuates Pol II and H3K36me3 deposition at the target genes, in coincidence with the reduction of their expression. Furthermore, analyses of hnRNPL binding transcriptome-wide reveals its association with eRNAs is a general phenomenon in multiple cells. Collectively, we propose that eRNA-hnRNPL interaction contributes to target mRNA activation.

Project description:Evidence of widespread transcription at active enhancers became apparent. However, our understanding about the functions of enhancer RNAs (eRNAs) and their mechanistic roles remains incomplete. Here, we study eRNA regulation and function using skeletal myoblast differentiation as a paradigm. We provide a panoramic view of enhancer transcription and uncover reprogramming in enhancer transcription occurring during myogenic differentiation. We demonstrate the critical role of MyoD in activating eRNAs production. Results from in depth dissection of two eRNAs transcribed from super enhancers (seRNA-1 and -2) suggest that seRNAs can promote myogenic differentiation in vitro and in vivo; the induction of the seRNAs is in coordination with the activation of the neighboring genes and seRNA loss largely impairs their expression. Mechanistically, we elucidate these seRNAs specifically bind to heterogeneous nuclear ribonucleoprotein L (hnRNPL) and modulate hnRNPL binding to the target promoter. A CAAA tract on the seRNA was identified to be essential in mediating the interaction between seRNA-1 and hnRNPL. Disruption of seRNA-hnRNPL interaction attenuates Pol II and H3K36me3 deposition at the target genes, in coincidence with the reduction of their expression. Furthermore, analyses of hnRNPL binding transcriptome-wide reveals its association with eRNAs is a general phenomenon in multiple cells. Collectively, we propose that eRNA-hnRNPL interaction contributes to target mRNA activation.