ABSTRACT: RNA-Seq performed on Dicer KO and WT murine mesenchymal stem cells from total RNA MicroRNAs (miRNAs) are small non-coding RNAs that regulates development and disease but induce only moderate repression of directs mRNA targets, suggesting that they coordinate with other modes ofs cellular regulation to effect large changes in gene expression. Ins this work we decouple direct effects of global miRNA loss froms transcriptional changes downstream in a pair of isogenic murines fibroblast cell lines with and without Dicer expression. Wes demonstrate how effects on direct miRNA targets are amplified bys transcription machinery through the construction of a network models that identifies specific transcription factors that cause changes ins mRNA expression upon Dicer loss. Through transcription factors over-expression, we delineate miRNA-mediated transcriptional programss and identify miRNA-mediated coherent and incoherent feed-forwards loops, suggesting a functional role of the interaction between miRNAss and transcription factors. In total, our results indicate thats miRNAs tightly control transcription factors within a denses interconnected network to modulate gene expression. Total RNA was analyzed from adult mesenchymal stem cells (immortalized monoclonal lines of murine MSCs) with and without Dicer (WT: Dicer f/f, KO: Dicer -/-), as well as from WT cells transfected with an empty vector or a vector containing Tead4, Sox9 or Pbx3 transcripts.
Project description:RNA-Seq performed on Dicer KO and WT murine mesenchymal stem cells MicroRNAs (miRNAs) are small non-coding RNAs that regulates development and disease but induce only moderate repression of directs mRNA targets, suggesting that they coordinate with other modes ofs cellular regulation to effect large changes in gene expression. Ins this work we decouple direct effects of global miRNA loss froms transcriptional changes downstream in a pair of isogenic murines fibroblast cell lines with and without Dicer expression. Wes demonstrate how effects on direct miRNA targets are amplified bys transcription machinery through the construction of a network models that identifies specific transcription factors that cause changes ins mRNA expression upon Dicer loss. Through transcription factors over-expression, we delineate miRNA-mediated transcriptional programss and identify miRNA-mediated coherent and incoherent feed-forwards loops, suggesting a functional role of the interaction between miRNAss and transcription factors. In total, our results indicate thats miRNAs tightly control transcription factors within a denses interconnected network to modulate gene expression. Examination of mature mRNA expression changes in adult mesenchymal stem cells (immortalized monoclonal lines of murine MSCs) with and without Dicer (WT: Dicer f/f, KO: Dicer -/-).
Project description:We performed ChIP-Seq of H3K27ac in duplicate in both WT and KO mesenchymal stem cells to evaluate global transcriptional changes between the new cells. We identified putative transcription factor binding sites using GEM v1.1 in K27ac data as well as in p MicroRNAs (miRNAs) are small non-coding RNAs that regulates development and disease but induce only moderate repression of directs mRNA targets, suggesting that they coordinate with other modes ofs cellular regulation to effect large changes in gene expression. Ins this work we decouple direct effects of global miRNA loss froms transcriptional changes downstream in a pair of isogenic murines fibroblast cell lines with and without Dicer expression. Wes demonstrate how effects on direct miRNA targets are amplified bys transcription machinery through the construction of a network models that identifies specific transcription factors that cause changes ins mRNA expression upon Dicer loss. Through transcription factors over-expression, we delineate miRNA-mediated transcriptional programss and identify miRNA-mediated coherent and incoherent feed-forwards loops, suggesting a functional role of the interaction between miRNAss and transcription factors. In total, our results indicate thats miRNAs tightly control transcription factors within a denses interconnected network to modulate gene expression. The experiment was designed to mimic the previously captured ChIP-Seq with two replicates in both WT and KO MSCs
Project description:RNA-Seq performed on Dicer KO and WT murine mesenchymal stem cells MicroRNAs (miRNAs) are small non-coding RNAs that regulates development and disease but induce only moderate repression of directs mRNA targets, suggesting that they coordinate with other modes ofs cellular regulation to effect large changes in gene expression. Ins this work we decouple direct effects of global miRNA loss froms transcriptional changes downstream in a pair of isogenic murines fibroblast cell lines with and without Dicer expression. Wes demonstrate how effects on direct miRNA targets are amplified bys transcription machinery through the construction of a network models that identifies specific transcription factors that cause changes ins mRNA expression upon Dicer loss. Through transcription factors over-expression, we delineate miRNA-mediated transcriptional programss and identify miRNA-mediated coherent and incoherent feed-forwards loops, suggesting a functional role of the interaction between miRNAss and transcription factors. In total, our results indicate thats miRNAs tightly control transcription factors within a denses interconnected network to modulate gene expression.
Project description:RNA-Seq performed on Dicer KO and WT murine mesenchymal stem cells from total RNA MicroRNAs (miRNAs) are small non-coding RNAs that regulates development and disease but induce only moderate repression of directs mRNA targets, suggesting that they coordinate with other modes ofs cellular regulation to effect large changes in gene expression. Ins this work we decouple direct effects of global miRNA loss froms transcriptional changes downstream in a pair of isogenic murines fibroblast cell lines with and without Dicer expression. Wes demonstrate how effects on direct miRNA targets are amplified bys transcription machinery through the construction of a network models that identifies specific transcription factors that cause changes ins mRNA expression upon Dicer loss. Through transcription factors over-expression, we delineate miRNA-mediated transcriptional programss and identify miRNA-mediated coherent and incoherent feed-forwards loops, suggesting a functional role of the interaction between miRNAss and transcription factors. In total, our results indicate thats miRNAs tightly control transcription factors within a denses interconnected network to modulate gene expression.
Project description:We performed ChIP-Seq of H3K27ac in duplicate in both WT and KO mesenchymal stem cells to evaluate global transcriptional changes between the new cells. We identified putative transcription factor binding sites using GEM v1.1 in K27ac data as well as in p MicroRNAs (miRNAs) are small non-coding RNAs that regulates development and disease but induce only moderate repression of directs mRNA targets, suggesting that they coordinate with other modes ofs cellular regulation to effect large changes in gene expression. Ins this work we decouple direct effects of global miRNA loss froms transcriptional changes downstream in a pair of isogenic murines fibroblast cell lines with and without Dicer expression. Wes demonstrate how effects on direct miRNA targets are amplified bys transcription machinery through the construction of a network models that identifies specific transcription factors that cause changes ins mRNA expression upon Dicer loss. Through transcription factors over-expression, we delineate miRNA-mediated transcriptional programss and identify miRNA-mediated coherent and incoherent feed-forwards loops, suggesting a functional role of the interaction between miRNAss and transcription factors. In total, our results indicate thats miRNAs tightly control transcription factors within a denses interconnected network to modulate gene expression.
Project description:MicroRNAs (miRNAs) are critical to proliferation, differentiation, and development. Here, we characterize gene expression in murine Dicer-null adult mesenchymal stem cell lines, a fibroblast cell type. Loss of Dicer leads to de-repression of let-7 targets at levels that exceed 10-100 fold with increases in transcription. Direct and indirect targets of this miRNA belong to a mid-gestation embryonic program that encompasses known oncofetal genes as well as oncogenes not previously associated with an embryonic state. Surprisingly, this mid-gestation program represents a distinct period that occurs between the pluripotent state of the inner cell mass at embryonic day 3.5 and the induction of let-7, upon differentiation, at embryonic day 10.5. Within this mid-gestation program, we characterize the let-7 target Nr6a1, an embryonic transcriptional repressor that regulates gene expression in adult fibroblasts following miRNA loss. In total, let-7 is required for the continual suppression of embryonic gene expression in adult cells, a mechanism that may underlie its tumor suppressive function. mRNAs from adult mesenchymal stem cells (immortalized monoclonal lines of murine MSCs) with and without Dicer (WT: Dicer f/f, KO: Dicer -/-), were analyzed. WT and KO cells were transfected with a nontargeting control siRNA. KO cells were separately transfected with a synthetic let-7g siRNA duplex, or an siRNA targeting Nr6a1.
Project description:Dicer is an RNase III-family endoribonuclease and haploinsufficient tumor suppressor that is required for the biogenesis of miRNAs, yet in vivo structure-function characterization of its RNase IIIA and IIIB domains have not been reported. In murine Dicer knockout fibroblasts, we expressed human Dicer with point mutations in the RNase III, helicase, and PAZ domains and characterized miRNA expression by Northern blot and massively parallel sequencing of small RNAs. Inactivation of the RNase IIIA or IIIB domain blocked maturation of miRNAs derived from the 3’ or 5’ arms of miRNA precursors, respectively, and resulted in altered miRNA expression profiles. Small RNAs from murine mesenchymal stem cells (MScs) with and without Dicer (WT:Dicer f/f, KO:Dicer -/-, KO transfected with various hsDicer point mutants) were analyzed.
Project description:MicroRNAs (miRNAs) are critical to proliferation, differentiation, and development. Here, we characterize gene expression in murine Dicer-null adult mesenchymal stem cell lines, a fibroblast cell type. Loss of Dicer leads to de-repression of let-7 targets at levels that exceed 10-100 fold with increases in transcription. Direct and indirect targets of this miRNA belong to a mid-gestation embryonic program that encompasses known oncofetal genes as well as oncogenes not previously associated with an embryonic state. Surprisingly, this mid-gestation program represents a distinct period that occurs between the pluripotent state of the inner cell mass at embryonic day 3.5 and the induction of let-7, upon differentiation, at embryonic day 10.5. Within this mid-gestation program, we characterize the let-7 target Nr6a1, an embryonic transcriptional repressor that regulates gene expression in adult fibroblasts following miRNA loss. In total, let-7 is required for the continual suppression of embryonic gene expression in adult cells, a mechanism that may underlie its tumor suppressive function. Examination of histone modifications in adult mesenchymal stem cells (immortalized monoclonal lines of murine MSCs) with and without Dicer (WT: Dicer f/f, KO: Dicer -/-).
Project description:Long noncoding RNAs (lncRNAs) are important regulators of cell fate, and their mis-expression has been implicated in many diseases. While distinct polymerases generate messenger vs. noncoding ribosomal or tRNAs3, little is known about distinct mechanisms controlling lncRNA expression. Here we show that transcription of lncRNAs is quantitatively different from that of messenger RNAs (mRNAs)--as revealed by deficiency of Dicer (Dcr), a key ribonuclease that generates microRNAs (miRNAs). Loss of Dcr in mouse embryonic stem cells (mESCs) led surprisingly to decreased level of the majority of lncRNAs. The canonical Dgcr8-Dcr-miRNA pathway is required for robust lncRNA expression, at the level of transcriptional initiation and elongation of lncRNA genes rather than at the level of their stability. cMyc, an oncogenic transcription factor, whose expression is indirectly regulated by Dcr-miRNA in mESCs, is partly responsible for lncRNA transcription. Loss of cMyc led to a more dramatic decrease of lncRNAs than mRNAs, and cMyc overexpression rescues lncRNA expression in Dcr KO cells. A quantitative metric of “mRNA-lncRNA decoupling” revealed that Dcr and cMyc differentially regulate lncRNAs vs. mRNAs in diverse cell types and in vivo, as evidenced by hundreds of microarray experiments. Thus, Dcr and cMyc may allow numerous lncRNAs to be activated or deactivated as a class, implicating lncRNAs to potential regulatory roles in development and disease states where Dcr and cMyc have been associated with. RNA was sequenced from WT and Dcr KO mESCs and the expression of lncRNAs and mRNAs are compared between WT and Dcr KO mESCs.
Project description:To determine the spectrum of miRNA targets regulated following Dicer deletion, we performed argonaute 2 (AGO2)-RNA Immunoprecipitation (RIP)-microarray in bone marrow-derived macrophages (BMDMs) from LysM-Cre/Dicerflox/flox/Apoe–/– and LysM-Cre/Dicerwt/wt/Apoe–/– mice. This analysis combined with miRNA profiling in Dicer wild type (WT) and knockout (KO) BMDMs may help to identify the miRNA targets regulated by Dicer deletion.