Project description:Alu SINEs are the most numerous frequently occurring transcription units in our genome and possess sequence competence for transcription by RNA Pol III. However, through poorly understood mechanisms, the Alu RNA levels are maintained at very low levels in normal somatic cells with obvious benefits of low rates of Alu retrotransposition and energy-economical deployment of RNA Pol III to the tRNA genes which share promoter structure and polymerase requirements with Alu SINEs. Using comparative ChIP sequencing, we unveil that a repeat binding protein, CGGBP1, binds to the transcriptional regulatory regions of Alu SINEs thereby impeding Alu transcription by inhibiting RNA Pol III recruitment. We show that this Alu-silencing depends on growth factor stimulation of cells and subsequent tyrosine phosphorylation of CGGBP1. Importantly, CGGBP1 ensures a sequence-specific discriminative inhibition of RNA Pol III activity at Alu promoters, while sparing the structurally similar tRNA promoters. Our data suggest that CGGBP1 contributes to growth-related transcription by preventing the hijacking of RNA Pol III by Alu SINEs. This study was used to find out the effect of CGGBP1 on serum-induced changes in gene expression and effect of serum on gene expression regulation by CGGBP1.

Project description:Alu SINEs are the most numerous frequently occurring transcription units in our genomes and possess sequence competence for transcription by RNA Pol III. However, through poorly understood mechanisms, the Alu RNA levels are maintained at very low levels in normal somatic cells with obvious benefits of low rates of Alu retrotransposition and energy-economical deployment of RNA Pol III to the tRNA genes which share promoter structure and polymerase requirements with Alu SINEs. Using comparative ChIP sequencing, we unveil that a repeat binding protein, CGGBP1, binds to the transcriptional regulatory regions of Alu SINEs thereby impeding Alu transcription by inhibiting RNA Pol III recruitment. We show that this Alu-silencing depends on growth factor stimulation of cells and subsequent tyrosine phosphorylation of CGGBP1. Importantly, CGGBP1 ensures a sequence-specific discriminative inhibition of RNA Pol III activity at Alu promoters, while sparing the structurally similar tRNA promoters. Our data suggest that CGGBP1 contributes to growth-related transcription by preventing the hijacking of RNA Pol III by Alu SINEs. Examination of one DNA binding protein in two different conditions of treatment.

Project description:Alu SINEs are the most numerous frequently occurring transcription units in our genomes and possess sequence competence for transcription by RNA Pol III. However, through poorly understood mechanisms, the Alu RNA levels are maintained at very low levels in normal somatic cells with obvious benefits of low rates of Alu retrotransposition and energy-economical deployment of RNA Pol III to the tRNA genes which share promoter structure and polymerase requirements with Alu SINEs. Using comparative ChIP sequencing, we unveil that a repeat binding protein, CGGBP1, binds to the transcriptional regulatory regions of Alu SINEs thereby impeding Alu transcription by inhibiting RNA Pol III recruitment. We show that this Alu-silencing depends on growth factor stimulation of cells and subsequent tyrosine phosphorylation of CGGBP1. Importantly, CGGBP1 ensures a sequence-specific discriminative inhibition of RNA Pol III activity at Alu promoters, while sparing the structurally similar tRNA promoters. Our data suggest that CGGBP1 contributes to growth-related transcription by preventing the hijacking of RNA Pol III by Alu SINEs.

Project description:To find target genes of MYC in GP5d human colon cancer cells, the cells were treated with siRNA against CTNNB1 and MAX. The level of MYC knockdown in human was not sufficiently efficient to be included in the experiments within the criteria list, and hence the values from CTNNB1 knockdown were used as the expression MYC dropped to below 5% of that in the control sample in RNA­seq.

Project description:Oncogenic activating mutations in Ras genes are among the most common drivers of human disease. Treating mouse skin with the chemical carcinogen DMBA induces a characteristic mutation in Hras at codon 61. To understand how skin responds to a constitutive lack of Hras, we generated a cohort of Hras knockout mice. A backcross was generated using male Mus spretus and female FVB/N Hras-/- mice; female F1 hybrids were mated with male FVB/N Hras -/- or Hras -/+ mice to generate a backcross population. This series contains mice that were Hras -/-. Mice were aged to 8 weeks and a tail skin sample was snap frozen.

Project description:Gene expression levels in normal tissues can differ substantially between individuals, due to inherited polymorphisms acting in cis or trans. Analysis of this variation across a population of genetically distinct individuals allows us to visualize a network of co-expressed genes under normal homeostatic conditions, and the consequences of perturbation by tissue damage or disease development. Here, we explore gene expression networks in normal adult skin from 470 genetically unique mice, and demonstrate the dependence of the architecture of signaling pathways on skin tissue location (dorsal or tail skin) and perturbation by induction of inflammation or tumorigenesis. Gene networks related to specific cell types, as well as signaling pathways including Sonic Hedgehog (Shh), Wnt, Lgr family stem cell markers, and keratins differed at these tissue sites, suggesting mechanisms for the differential susceptibility of dorsal and tail skin to development of skin diseases and tumorigenesis. The Pten tumor suppressor gene network is extensively rewired in premalignant tumors compared to normal tissue, but this response to perturbation is lost during malignant progression. We present a software package for eQTL network analysis and demonstrate how network analysis of whole tissues provides insights into interactions between cell compartments and signaling molecules. Refer to individual Series

Project description:Although liganded nuclear receptors have been established to regulate RNA polymerase II (Pol II)-dependent transcription units, their role in regulating Pol III-transcribed DNA repeats remains largely unknown. Here we report that ~2-3% of the ~100,000-200,000 total human DR2 Alu repeats located in proximity to activated Pol II transcription units are activated by the retinoic acid receptor (RAR) in human embryonic stem cells to generate Pol III-dependent RNAs. These transcripts are processed, initially in aM-BM- DICER-dependent fashion, into small RNAs (~28-65 nt) referred to as repeat-induced RNAs that cause the degradation of a subset of crucial stem-cell mRNAs, includingM-BM- NanogM-BM- mRNA, which modulate exit from the proliferative stem-cell state. This regulation requiresM-BM- AGO3-dependent accumulation of processed DR2 Alu transcripts and the subsequent recruitment ofM-BM- AGO3-associated decapping complexes to the target mRNA. In this way, the RAR-dependent and Pol III-dependent DR2 Alu transcriptional events in stem cells functionally complement the Pol II-dependent neuronal transcriptional program. RNA-sequencing of polyA selected RNA molecules in NTera2/D1 cells and Global Run On (GRO) assay followed by high throughput sequencing (GRO-seq).

Project description:Gene expression levels in normal tissues can differ substantially between individuals, due to inherited polymorphisms acting in cis or trans. Analysis of this variation across a population of genetically distinct individuals allows us to visualize a network of co-expressed genes under normal homeostatic conditions, and the consequences of perturbation by tissue damage or disease development. Here, we explore gene expression networks in normal adult skin from 470 genetically unique mice, and demonstrate the dependence of the architecture of signaling pathways on skin tissue location (dorsal or tail skin) and perturbation by induction of inflammation or tumorigenesis. Gene networks related to specific cell types, as well as signaling pathways including Sonic Hedgehog (Shh), Wnt, Lgr family stem cell markers, and keratins differed at these tissue sites, suggesting mechanisms for the differential susceptibility of dorsal and tail skin to development of skin diseases and tumorigenesis. The Pten tumor suppressor gene network is extensively rewired in premalignant tumors compared to normal tissue, but this response to perturbation is lost during malignant progression. We present a software package for eQTL network analysis and demonstrate how network analysis of whole tissues provides insights into interactions between cell compartments and signaling molecules. Time course analysis of replicate exposure to epidermal application of TPA

Project description:While liganded nuclear receptors are well established to regulate Pol II protein-coding transcription units, their role in regulation of DNA repeats remains largely unknown. Here, we report that ~2-3% of the ~1-200,000 human DR2 Alu repeats, particularly those in proximity to retinoic acid-activated Pol II transcription units, are bound and activated by retinoic acid receptor in human embryonic stem cells, triggering their Pol  III-dependent transcription. The non-coding DR2 Alu transcripts are processed in a Dicer-dependent fashion into a series of small RNA products with sizes ranging ~28-65nt and exhibit substantial co-localization with P bodies. These small RNAs cause degradation of a subset of mRNAs critical for the "stem cell" state, which harbor complimentary sequences in their 3' untranslated regions. This regulation requires Ago3- dependent stabilization of full-length and processed DR2 Alu transcripts, and recruitment of Ago3-associated decapping complexes to the target mRNAs. Thus, the RAR/Pol III-dependent DR2 Alu transcriptional program in stem cells serves as a functional complement to the RAR/Pol II-dependent counterpart. ChIP-seq of H3K36me3 samples before and after RA (retinoic acid) treatments.

Project description:RNA polymerase (RNA Pol) III synthesizes the tRNAs, the 5S ribosomal RNA and a small number of untranslated RNAs. In vitro, it also transcribes short interspersed nuclear elements (SINEs). We investigated the distribution of RNA Pol III and its associated transcription factors on the genome of mouse embryonic stem (ES) cell using a highly specific tandem ChIP-Seq method. Only a subset of the annotated class-III genes was bound and thus transcribed. A few hundred SINEs were associated with the RNA Pol III transcription machinery. We observed that RNA Pol III and its transcription factors were present at thirty unannotated sites on the mouse genome, only one of which was conserved in human. An RNA was associated with more than 80% of these regions. More than 2200 regions bound by TFIIIC transcription factor were devoid of RNA Pol III. These sites are correlated with association of CTCF and the cohesin. Cohesin has been shown to occupy sites bound by CTCF and to contribute to DNA loop formation associated with gene repression or activation. This observation suggests that TFIIIC may play a role in chromosome organization in mouse. We also investigated the genome-wide distribution of the ubiquitous TFIIS variant, TCEA1. We found that, as in Saccharomyces cerevisiae, TFIIS is associated with class III genes and also with SINEs suggesting that TFIIS is a RNA Pol III transcription factor in mammals. We performed ChIP-seq experiment on mouse ES cells, in order to analyse the distribution of the RNA Pol III, with two of its subunits, RPC1 and RPC4, of the two distinct forms of the transcription factor TFIIIB, with BRF1 and BRF2, respectively subunit of TFIIIB-beta, and TFIIIB-alpha form, and three subunits of the transcription factor TFIIIC, TFIIIC90, TFIIIC110, TFIIIC220. We also analysed the distribution of the RNA Pol II elongation factor TCEA1. We used tagged proteins, in order to develop a highly specific and generic ChIP-seq protocol. A sequence encoding a 6 histidine-Flag-HA tag was inserted just after the last codon of the gene encoding proteins of the RNA Pol III machinery subunits, or just after the start codon for TCEA1, using the recombineering technology. Untagged ES cell line was used as negative control for data processing. Our dataset comprises of ten ChIP-seq samples, eight from tagged proteins, two from untagged cell line.