Project description:Transcription by RNA polymerase (RNAP) is interrupted by pauses that play diverse regulatory roles. Although individual pauses have been studied in vitro, the determinants of pauses in vivo and their distribution throughout the bacterial genome remain unknown. Using nascent transcript sequencing we identify a 16 nt consensus pause sequence in E. coli that accounts for known regulatory pause sites as well as ~20,000 new in vivo pause sites. In vitro single-molecule and ensemble analyses demonstrate that these pauses result from RNAP/nucleic-acid interactions that inhibit next-nucleotide addition. The consensus sequence also leads to pausing by RNAPs from diverse lineages and is enriched at translation start sites in both E. coli and B. subtilis. Our results thus implicate a conserved mechanism unifying known and newly identified pause events. Examination of nascent transcripts in E. coli and B. subtilis. 6 samples of E. coli NET-seq, 1 sample of E. coli mRNA-seq, and 1 sample of B. subtilis NET-seq.

Project description:Recent evidence suggests that RNA interaction can regulate the activity and localization of DNA binding proteins, particularly chromatin-associated proteins. However, it is unknown if these observations are specialized instances for a few key RNAs and chromatin factors in specific contexts, or a general mechanism underlying the establishment of chromatin state and regulation of gene expression. Here, we introduce formaldehyde RNA ImmunoPrecipitation (fRIP-Seq), a sensitive method for cataloging RNA-protein interactions, to survey the RNA associated with a panel of 24 chromatin-associated and traditional RNA binding proteins. For each protein that reproducibly bound measurable quantities of bulk RNA (90% of the panel), we detected enrichment for hundreds to thousands of both noncoding and mRNA transcripts. We found that the enriched sets of RNA share biochemical, functional, and epigenetic properties. Thus, these data provide strong evidence that non-random RNA association is a common feature across diverse classes of chromatin modifying complexes. RNA associated with 24 different proteins using fRIP was compared to total RNA-seq

Project description:A large fraction of our genome consists of mobile genetic elements. Governing transposons in germ cells is critically important, and failure to do so compromises genome integrity, leading to sterility. In animals, the piRNA pathway is the key to transposon constraint, yet the precise molecular details of how piRNAs are formed and how the pathway represses mobile elements remain poorly understood. In an effort to identify general requirements for transposon control and novel components of the piRNA pathway, we carried out a genome-wide RNAi screen in Drosophila ovarian somatic sheet cells. We identified and validated 87 genes necessary for transposon silencing. Among these were several novel piRNA biogenesis factors. We also found CG3893 (asterix) to be essential for transposon silencing, most likely by contributing to the effector step of transcriptional repression. Asterix loss leads to decreases in H3K9me3 marks on certain transposons but has no effect on piRNA levels. We sequenced small RNAs, RNA-seq and ChIP-seq from either tj-Gal4 driven hpRNA knockdown flies or P-element insertion flies

Project description:Fragile-X Syndrome (FXS) is a multi-organ disease leading to mental retardation, macro-orchidism in males, and premature ovarian insufficiency in female carriers. FXS is also a prominent monogenic disease associated with autism spectrum disorders (ASD). FXS is typically caused by the loss of FRAGILE X-MENTAL RETARDATION 1 (FMR1) expression, which encodes for the RNA-binding protein (RBP), FMR1 (or FMRP). We report the discovery of the RNA recognition elements (RREs), binding sites, and mRNA targets for wild-type and I304N mutant FMRP isoforms as well as its paralogs, FXR1 and FXR2. RRE frequency, ratio, and distribution determine target mRNA association with FMRP. Among highly-enriched targets, we identified many genes involved in ASD and demonstrate that FMRP can affect their protein levels in cell culture, mice, and human brain. Unexpectedly, we discovered that these targets are also dysregulated in Fmr1-/- mouse ovaries, showing signs of premature follicular overdevelopment. These results indicate that FMRP targets shared signaling pathways across different cellular contexts. As it is become increasingly appreciated that signaling pathways are important to FXS and ASD, our results here provide an invaluable molecular guide towards the pursuit of novel therapeutic targets for these devastating neurological disorders. The mRNA profile of RNA recovered from FLAG-antibody immunoprecipitated FMRP was compared to the mRNA profile of the starting lysate material.

Project description:Eukaryotic ribosomal RNA carries diverse posttranscriptional modifications, among which the evolutionarily conserved 2’-O-methylation (2’-O-Me) occurs at more than 100 sites and is essential for ribosome biogenesis. Plasticity of 2´-O-Me in ribosomes and its functional consequences in human disease are not yet known. Here, we present the full rRNA 2’-O-Me landscape (ribomethylome) of human acute myeloid leukemia (AML) through profiling 94 patient samples as well as 21 normal hematopoietic samples of 5 different lineages. While interior modification sites in functional centers are persistently fully 2’-O-methylated in human AMLs, methylation on ribosome exterior sites is unprecedentedly dynamic. Higher 2’-O-methylation on exterior dynamic sites is associated with leukemia stem cell (LSC) signatures. Forced expression of enzymatically active but not of the catalytic defect 2’-O-methyltransferase FBL induces AML stemness and accelerates leukemogenesis in patient-derived xenografts. Mechanistically, ribomethylome dynamics shifted mRNA ribosome translation preferences. High rRNA 2’-O-Me enhances translation of amino acid transporters enriched in optimal codons and subsequently increases intra-cellular amino acid levels. Methylation on a single exterior modification site affects leukemia stem cell activity. The Guanosine 1447 on the small subunit ribosomal RNA is the most variable site in primary AMLs. Gm1447 is increased in leukemia stem cell populations compared to non-leukemogenic blast cells and AML specimens with higher Gm1447 are enriched for leukemia stem cell genes. Comparison of Gm1447high and Gm1447low ribosome structure solved by cryo-electron microscopy demonstrated disassociation of LYAR from Gm1447low ribosomes. Suppression of Gm1447 alone is sufficient to suppress translation of amino acid transporters, resulting in decreased cellular amino acid levels and leukemia stem cell activity. Taken together, our data reveal the dynamic FBL-mediated rRNA 2'-O-Me landscape as a novel epitranscriptomic level of control employed by leukemic stem cells and may enable new strategies to target human AML.

Project description:CENP-A, a variant of histone H3, is incorporated into centromeric chromatin and plays a role during kinetochore establishment. In fission yeast, the localization of CENP-A is limited to a region spanning 10 to 20 kb of the core domain of the centromere. Here, we report a mutant (rpt3-1) in which this region is expanded to 40 to 70 kb. Likely due to abnormal distribution of CENP-A, this mutant exhibits chromosome instability and enhanced gene silencing. Interestingly, the rpt3+ gene encodes a subunit of the 19S proteasome, which localizes to the nuclear membrane. While Rpt3 associates with centromeric chromatin, the mutant protein has lost this localization. A loss of the cut8+ gene encoding an anchor of the proteasome to the nuclear membrane causes similar phenotypes as observed in the rpt3-1 mutant. Thus, we propose that the proteasome (or its subcomplex) associates with centromeric chromatin and regulates distribution of CENP-A. Chromosomal distributions of differentially expressed centromere protein A in wild-type and a proteasome mutant.

Project description:Nascent transcription profiles are shown for scaled megadomains and 100kb flanking regions before BRD4-NUT induction (0h) and at different time points (2h, 3h, 7h) following induction in 293T cells. Increase of the transcription from 0h to 7h after induction. Average level of transcriptional activity is reduced within the megadomains and their flanking regions following JQ1 treatment of TC-797 cells. Profile of nascent RNA-seq is shown for cells without JQ1 treatment, and for cells 1hr, 2.5hr and 4hr following JQ1 treatment. Recovery and analysis of nascent RNA

Project description:This SuperSeries is composed of the following subset Series: GSE27650: Bacillus subtilis SigA ChIP-chip (BsubT1 array) GSE27665: Bacillus subtilis SigA ChIP-chip (BsubT2 array) Refer to individual Series

Project description:The goal of this study is to identify likely sites of polycistronic transcription initiation in a kinetoplastid parasite. Peaks in histone H3 acetylations were found to mark these likely sites, with TBP and SNAP50 enriched upstream of these acetylation peaks. Acetylation peaks are greater in rapidly dividing cells than in stationary cells. Each ChIP sample was compared to an input chromatin sample that underwent a mock immunoprecipitation (without antiserum), or in the case of acetylH3 ChIPs, used an antiserum that recognized total H3 histones. Log ratios and raw scores for each probe are provided.

Project description:The following data contains sequencing files for RNA IP and Polysome profiling experiments in wt and not5delta strains with background of Not1-TAP tagged strain (MAT_ leu2_20 ura3_ met15_ lys2_ his3delta1 not1::NOT1-Tap-tag-URA3). The RNA IP experiments have been performed as described previously (Gupta et al 2014) and the Polysome profiling experiments have been performed as described in (Albanese 2010). The libraries have been sequenced using polyadenylation isoform specific profiling protocol. The Not1 RIP experiments demonstrate genome-wide association of RNA with the central essential scaffold of the Ccr4-Not complex. The same RIP experiment in the not5delta background demonstrates the specificity of not5 in determining Not1 binding specificity to pulled down RNA. The polysome profiling experiments demonstrate the role of not5 in determining the translatability of ribosomal RNA.