Project description:The biological functions of nuclear topoisomerase I (Top1) have been difficult to study because knocking out TOP1 is lethal in metazoans. To reveal the functions of human Top1, we have generated stable Top1siRNA cell lines from colon and breast carcinomas (HCT116-siTop1 and MCF-7-siTop1, respectively). In those cells, Top2 compensates for Top1 deficiency. A prominent feature of the siTop1 cells is genomic instability, with chromosomal aberrations and histone gamma-H2AX foci associated with replication. siTop1 cells also show rDNA and nucleolar alterations, and increased nuclear volume. Genome-wide transcription profiling revealed 55 genes with consistent changes in siTop1 cells. Among them, asparagine synthetase (ASNS) was reduced in siTop1 cells, as it also was in cells with transient Top1 downregulation. Conversely, Top1 complementation increased ASNS, indicating a causal link between Top1 and ASNS expression. Correspondingly, pharmacological profiling showed l-asparaginase hypersensitivity in the siTop1 cells. Resistance to camptothecin, aphidicolin, hydroxyurea and staurosporine, and hypersensitivity to etoposide and actinomycin D demonstrated that Top1, in addition to being the target of camptothecins, also regulates DNA replication, rDNA stability and apoptosis. Overall, our studies demonstrate the pleiotropic nature of human Top1 activities. In addition to its classical DNA nicking-closing functions, Top1 plays critical non-classical roles in genomic stability, gene-specific transcription, and response to various anticancer agents. Experiment Overall Design: We are using Affymetrix whole genome array U133 Plus 2, which is a single color microarray platform. For colon experiments, we analyzed 2 different samples as 4 replicates. For breast experiments, we analyzed 2 samples as replicates.

Project description:HeLa cells were fracitonated into nuclear soluble, chromatin bound and cytosolic. Extracts were immunoprecipitated with a CSN3 antibody, then eluted with glycine. Proteins were digested, then enriched for phosphopeptides. Samples were analyzed on an LTQ-Orbitrap. Data was analyzed using the TRansOMics software for time alignment and feature detection. MS/MS spectra searched using Mascot.

Project description:N6-methyladenosine (m6A) is the most prevalent internal modification found in mammalian messenger and non-coding RNAs. The discoveries of functionally significant demethylases that reverse this methylation as well as the recently revealed m6A distributions in mammalian transcriptomes strongly indicate regulatory functions of this modification. Here we report the identification and characterization of the mammalian nuclear RNA N6-adenosine methyltransferase core (RNMTC) complex. Besides METTL3, a methyltransferase which was the only known component of RNMTC in the past, we discovered that a previously uncharacterized methyltransferase, METTL14, exhibits a N6-adenosine methyltransferase activity higher than METTL3. Together with WTAP, the third component that dramatically affects the cellular m6A level, these three proteins form the core complex that orchestrates m6A deposition on mammalian nuclear RNA. Biochemistry assays, imaging experiments, as well as transcriptome-wide analyses of the binding sites and their effects on m6A methylation support methylation function and reveal new insights of RNMTC. PAR-CLIP and m6A-seq in HeLa cells

Project description:This SuperSeries is composed of the following subset Series: GSE39855: LIN28 binds messenger RNAs at GGAGA motifs and regulates splicing factor abundance (splicing array) GSE39872: LIN28 binds messenger RNAs at GGAGA motifs and regulates splicing factor abundance (HTS) Refer to individual Series

Project description:The ring-shaped cohesin complex links sister chromatids until their timely segregation during mitosis. Cohesin is enriched at centromeres, where it provides the cohesive counter-force to bi-polar tension produced by the mitotic spindle. As a consequence of spindle tension, centromeric sequences transiently split in pre-anaphase cells, in some organisms up to several micrometeres. This M-bM-^@M-^Xcentromere breathingM-bM-^@M-^Y presents a paradox, how sister sequences separate where cohesin is most enriched. We now show that in the budding yeast S. cerevisiae, cohesin binding diminishes over centromeric sequences that split during breathing. We see no evidence for cohesin translocation to surrounding sequences, suggesting that cohesin is removed from centromeres during breathing. Two pools of cohesin can be distinguished. Cohesin loaded before DNA replication, that has established sister chromatid cohesion, disappears during breathing. In contrast, cohesin loaded after DNA replication is partly retained. As sister centromeres re-associate after transient separation, cohesin is re-loaded in a manner independent of the canonical cohesin loader Scc2/Scc4. Efficient centromere re-association requires the cohesion establishment factor Eco1, suggesting that re-establishment of sister chromatid cohesion contributes to the dynamic behaviour of centromeres in mitosis. These findings provide new insights into cohesin behaviour at centromeres. Keywords: ChIP-chip SAMPLES Origin of each biological sample: Saccharomyces cerevisiae (W303background) Growth conditions: Cells containing the MET3-CDC20 allele were grown at 25M-BM-0C in SC medium lacking methionine with 2% raffinose or 2% glucose as the carbon source (Uhlmann et al. 2000). Cultures were synchronized in G1 with M-NM-1-factor (5 M-NM-<g/ml) and released into medium containing 100 mM hydroxyurea (HU) for arrest in early S-phase. For arrest in metaphase, cells were released from M-NM-1-factor or HU arrest by filtration and re-suspension in YP medium supplemented with 5 mM methionine to deplete Cdc20. To inactivate cohesin loading, cells harbouring the temperature sensitive scc2-4 allele (Ciosk et al. 2000) were shifted to the restrictive temperature of 35M-BM-0C for 1 hour before release. To prevent metaphase spindle assembly, or to disassemble already formed spindles, 7.5 M-NM-<g/ml nocodazole was added to the medium for 1 hour. To wash out nocodazole, cells were filtered again, washed, and re-suspended in fresh medium lacking nocodazole for 1 hour. Expression of Scc1 to induce differentially epitope-tagged cohesin under control of the GAL1 promoter, or of Cdc14, was achieved by addition of 2% galactose for 1 hour to cultures grown in raffinose-containing medium. EXPERIMENTAL DESIGN Experiment type: ChIP-chip = Chromatin immunoprecipitation (ChIP) followed by hybridization to a high-density oligonucleotide microarray (chip). Number of hybridizations performed: 13 ChIP-chip samples; 2 SUPernatant samples Analysis: ChIP samples were normalized against SUPernatant fractions Quality control: Confirmation of results by duplication of experiments, by usage of different epitope tags for the same protein, and by usage of different subunits of the same protein complex. Also, whole cell extract, SUPernatant, and ChIP fractions were checked by Western blotting. Protocols: ChIP-chip and hybridization protocols were performed as previously described (Katou et al. 2003; Lengronne et al. 2004; Lengronne et al. 2006). A summary is provided below: ChIP. Cells were grown under the conditions described above and cross-linked with 1% formaldehyde. Cells were disrupted using a Multi-Beads Shocker, and whole cell extracts were sonicated to obtain 400-600 bp genomic DNA fragments. Chromatin immunoprecipitation (ChIP) was performed with anti-HA antibody or anti-PK monoclonal antibody coupled to protein A Dynabeads. Immunprecipates were eluted and incubated overnight at 65M-BM-:C to reverse the cross-link. The immunoprecipitated genomic DNA was then incubated with proteinase K, extracted twice with phenol/chloroform/isoamylalcohol, precipitated, resuspended in TE and incubated with RNaseA. The DNA was purified, concentrated by ethanol precipitation and amplified by PCR after random priming. 10ug of the amplified DNA was digested with DNase I and end-labelled using TdT Terminal Transferase and Biotin-N6-ddATP. Hybridization and scanning. Samples were hybridized in buffer containing SSPE, TritonX-100, denatured salmon sperm DNA and biotin-labelled control oligonucleotide, oligo B2. Samples were denatured at 95M-BM-:C for 10 minutes before being hybridized to the arrays for 16 hours at 42M-BM-:C in a GeneChip Hybridization Oven 640. The washing and scanning protocol (FlexMidi_euk2v3_450), provided by Affymetrix, was performed automatically on a GeneChip Fluidics Station 450. Arrays were scanned using the GeneChip Scanner 3000 7G, and primary analysis of tiling chip data was performed using the Affymetrix GeneChip Operating Software (GCOS). ARRAY DESIGN General array design: in situ synthesized arrays from Affymetrix Location and ID of each spot on arrays: available upon request from Affymetrix Probe type: oligonucleotide Availability of arrays: commercially available from Affymetrix S. cerevisiae (Chromosome VI) rikDACF, P/N# 510636 S. cerevisiae T iling Array (Forward), P/N# 520286 REFERENCES Ciosk R, Shirayama M, Shevchenko A, Tanaka T, Toth A, Shevchenko A, Nasmyth K (2000) Cohesin's binding to chromosomes depends on a separate complex consisting of Scc2 and Scc4 proteins. Mol Cell 5: 1-20 Katou Y, Kanoh Y, Bandoh M, Noguchi H, Tanaka H, Ashikari T, Sugimoto K, Shirahige K (2003) S-phase checkpoint proteins Tof1 and Mrc1 form a stable replication-pausing complex. Nature 424: 1078-1083 Lengronne A, Katou Y, Mori S, Yokobayashi S, Kelly GP, Itoh T, Watanabe Y, Shirahige K, Uhlmann F (2004) Cohesin relocation from sites of chromosomal loading to places of convergent transcription. Nature 430: 573-578 Lengronne A, McIntyre J, Katou Y, Kanoh Y, Hopfner K-P, Shirahige K, Uhlmann F (2006) Establishment of sister chromatid cohesion at the S. cerevisiae replication fork. Mol Cell 23: 787-799 Uhlmann F, Wernic D, Poupart M-A, Koonin EV, Nasmyth K (2000) Cleavage of cohesin by the CD clan protease separin triggers anaphase in yeast. Cell 103: 375-386

Project description:Snail is a zinc-finger transcription factor best known for its ability to down-regulate E-cadherin. Its established significance in embryology and organogenesis has been expanded to include a role in the tumor progression of a number of human cancers. In addition to E-cadherin, it has more recently been associated with the down-regulation and up-regulation of a number of other genes that affect important malignant phenotypes. After establishing the presence of up-regulated Snail in human non-small cell lung cancer specimens, we used microarrays to detail the global programme of gene expression in non-small cell lung cancer cell lines stably transduced to over-express Snail as compared to vector control cell lines. Non-small cell lung cancer cell lines (H441, H292, H1437) were stably transduced with a retroviral vector to over-express Snail. Elevated Snail and a corresponding down-regulation of E-cadherin was verified in the Snail over-expressing cell lines as compared to vector control cell lines by Western analysis. RNA extraction was performed and samples submitted to the UCLA Clinical Microarray Core for hybridization to Affymetrix arrays.

Project description:LIN28 is a conserved RNA binding protein implicated in pluripotency, reprogramming and oncogenesis. Previously shown to act primarily by blocking let-7 microRNA (miRNA) biogenesis, here we elucidate distinct roles of LIN28 regulation via its direct messenger RNA (mRNA) targets. Through cross-linking and immunoprecipitation coupled with high-throughput sequencing (CLIP-seq) in human embryonic stem cells and somatic cells expressing exogenous LIN28, we have defined discrete LIN28 binding sites in a quarter of human transcripts. These sites revealed that LIN28 binds to GGAGA sequences enriched within loop structures in mRNAs, reminiscent of its interaction with let-7 miRNA precursors. Among LIN28 mRNA targets, we found evidence for LIN28 autoregulation and also direct but differing effects on the protein abundance of splicing regulators in somatic and pluripotent stem cells. Splicing-sensitive microarrays demonstrated that exogenous LIN28 expression causes widespread downstream alternative splicing changes. These findings identify important regulatory functions of LIN28 via direct mRNA interactions. In triplicate, polyA-selected RNA was extracted from untreated Flp-In-293 cells, stable LIN28V5 293 cells, TDP-43 over-expressed Flp-In-293 cells, control over-expressed Flp-In-293 cells, LIN28 depleted hES cells, and control depleted hES cells, and hybridized to custom human splicing sensitive microarrays

Project description:We used ATLAS-seq-neo to map the sites of integration of an engineered LINE-1 (L1) retrotransposon into the genome of HeLa S3 cells. In brief, we transfected cells with a plasmid-borne L1.3 element carrying a neomycin-resistance-based retrotransposition cassette, as well as a hygromycin-resistance cassette on the plasmid backbone. For this set of experiments, cells were only selected for transfection (hygromycin) but not for retrotransposition (neomycin). Then we prepared ATLAS-seq-neo libraries. Each sample corresponds to an independent transfection and pool of hygromycin-resistant cells. ATLAS-seq-neo relies on the random mechanical fragmentation of the genomic DNA to ensure high-coverage, ligation of adapter sequences, suppression PCR-amplification of the 3' end L1 junction with its flanking genomic sequence, and Ion Torrent sequencing using single-end 400 bp read chemistry. The primer used for suppression PCR specifically targets the engineered element and not endogenous copies as in the original ATLAS-seq protocol (Philippe et al. eLife 2016). For some libraries, the linker-ligated genomic DNA was digested with BamHI, which cuts downstream of L1 polyA site in the plasmid backbone, to limit amplification from the plasmid and enrich for retrotransposition-mediated insertion events into the genomic DNA.

Project description:To identify Lgl binding proteins, we purified Lgl-containing protein complexes from cultured Drosophila S2 cells, using the single-step streptavidin purification from stable cell lines expressing SBP-tagged Lgl, followed by nanoLC-MS/MS analysis of the interactors. This study revealed the binding of Lgl to Vap33, which we further connected to the function of the vacuolar ATPase and regulation of Notch signaling.

Project description:Transfection of human SCCHN cell line with vectors containing deltaNp63 isoforms.