Project description:RECQL5 globally effects the distribution of RNA Polymerase II on genes in a dose dependent manner. Knock-down of RECQL5 reduces RNA Polymerase II density in the gene body, while increasing density on TSS and TTS. Overexpression shows exactly the opposite effect. We postulate that RECQL5 acts as a regulator of the elongation rate, more specifically, that the knock-down increases elongation rate while the overexpression decreases it. RNA Polymerase II ChIP-Seq upon knock-down of RECQL5 with either of two specific shRNAs or a CTRL shRNA, and upon Doxycycline induced overexpression of RECQL5 .

Project description:Global Run-On has been performed on WT or KD for RECQL5 cells after release from DRB. When RECQL5 is knocked-down the transcriptional wave front is more advanced, suggesting that transcription is faster. Constitutive knock-down cell lines expressing or not endogenous levels of shRNA resistant RECQL5 under a Doxycycline inducible promoter were treated with high doses of DRB to block transcription. Upon release into fresh medium we were able to follow how much and how fast the RNA Pol II progresses through genes by mapping nascent RNA by Run-On. The experiment was performed in two cell line clones.

Project description:In the activated B-cell-like (ABC) subtype of diffuse large B cell lymphoma (DLBCL), the most frequent gain-of-function mutations target MyD88, a signaling adapter for Tolllike receptors (TLRs). The most prevalent oncogenic mutant, MyD88 L265P, occurs in 29% of cases and is the most active in engaging the NF-kappaB pathway. Here we show that MyD88 mutants do not function autonomously, but rather require TLR7, TLR9, and to a lesser extent, TLR4 to promote the survival of ABC DLBCL cells. Unlike wild type MyD88, MyD88 mutants associate constitutively with TLR7 and TLR9 in ABC DLBCL cells. Like ligand-induced TLR7/9 signaling in normal immune cells, the survival of ABC DLBCL cell lines depends upon translocation of TLR7 and TLR9 to acidic endolysosomes, where proteolytic processing of their ligand binding ectodomains is required for their oncogenic signaling. ABC DLBCL viability also depends upon CD14, a co-receptor for TLR7 and TLR9 that promotes engagement of nucleic acid ligands by these receptors. Point mutations in the TLR7 or TLR9 ectodomains that abrogate ligand binding and/or signaling were incapable of sustaining ABC DLBCL survival. An inhibitory oligonucleotide that suppresses TLR9 responses in normal B cells blocked NF-kappaB signaling and survival of ABC DLBCL lines. Together, these data suggest that an endogenous TLR ligand may play a pathogenic role in ABC DLBCL and provide a rationale for targeting TLR signaling to improve therapy of this aggressive lymphoma. Gene expression was analyzed using Agilent human 2-color 4X44K oligo gene expression arrays. Cell line, TMD8 ABC-DLBCL, was infected with control (shControl, Cy3), shLTR7 (Cy5) or shLTR9 (Cy5) and changes in gene expression were monitored on day 1 and day 2 after induction of the shRNA with doxycycline, co-hybridizing control and experimental samples (Cy3+Cy5), for a total of 4 arrays.

Project description:Developmental checkpoints in stem/progenitor cells are critical to the determination, commitment and differentiation into distinct lineages. Cancer cells often retain expression of lineage-specific checkpoint proteins, but their potential impact in cancer remains elusive. T lymphocytes mature in the thymus following a highly orchestrated developmental process that entails the successive rearrangements and expression of T-cell receptor (TCR) genes. Low affinity recognition of self-peptide/MHC complexes (self-pMHC) presented by thymic epithelial cells by the TCR of CD4+CD8+ (DP) cortical thymocytes transduces positive selection signals that ultimately shape the developing T cell repertoire. DP thymocytes not receiving these signals die by lack of stimulation whereas those that recognize self-pMHC with high affinity undergo TCR-mediated apoptosis and negative selection. In T-cell acute lymphoblastic leukaemia (T-ALL), leukaemic transformation of maturating thymocytes results from the acquisition of multiple genetic and epigenetic alterations in oncogenes and tumour suppressor genes, that disrupt the normal regulatory circuits and drive clonal expansion of differentiation-arrested lymphoblasts. We show here that TCR triggering by negatively-selecting self-pMHC prevented T-ALL development and leukaemia maintenance in mice. Induction of TCR signalling by high affinity self-pMHC or treatment with monoclonal antibodies to the CD3 signalling chain (anti-CD3) caused massive leukaemic cell death and a gene expression program resembling that of thymocyte negative selection. Importantly, anti-CD3 treatment hampered leukaemogenesis in mice transplanted with either mouse or patient-derived T-ALLs. These data provide a rationale for targeted therapy based on anti-CD3 treatment of T-ALL patients and demonstrate that endogenous developmental checkpoint proteins are amenable to therapeutic intervention in cancer cells. Gene expression data from four culture conditions was performed for the following cells: ALL-SIL-TCRα/β-GFP co-cultured on OP9-DL1 for 48 h, ALL-SIL-TCRα/β-GFP without co-culture, ALL-SIL cells transduced with TLX shRNA (sh-TLX), and ALL-SIL transduced with sh-control vectors. All conditions are performed in two replicates.

Project description:Using two different approaches to CK2alpha-silencing, we have used RNA-seq to identify variation in gene-expression of important cell cycle regulators with relevance to heart-associated defects.

Project description:Transcriptional profiling of primary human white preadipocytes after infection with lentiviral vector either containing shRNA directed against dipeptidypeptidase 4 (DPP4) or unspecific shRNA as negative control Treatment of cells with DPP4 shRNA or control shRNA was done in 4 biological replicates, the first sample of DPP4 KD was hybridized against the first sh-control sample, the second DPP4 smple against the second control sample and so on

Project description:A non-functional myosin Vb motor in duodenal enterocytes results in disruption of epithelial cell polarity characterized by complete loss of microvilli and mislocalization of apical brush border proteins in the cytoplasm which finally cause a devastating disease in neonates with severe malabsorption defects accompanied by protracted diarrhea during infancy, classified as microvillus inclusion disease (MVID). The exact mechanisms how loss-of-function of MYO5B induces polarity loss are not completely understood in MVID pathogenesis. Obtaining better insights in cell polarity defects caused by loss of MYO5B, we performed microarray- in combination with protein expression-analysis in an inducible CaCo2 MYO5B RNAi cell system. Surprisingly, in MYO5B-depleted CaCo2 cells, CDH1 coding for the cell adhesion protein E-Cadherin and important for cell adhesion and therefore maintenance of cell polarity, was significantly downregulated. Interestingly, mesenchymal cell markers, specifically Vimentin and N-Cadherin, physiologically not expressed in differentiated epithelium, were upregulated and accompanied by increased phospho-c-jun levels in the nucleus. Importantly phospho-c-jun was also found in nuclei of duodenal enterocytes in MVID patients, indicating loss of MYO5B induces epithelial cell scattering in enterocytes. 3 Myosin 5B KD versus 3 control samples

Project description:Recruitment of the RNA Polymerase II (Pol II) transcription initiation apparatus to promoters by specific DNA binding transcription factors is well recognized as a key regulatory step in gene expression. We describe here evidence that promoter-proximal pausing is a general feature of transcription by Pol II in embryonic stem (ES) cells, and thus an additional step where regulation of gene expression may occur. We report here that c-Myc, which occupies a third of actively transcribed genes in ES cells and is a key regulator of cellular proliferation, binds P-TEFb and contributes to release of promoter-proximal paused Pol II at these genes. ChIP-seq data for Pol II and additional factors controlling pause release in mouse ES cells.

Project description:We report how CSB affects globally the density of RNA Pol II at TSS and how this effect correlates with the gene expression alterations observed from microarray analysis. We also show globally the distribution of CSB. RNA Pol II and CSB ChIP-Seq in CS1AN cells and CSB reconstituted wild type cells, in duplicate, using Illumina GAIIx

Project description:Background: Genome-wide transcriptome profiling generated by microarray and RNA-Seq often provides deregulated genes or pathways applicable only to larger cohort. On the other hand, individualized interpretation of transcriptomes is increasely pursued to improve diagnosis, prognosis, and patient treatment processes. Yet, robust and accurate methods based on a single paired-sample remain an unmet challenge. Methods: M-bM-^@M-^\N-of-1-pathwaysM-bM-^@M-^] translates gene expression data profiles into mechanism-level profiles on single pairs of samples (one p-value per geneset). It relies on three principles: i) statistical universe is a single paired sample, which serves as its own control; ii) statistics can be derived from multiple gene expression measures that share common biological mechanisms assimilated to genesets; iii) semantic similarity metric takes into account inter-mechanismsM-bM-^@M-^Y relationships to better assess commonality and differences, within and cross study-samples (e.g. patients, cell-lines, tissues, etc.), which helps the interpretation of the underpinning biology. Results: In the context of underpowered experiments, N-of-1-pathways predictions perform better or comparable to those of GSEA and Differentially Expressed Genes enrichment (DEG enrichment), within- and cross-datasets. N-of-1-pathways uncovered concordant PTBP1-dependent mechanisms across datasets (Odds-RatiosM-bM-^IM-%13, p-valuesM-bM-^IM-$1M-CM-^W10-5), such as RNA splicing and cell cycle. In addition, it unveils tissue-specific mechanisms of alternatively transcribed PTBP1-dependent genesets. Furthermore, we demonstrate that GSEA and DEG Enrichment preclude accurate analysis on single paired samples. Conclusions: N-of-1-pathways enables robust and biologically relevant mechanism-level classifiers with small cohorts and one single paired samples that surpasses conventional methods. Further, it identifies unique sample/ patient mechanisms, a requirement for precision medicine. Cell lines, culture conditions: The epithelial human breast cancer cell line MDA-MB231 (ER-/ PR-/ HER2-) were obtained from the American Type Culture Collection (Manassas, VA). The epithelial human ovarian tumor cell line A2780 was received as a generous gift from Dr. Thomas C. Hamilton (Fox Chase Cancer Center, Philadelphia, PA) Cancer Center, Philadelphia, PA). Cells were grown in DMEM supplemented with 10% fetal bovine serum (FBS), 2mM L-glutamine in a humid environment at 37M-BM-0C, with 5% CO2. Both cell lines were free of Mycoplasma species and were maintained for no longer than 10 weeks in culture after recovery from frozen stocks. Mycoplasma levels were checked periodically using the MycoAlertM-BM-. Mycoplasma Detection Kit (Lonza Inc., Allendale, NJ). The authenticity of cell lines was assessed by the ATCC carrying out short tandem repeat (STR) analysis (Verified STR Profiling Service, ATCCM-BM-. 135-XV). Additionally, we compared A2780 to the original STR profile collected by the European Collection of Cell Culture (Catalogue number 93112519). Doxycycline-inducible knockdown of PTBP1 regulated by small hairpin RNA (shRNA): In order to analyze the effect of PTBP1 depletion, two consecutive viral transductions were performed in both MDA-MB231 and A2780 cell lines. Cells were plated on 24-well plate (10-20M-CM-^W104 cells/well), maintained in culture for 16 hours, and then medium containing LV-tTR/KRAB-Red lentiviral particles was added. Following 16 h of incubation, cells were transduced a second time by LV-THM/PTBshRNA or LV-THM/LUCshRNA lentiviral particles. Clones expressing both red and green fluorescent protein (dsRED and GFP respectively) were selected and expanded. Following 16 h of incubation, cells were washed and split in two subcultures, one without doxycycline (PTBP1/-DOX; Control in Figure 1) and the other with Doxycycline (DOX) at a final concentration of 1 M-NM-<g/ml (PTBP1/+DOX; PTBP1-KD in Figure 1). Doxycycline was prepared according to the manufacturerM-bM-^@M-^Ys recommendations (Sigma-Aldrich, St. Louis, MO). Five days later, cells were analyzed by fluorescence microscopy, and PTBP1 gene expression was assessed using PCR and Western Blotting (data not shown). The cells that were transduced by LV-LUCshRNA express PTBP1 regardless of the presence of DOX (LUCshRNA/+DOX). Constructs and lentivirus preparation were performed as previously described in literature [He X et al., Knockdown of polypyrimidine tract-binding protein suppresses ovarian tumor cell growth and invasiveness in vitro, Oncogene 2007, 26(34):4961-4968]. Microarray Analysis: For each of the cell lines, MDA-MB231 and A2780, total RNAs were extracted from four biological replicates of PTBP1-depleted cells, PTBP1-KD (4M-CM-^W PTBP1/+DOX) and eight biological replicates control cells (4M-CM-^W PTBP1/-DOX and 4M-CM-^W LUCshRNA/+DOX) by Direct-zol RNA kit (Zymo Research, Irvine, CA). All paired samples consist of PTBP1-depleted cells (PTBP1-KD) and matched control cells. Qualities of RNA were assessed based on the RNA quality indicator (RQI M-bM-^IM-% 8) using Experion Automated Electrophoresis System (Bio-Rad, Hercules, CA). Gene expression microarray measurements were performed using the GeneChip PrimeView Human Gene Expression Array that contains 49,395 probes and measures 36,000 transcripts and variants per sample. Labeling and hybridization were performed following Affymetrix protocols. The raw data were normalized according to the Robust Multiple-array Average (RMA) technique, using Affymetrix Power Tools (APT). biological replicate: Ovarian_LucsH_DOX_1, Ovarian_LucsH_DOX_2, Ovarian_LucsH_DOX_3, Ovarian_LucsH_DOX_4 biological replicate: Ovarian_PTBsh1_NODOX_1, Ovarian_PTBsh1_NODOX_2, Ovarian_PTBsh1_NODOX_3, Ovarian_PTBsh1_NODOX_4 biological replicate: Ovarian_PTBsh1_DOX_1, Ovarian_PTBsh1_DOX_2, Ovarian_PTBsh1_DOX_3, Ovarian_PTBsh1_DOX_4 biological replicate: Breast_LucsH_DOX_1, Breast_LucsH_DOX_2, Breast_LucsH_DOX_3, Breast_LucsH_DOX_4 biological replicate: Breast_PTBsh1_NODOX_1, Breast_PTBsh1_NODOX_2, Breast_PTBsh1_NODOX_3, Breast_PTBsh1_NODOX_4 biological replicate: Breast_PTBsh1_DOX_1, Breast_PTBsh1_DOX_2, Breast_PTBsh1_DOX_3, Breast_PTBsh1_DOX_4