A Genome-Scale RNAi Screen for Oct4 Modulators Defines a Role of the Paf1 Complex for Embryonic Stem Cell Identity

Ding, Li; Paszkowski‐Rogacz, Maciej; Nitzsche, Anja; Słabicki, Mikołaj; Heninger, Anne-Kristin; Vries, Ingrid de; Kittler, Ralf; Junqueira, Magno; Shevchenko, Andrej; Schulz, Herbert; Hübner, Norbert; Doss, Michael Xavier; Sachinidis, Agapios; Hescheler, Juergen; Iacone, Roberto; Anastassiadis, Konstantinos; Stewart, A. Francis; Pisabarro, M. Teresa; Caldarelli, Antonio; Poser, Ina; Theis, Mirko; Buchholz, Frank

doi:10.1016/j.stem.2009.03.009

Cited by 233 publications

(274 citation statements)

References 49 publications

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“…Indeed, large-scale RNAi knockdown studies have led to the discovery of important mESC factors such as Esrrb, Tbx3 and Tcl1 [26], as well as the chromatin regulators Tip60-p400 [27] and SetDB1 [28]. Similarly, unbiased genome-wide siRNA screens were able to identify Cnot3 and Trim28 [29], Paf1C [30] and the mediator and cohesin complex [31] as important mESC transcriptional cofactors. Extending this approach into hESCs, Chia et al [32] used a similar genome-wide siRNA screening to identify components of the INO80 chromatin remodeling complex, the mediator and TAF transcriptional regulatory complexes, and the COP9 signalosomes as important hESC factors.…”

Section: The Expanded Esc Pluripotency Networkmentioning

confidence: 99%

The transcriptional regulation of pluripotency

Yeo

2012

Cell Res

114

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Abbreviations: 2C (2-cell); 2i (two inhibitor); BMP4 (bone morphogenic protein 4); ChIP (chromatin immunoprecipitation); ChIP-seq (chromatin immunoprecipitation and sequencing); ESCs (embryonic stem cells); EpiSCs (Epiblast-derived stem cells); Fgf4 (fibroblast growth factor 4); hESCs (human embryonic stem cells); ICM (inner cell mass); iPSCs (induced pluripotent stem cells); LIF (leukemia inhibitory factor); lincRNA (large intergenic non-coding RNA); mESCs (mouse embryonic stem cells); miRNA (micro RNA); ncRNA (non-coding RNA); PcG (Polycomb group proteins); PGCs (primodial germ cells); POU (Pit-Oct-Unc); RNAi (RNA interference); RNA-seq (RNA sequencing); SCF (stem cell factor); siRNA (short interfering RNA); XaXa (double X-chromosome active); XaXi (single X-chromosome inactivated)The defining features of embryonic stem cells (ESCs) are their self-renewing and pluripotent capacities. Indeed, the ability to give rise into all cell types within the organism not only allows ESCs to function as an ideal in vitro tool to study embryonic development, but also offers great therapeutic potential within the field of regenerative medicine. However, it is also this same remarkable developmental plasticity that makes the efficient control of ESC differentiation into the desired cell type very difficult. Therefore, in order to harness ESCs for clinical applications, a detailed understanding of the molecular and cellular mechanisms controlling ESC pluripotency and lineage commitment is necessary. In this respect, through a variety of transcriptomic approaches, ESC pluripotency has been found to be regulated by a system of ESC-associated transcription factors; and the external signalling environment also acts as a key factor in modulating the ESC transcriptome. Here in this review, we summarize our current understanding of the transcriptional regulatory network in ESCs, discuss how the control of various signalling pathways could influence pluripotency, and provide a future outlook of ESC research.

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Section: The Expanded Esc Pluripotency Networkmentioning

confidence: 99%

The transcriptional regulation of pluripotency

Yeo

2012

Cell Res

114

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“…RNAi-based high-throughput screening has become a widely used method for identification of new components of diverse biological processes, including signal transduction, cancer, and host cell responses to infection (1,2). Genome-scale RNAi screens have led to identification of tumor suppressors (3), oncogenes (4), therapeutic targets (5), and regulators of ES cell (ESC) maintenance (6)(7)(8)(9)(10), tissue regeneration (11), viral infection (12), and antiviral response (13).…”

mentioning

confidence: 99%

“…For example, multiple genomescale RNAi screens for host proteins required for HIV infection/ replication resulted in a limited overlap among screen hits at the gene level (1). Similarly, screens performed in mouse ESCs (mESCs) for genes essential for the maintenance of ESC identity resulted in only ∼8% overlap (8,9), although many of the unique hits in each screen were known or later validated to be real. The lack of concordance suggest that these screens have not reached saturation (14) and that additional genes of importance remain to be discovered.…”

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confidence: 99%

Integrative framework for identification of key cell identity genes uncovers determinants of ES cell identity and homeostasis

Cinghu

Yellaboina

Freudenberg

et al. 2014

Proc. Natl. Acad. Sci. U.S.A.

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Identification of genes associated with specific biological phenotypes is a fundamental step toward understanding the molecular basis underlying development and pathogenesis. Although RNAibased high-throughput screens are routinely used for this task, false discovery and sensitivity remain a challenge. Here we describe a computational framework for systematic integration of published gene expression data to identify genes defining a phenotype of interest. We applied our approach to rank-order all genes based on their likelihood of determining ES cell (ESC) identity. RNAi-mediated loss-of-function experiments on top-ranked genes unearthed many novel determinants of ESC identity, thus validating the derived gene ranks to serve as a rich and valuable resource for those working to uncover novel ESC regulators. Underscoring the value of our gene ranks, functional studies of our top-hit Nucleolin (Ncl), abundant in stem and cancer cells, revealed Ncl's essential role in the maintenance of ESC homeostasis by shielding against differentiation-inducing redox imbalance-induced oxidative stress. Notably, we report a conceptually novel mechanism involving a Nucleolin-dependent Nanog-p53 bistable switch regulating the homeostatic balance between self-renewal and differentiation in ESCs. Our findings connect the dots on a previously unknown regulatory circuitry involving genes associated with traits in both ESCs and cancer and might have profound implications for understanding cell fate decisions in cancer stem cells. The proposed computational framework, by helping to prioritize and preselect candidate genes for tests using complex and expensive genetic screens, provides a powerful yet inexpensive means for identification of key cell identity genes.C ell identity is governed by a set of key regulators, which maintain the gene expression program characteristic of that cell state while restricting the induction of alternate programs that could lead to a new cell state. Identification of cell identity genes is a fundamental step toward understanding the mechanisms that underlie cellular homeostasis, differentiation, development, and pathogenesis. RNAi-based high-throughput screening has become a widely used method for identification of new components of diverse biological processes, including signal transduction, cancer, and host cell responses to infection (1, 2). Genome-scale RNAi screens have led to identification of tumor suppressors (3), oncogenes (4), therapeutic targets (5), and regulators of ES cell (ESC) maintenance (6-10), tissue regeneration (11), viral infection (12), and antiviral response (13).Despite the success of RNAi screens, false discovery and sensitivity remain a significant and difficult problem to address, with surprisingly small overlap among screen hits from independent but related screens (1). For example, multiple genomescale RNAi screens for host proteins required for HIV infection/ replication resulted in a limited overlap among screen hits at the gene level (1). Similarly, screens performed in mous...

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“…Several genome-wide RNAi screens have identified factors required for self-renewal, and cohesin and condensin have shown up time and time again [13,[63][64][65][66]. Since self-renewal implies proliferation, these screens will identify a large fraction of genes required for DNA replication, repair and cell division.…”

Section: A Role For Cohesin In Gene Expression and Development: Disenmentioning

confidence: 99%