Project description:Neuroblastoma is an embryonic malignancy originating from early nerve cells. Neuroblastoma retains plasticity, interconverting between the mesenchymal (MES) and adrenergic (ADRN) states, which are controlled by different sets of transcription factors forming the core regulatory circuit (CRC). However, their functional roles and cooperative mechanisms in neuroblastoma pathogenesis are poorly understood. Here, we demonstrate that overexpression of ASCL1 in MES neuroblastoma cells opens closed chromatin at the promoters of key ADRN genes, accompanied by epigenetic activation and establishment of enhancer-promoter interactions, thereby initiating subtype switching. ASCL1 inhibits the TGFb-SMAD2/3 pathway but activates the BMP-SMAD1-ID3/4 pathway, serving as negative feedback to balance the function of ASCL1-TCF12 dimers. ASCL1 and other ADRN CRC members potentiate each other’s activity, increasing the expression of the original targets and inducing a new set of genes, thereby promoting conversion to ADRN neuroblastoma. Thus, via its pioneer factor function, ASCL1 serves as a master regulator that characterizes ADRN neuroblastoma.

Project description:Neuroblastomas (NBs) are aggressive pediatric tumors that are responsible for up to 15% of all pediatric cancer deaths. Two differentiation states exist in NB tumors, a majority of more committed ADRN tumor cells and a minority of neural crest cell (MES/NCC)-like cells. The transition between identity states is governed by different sets of master TFs that collectively form core regulatory circuitries (CRC) that drive high expression of downstream lineage-specific genes. In this study we aim to discover new lineage dependency factors in NB. Here, we identified the E-box transcription factor TCF4 (E2-2) not previously reported in NB to be a critical factor shared across both NB states and play important role in driving NB oncogenesis. We performed multiple functional and high-throughput analysis to delineate the unrecognized function of TCF4 in NB 

Project description:Neuroblastomas (NBs) are aggressive pediatric tumors that are responsible for up to 15% of all pediatric cancer deaths. Two differentiation states exist in NB tumors, a majority of more committed ADRN tumor cells and a minority of neural crest cell (MES/NCC)-like cells. The transition between identity states is governed by different sets of master TFs that collectively form core regulatory circuitries (CRC) that drive high expression of downstream lineage-specific genes. In this study we aim to discover new lineage dependency factors in NB. Here, we identified the E-box transcription factor TCF4 (E2-2) not previously reported in NB to be a critical factor shared across both NB states and play important role in driving NB oncogenesis. We performed multiple functional and high-throughput analysis to delineate the unrecognized function of TCF4 in NB 

Project description:Expression analysis of ADRN cell line SH-SY5Y with doxycycline-inducible NOTCH3-IC was used to study transcriptional reprogramming to a MES state.

Project description:Expression analysis of xenograft tumors of ADRN cell line SH-SY5Y with doxycycline-inducible NOTCH3-IC was used to study transcriptional reprogramming to a MES state in vivo.

Project description:A NOTCH feed-forward loop drives reprogramming from adrenergic to mesenchymal state in neuroblastoma.

Project description:Mesenchymal (MES)- and Adrenergic (ADRN) neuroblastoma cell line pairs of isogenic origin

Project description:This SuperSeries is composed of the following subset Series: GSE29182: Identification of active microRNA/transcription factor feed-forward loops during human adipogenesis (mRNA) GSE29185: Identification of active microRNA/transcription factor feed-forward loops during human adipogenesis (miRNA) Refer to individual Series

Project description:Tumor cell heterogeneity in neuroblastoma, a pediatric cancer arising from neural crest-derived progenitor cells, poses a significant clinical challenge. In particular, unlike adrenergic (ADRN) neuroblastoma cells, mesenchymal (MES) cells are resistant to chemotherapy and retinoid therapy and thereby significantly contribute to relapses and treatment failures. Previous research suggested that overexpression or activation of miR-124, a neurogenic microRNA with tumor suppressor activity, can induce the differentiation of retinoic acid-resistant neuroblastoma cells. Leveraging our established screen for miRNA modulatory small molecules, we validated PP121, a dual inhibitor of tyrosine and phosphoinositide kinases, as a robust inducer of miR-124. A combination of PP121 and miR-132-inducing bufalin synergistically arrests proliferation, induces differentiation, and prolongs the survival of differentiated MES SK-N-AS cells for 8 weeks. RNA-seq and deconvolution analyses revealed a collapse of the ADRN core regulatory circuitry (CRC) and the emergence of novel CRCs associated with chromaffin cells and Schwann cell precursors. Using a similar protocol, we differentiated and maintained other MES neuroblastoma, as well as glioblastoma cells, over 16 weeks. In conclusion, our novel protocol suggests a promising treatment for therapy-resistant cancers of the nervous system. Moreover, these long-lived, differentiated cells provide valuable models for studying mechanisms underlying differentiation, maturation, and senescence.

Project description:Pluripotent stem cells can be isolated from early embryos or induced by cell fusion, somatic nuclear transfer, or expression of a selected set of transcription factors. Embryonic stem (ES) cells are characterized by an open chromatin configuration and high transcription levels achieved via autoregulatory and feed-forward transcription factor loops. How the general transcription machinery is involved in pluripotency is unclear. Here, we show that TFIID knockdown affected the pluripotent circuitry in ES cells and inhibited reprogramming of fibroblasts. TFIID and pluripotency factors form a feed-forward loop to induce and maintain a stable transcription state. Strikingly, transient expression of TFIID subunits greatly enhanced reprogramming by Oct4, Sox2, Klf4 and c-Myc reaching efficiencies upto 50%. These results show that TFIID is a critical and selective component for transcription factor-mediated reprogramming. We anticipate that by creating plasticity in gene expression programs, basal transcription complexes such as TFIID assist reprogramming into different cellular states. Three iPS lines, iPS#1, iPS#4, and iPS#5 were used in duplicate for microarray analysis against a pool of RNA from ES-cells.