Project description:This SuperSeries is composed of the SubSeries listed below.

Project description:Leukemia stem cells (LSCs) are regarded as the origins and key therapeutic targets of leukemia, but limited knowledge is available on the key determinants of LSC “stemness”. Using single cell RNAseq analysis, we identify a master regulator PU.1, whose LSC-specific expression determines the molecular signature and activity of LSC in the Pten-null T-ALL model. Although initiated by PTEN controlled β-catenin activation, PU.1 expression and LSC “stemness” are maintained by a β-catenin-PU.1-TIM-3 feedback loop, independent of the leukemogenic driver mutation. Perturbing any component of this loop, either genetically or pharmacologically, can prevent LSC formation or eradicate existing LSCs. LSCs lose their “stemness” when PU.1 expression is silenced by DNA methylation, which can be reactivated by 5-AZ. Importantly similar regulatory mechanisms are also present in human T-ALLs.

Project description:Leukemia stem cells (LSCs) are regarded as the origins and key therapeutic targets of leukemia, but limited knowledge is available on the key determinants of LSC “stemness”. Using single cell RNAseq analysis, we identify a master regulator PU.1, whose LSC-specific expression determines the molecular signature and activity of LSC in the Pten-null T-ALL model. Although initiated by PTEN controlled β-catenin activation, PU.1 expression and LSC “stemness” are maintained by a β-catenin-PU.1-TIM-3 feedback loop, independent of the leukemogenic driver mutation. Perturbing any component of this loop, either genetically or pharmacologically, can prevent LSC formation or eradicate existing LSCs. LSCs lose their “stemness” when PU.1 expression is silenced by DNA methylation, which can be reactivated by 5-AZ. Importantly similar regulatory mechanisms are also present in human T-ALLs.

Project description:Leukemia stem cells (LSCs) are regarded as the origins and key therapeutic targets of leukemia, but limited knowledge is available on the key determinants of LSC “stemness”. Using single cell RNAseq analysis, we identify a master regulator PU.1, whose LSC-specific expression determines the molecular signature and activity of LSC in the Pten-null T-ALL model. Although initiated by PTEN controlled β-catenin activation, PU.1 expression and LSC “stemness” are maintained by a β-catenin-PU.1-TIM-3 feedback loop, independent of the leukemogenic driver mutation. Perturbing any component of this loop, either genetically or pharmacologically, can prevent LSC formation or eradicate existing LSCs. LSCs lose their “stemness” when PU.1 expression is silenced by DNA methylation, which can be reactivated by 5-AZ. Importantly similar regulatory mechanisms are also present in human T-ALLs.

Project description:T-ALL Leukemia Stem Cell “stemness” is Epigenetically Controlled by the Master Regulator PU.1

Project description:T-ALL Leukemia Stem Cell “stemness” is Epigenetically Controlled by the Master Regulator PU.1 [bulkRNA]

Project description:T-ALL Leukemia Stem Cell “stemness” is Epigenetically Controlled by the Master Regulator PU.1 [scRNA-seq]

Project description:T-ALL Leukemia Stem Cell “stemness” is Epigenetically Controlled by the Master Regulator PU.1 [BiSulfite-seq]

Project description:Glioblastoma (GBM) is the most aggressive and most lethal brain tumor. As current standard therapy consisting of surgery and chemo-irradiation provides limited benefit for GBM patients, novel therapeutic options are urgently required. Forkhead box M1 (FoxM1) transcription factor is an oncogenic regulator that promotes the proliferation, survival, and treatment resistance of various human cancers. The roles of FoxM1 in GBM remain incompletely understood, due in part to pleotropic nature of the FoxM1 pathway. Here, we show the roles of FoxM1 in GBM stem cell maintenance and radioresistance. ShRNA-mediated FoxM1 inhibition significantly impeded clonogenic growth and survival of patient-derived primary GBM cells with marked downregulation of Sox2, a master regulator of stem cell phenotype. Ectopic expression of Sox2 partially rescued FoxM1 inhibition-mediated effects. Conversely, FoxM1 overexpression upregulated Sox2 expression and promoted clonogenic growth of GBM cells. These data, with a direct binding of FoxM1 in the Sox2 promoter region in GBM cells, suggest that FoxM1 regulates stemness of primary GBM cells via Sox2. We also found significant increases in FoxM1 and Sox2 expression in GBM cells after irradiation both in vitro and in vivo orthotopic tumor models. Notably, genetic or a small-molecule FoxM1 inhibitor-mediated FoxM1 targeting significantly sensitized GBM cells to irradiation, accompanying with Sox2 downregulation. Finally, FoxM1 inhibition combined with irradiation in a patient GBM-derived orthotopic model significantly impeded tumor growth and prolonged the survival of tumor bearing mice. Taken together, these results indicate that the FoxM1-Sox2 signaling axis promotes clonogenic growth and radiation resistance of GBM, and suggest that FoxM1 targeting combined with irradiation is a potentially effective therapeutic approach for GBM.

Project description:Resident adult epithelial stem cells maintain tissue homeostasis by balancing self-renewal and differentiation. The stem cell potential of human epidermal keratinocytes is retained in vitro but lost over time suggesting extrinsic and intrinsic regulation. Transcription factor-controlled regulatory circuitries govern cell identity, are sufficient to induce pluripotency and transdifferentiate cells. We investigate whether transcriptional circuitry also governs phenotypic changes within a given cell type by comparing human primary keratinocytes with intrinsically high versus low stem cell potential. Using integrated chromatin and transcriptional profiling, we implicate IRF2 as antagonistic to stemness and show that it binds and regulates active cis-regulatory elements at interferon response and antigen presentation genes. CRISPR-KD of IRF2 in keratinocytes with low stem cell potential increases self-renewal, migration and epidermis formation. These data demonstrate that transcription factor regulatory circuitries, in addition to maintaining cell identity, control plasticity within cell types and offer potential for therapeutic modulation of cell function.