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

Project description:Here we were performed RNAseq to analyze the transcriptome changing of Hoxb5 in Pro/pre-B by over expression.

Project description:Chipseq were performed to analyze the targets of Hoxb5 in pro-/pre-B by over expression.

Project description:Natural hematopoietic stem cells are currently the only cell resource to generate entire T lymphopoiesis in vivo. Altenatively, functional and non-tumorigenic T lymphocytes converted from the other cell types remain unsuccessful. Evidence is still lacking about the concept that 'lineage-switching factors' (LSFs) exist in HSC, whose re-activation in progeny cells can accomplish lineage conversions. Here we show that upon ectopic expression of Hoxb5(a HSC-specific transcription factor), the Pro-/Pre-B cells were induced into functional early T cell progenitors(iETPs) in vivo. The reprogramming process initiated in the bone marrow and accomplished in the thymus at ETP stage. Strikingly, the T lymphocytes derived from iETPs resemble their natural counterparts in transcriptome pattern, hierarchical differentiation, tissue distribution and immune functions. Our observations pave the way for achieving lineage regeneration by direct reprogramming autologous somatic cells in vivo. Further, our success in haematopoietic system may build a paradigm for LSF-mediated regeneration of other tissues.

Project description:Transcription factor Hoxb5 reprograms B cells into functional T lymphocytes

Project description:Transcription factor Hoxb5 reprograms B cells into functional T lymphocytes [RNA-seq2]

Project description:Transcription factor Hoxb5 reprograms B cells into functional T lymphocytes [ChIP-Seq]

Project description:Through both gain- and loss-of-TTF-1 expression strategies, we show that TTF-1 positively regulates vascular endothelial growth factor (VEGF) and that the VEGF promoter element contains multiple TTF-1-responsive sequences. The major signaling receptor for VEGF, i.e VEGFR2, also appears to be under a direct and positive regulation of TTF-1. The TTF-1-dependent upregulation of VEGF was moderately sensitive to rapamycin, implicating a partial involvement of mammalian target of rapamycin (mTOR). However, hypoxia did not further increase the secreted VEGF level of the TTF-1(+) lung cancer cells. The TTF-1-induced VEGF upregulation occurs in both compartments (exosomes and exosome-depleted media (EDM)) of the conditioned media. Surprisingly, the EDM of TTF-1(+) lung cancer cells (designated EDM-TTF-1(+)) displayed an anti-angiogenic activity in the endothelial cell tube formation assay. Mechanistic studies suggest that the increased granulocyte-macrophage colony-stimulating factor (GM-CSF) level in the EDM-TTF-1(+) conferred the antiangiogenic activities. In human lung cancer, the expression of TTF-1 and GM-CSF exhibits a statistically significant and positive correlation. In summary, this study provides evidence that TTF-1 may reprogram lung cancer secreted proteome into an antiangiogenic state, offering a novel basis to account for the long-standing observation of favorable prognosis associated with TTF-1(+) lung adenocarcinomas.

Project description:We performed the single cell RNA-seq for the Hoxb5 Mac-1+CD48+ SK cells, bone marrow HSC, bone marrow MPP, and fetal liver HSC by Smart-Seq2.

Project description:Cell fate specification relies on the action of critical transcription factors that become available at distinct stages of embryonic development. One such factor is NeuroD1, which is essential for eliciting the neuronal development program and possesses the ability to reprogram other cell types into neurons. Given this capacity, it is important to understand its targets and the mechanism underlying neuronal specification. Here, we show that NeuroD1 directly binds regulatory elements of neuronal genes that are developmentally silenced by epigenetic mechanisms. This targeting is sufficient to initiate events that confer transcriptional competence, including reprogramming of transcription factor landscape, conversion of heterochromatin to euchromatin, and increased chromatin accessibility, indicating potential pioneer factor ability of NeuroD1. The transcriptional induction of neuronal fate genes is maintained via epigenetic memory despite a transient NeuroD1 induction during neurogenesis. NeuroD1 also induces genes involved in the epithelial-to-mesenchymal transition, thereby promoting neuronal migration. Our study not only reveals the NeuroD1-dependent gene regulatory program driving neurogenesis but also increases our understanding of how cell fate specification during development involves a concerted action of transcription factors and epigenetic mechanisms.