Project description:Chromatin accessibility was assessed by ATAC-Seq in lymphoid-primed multipotent progenitors (LMPPs) from human foetal livers (FLs) and mouse wild-type FLs as well as FLs from mouse embryos that express the oncofusion Mll-AF4 in the definitive blood system. The aim of this study was to establish whether overall chromatin accessibility at key haematopoietic sites and loci that have been linked to leukaemia are differentially accessible in human vs mouse LMPPs and whether this is altered by the expression of the Mll-AF4 oncofusion.
Project description:As MLL-rearranged infant leukaemia is known to initiate in utero, we sought to identify developemntal genes expressed in foetal cells that may aid leukaemogenesis. Bulk RNA-Seq was therefore carried out on mouse and human foetal liver blood progenitors (lymphoid-primed multipotent progenitors [LMPPs] and haematopoietic stem cells/ multipotent progenitor cells [HSC/MPPs]) and compared with the same cell types isolated from developmentally later human cord blood and mouse adult bone marrow.
Project description:We have used ATAC-seq to track cell state changes that occur during the differentiation of mouse embryonic stem cells to defined neural progenitor fates. We have performed ATAC-seq every 24 hours in cells en route to 3 distinct neural progenitors fates, anterior, hindbrain and spinal cord. This has allowed us to define how cells transition to a neural state, based on their enhancer usage. We identified regions distinct to different anterior-posterior neural progenitors, and validated their relevance by performing in vivo ATAC-seq on neural progenitors isolated from different axial levels of mouse embryos.
Project description:This is plate-based (SmartSeq2-Seq) single-cell transcriptome data set from 15 human foetal livers and bone marrow (17-22 PCW). It includes 5,867 cells with an average of 3,074 genes per cell before QC and 4,504 cells with an average of 3,642 genes per cell after QC.
Project description:During development of the human cerebral cortex, multipotent neural progenitors generate excitatory neurons and glial cells. This process is faithfully recapitulated in brain organoids. By using telencephalic brain organoids grown using a dual reporter cell line to isolate neural progenitors and neurons we generated a cell type and developmental stage-specific ATAC-seq dataset.