Project description:Histone modifiers are crucial for instructing multiple-stage cellular differentiation, yet the mechanisms underlying their temporal precision remain enigmatic. Here, we demonstrate that the H3K27 demethylase Kdm6b acts as an epigenetic regulator, coordinating stepwise motor neuron (MN) differentiation through sequential partnerships with stage-specific transcription factors (TFs). Genome-wide profiling reveals a progressive gain in Kdm6b occupancy, especially at distal regulatory elements, as differentiation proceeds. Kdm6b dynamically shapes chromatin landscapes by coordinating H3K27me3 removal with H3K27ac and H3K4me1 acquisition, thereby enabling timed gene activation from MN specification to maturation. Stage-specific inhibition of Kdm6b compromised the ordered expression of developmental genes. Mechanistically, Kdm6b interacts with temporal TFs over time to ensure precise transcriptional control and MN differentiation. Our work elucidates how a single epigenetic regulator achieves temporal fidelity in driving stepwise MN development, and exemplifies a mechanistic insight into epigenetic regulation in determining developmental timing, with broad implications for understanding neurodevelopment and related diseases.dynamic epigenetic choreography to precisely regulate MN developmental programs from early MN fate specification, intermediate cell differentiation and growth to later maturation. The ordered expression of developmental genes was compromised by stage-specific Kdm6b inhibition. Our work resolves how a single epigenetic regulator achieves temporal precision in driving stepwise MN development, with broad implications for neurodevelopment and diseases.

Project description:Cell differentiation is controlled by transcription factors (TFs). However, we still do not fully understand which TFs are needed for even one mammalian differentiation pathway. To address this, we developed a detailed and integrated method. This method combines pluripotent stem cell differentiation in the lab, single-cell transcriptomics, and a CRISPR-based TF loss-of-function screen. Using this approach, we identified all the TFs required for spinal motor neuron (MN) differentiation in mice and their requirement in human MN differentiation. Our transcriptomic analysis revealed that while over 1,300 TFs are transcribed during ventral spinal cord differentiation, only 55 have annotated functions in the literature. The screen identified 232 TFs and other transcription-regulating genes essential for the progression of ventral spinal cord differentiation, including 116 TFs specifically required for MN differentiation. This approach led to three critical observations. First, the motor neuron progenitor (pMN) stage is a regulatory hub that correlates with a reduction in cell potential. Second, a secondary screen in human ventral spinal cord differentiation revealed a greater degree of conservation j between mouse pMNs and the human-specific ventral MN progenitors (vpMNs). This finding was unexpected, as the conservation was anticipated to be with the canonical human pMN stage. Third, the screen underscored the importance of the numerous and yet understudied ZF TFs controlling mammalian cell differentiation. In summary, we present a universal, unbiased strategy for studying TFs in mammalian differentiation, comparable to methodologies used in simpler organisms. This approach enhances our understanding of MN differentiation and provides a practical framework to identify all TFs required for any differentiation trajectory that can be recapitulated in vitro, offering many applications in various fields of developmental biology.

Project description:Kdm6b-mediated epigenetic coordination of temporal precision during motor neuron differentiation

Project description:Kdm6b-mediated epigenetic coordination of temporal precision during motor neuron differentiation [CutRun_CutTag]

Project description:Kdm6b-mediated epigenetic coordination of temporal precision during motor neuron differentiation [RNA-seq]

Project description:Epigenetic modifications play a crucial role in learning, memory and neurogenesis, but the study of its role in early neuroectoderm commitment from pluripotent inner cell mass is relatively lack. Here we utilized the system of directed neuroectoderm differentiation from human embryonic stem cells and identified KDM6B, an enzyme responsible to erase H3K27me3, was the most upregulated enzyme of histone methylation during neuroectoderm differentiation by transcriptome analysis. We then constructed KDM6B-null embryonic stem cells and found strikingly, the cells with KDM6B knockout exhibited much higher neuroectoderm induction efficiency. Furthermore, we constructed a serial of embryonic stem cell lines knocking out the other H3K27 demethylase KDM6A, and depleting both KDM6A and KDM6B, respectively. These cell lines together confirmed KDM6 impeded early neuroectoderm commitment. By RNA-seq, we found a panel of WNT activation genes significantly downregulated while WNT inhibiting genes significantly upregulated upon depletion of KDM6. Functional rescue assayed that WNT agonist could abolish the differential neuroectoderm induction due to manipulating KDM6 demonstrated WNT was the major downstream of KDM6 during early neural induction. Taken together, our findings illustrated the important role of histone methylation modifier KDM6A and KDM6B in neuroectoderm differentiation and provided additional insights into the precise epigenetic regulation in different stage of neurogenesis.

Project description:The integration of cell metabolism with signalling pathways, transcription factor networks and epigenetic mediators is critical in coordinating molecular and cellular events during embryogenesis. Induced pluripotent stem cells (IPSCs) are an established model for embryogenesis, germ layer specification and cell lineage differentiation, advancing the study of human embryonic development and the translation of innovations in drug discovery, disease modelling and cell-based therapies. The metabolic regulation of IPSC pluripotency is mediated by balancing glycolysis and oxidative phosphorylation, but there is a paucity of data regarding the influence of individual metabolite changes during cell lineage differentiation. We used ¹H NMR metabolite fingerprinting and footprinting to monitor metabolite levels as IPSCs are directed in a three-stage protocol through primitive streak/mesendoderm, mesoderm and chondrogenic populations. Metabolite changes were associated with central metabolism, with aerobic glycolysis predominant in IPSC, elevated oxidative phosphorylation during differentiation and fatty acid oxidation and ketone body use in chondrogenic cells. Metabolites were also implicated in the epigenetic regulation of pluripotency, cell signalling and biosynthetic pathways. Our results show that ¹H NMR metabolomics is an effective tool for monitoring metabolite changes during the differentiation of pluripotent cells with implications on optimising media and environmental parameters for the study of embryogenesis and translational applications.

Project description:The mechanistic links between transcription factors and the epigenetic landscape, which coordinate the deregulation of gene networks during cell transformation are largely unknown. We used an isogenic model of stepwise tumorigenic transformation of human primary cells to monitor the progressive deregulation of gene networks upon immortalization and oncogene-induced transformation. By combining transcriptome and epigenome data for each step during transformation and by integrating transcription factor (TF) - target gene associations, we identified 142 TFs and 24 chromatin remodelers/modifiers (CRMs), which are preferentially associated with specific co-expression paths that originate from deregulated gene programming during tumorigenesis. These TFs are involved in the regulation of divers processes, including cell differentiation, immune response and establishment/modification of the epigenome. Unexpectedly, the analysis of chromatin state dynamics revealed patterns that distinguish groups of genes, which are not only co-regulated but also functionally related. Further decortication of TF targets enabled us to define potential key regulators of cell transformation, which are engaged in RNA metabolism and chromatin remodelling. Our study suggests a direct implication of CRMs in oncogene-induced tumorigenesis and identifies new CRMs involved in this process. This is the first comprehensive view of gene regulatory networks that are altered during the process of stepwise human cellular tumorigenesis in a virtually isogenic system. Examination of 4 different histone modifications marks and RNA PolII in all 3 cell lines of stepwise tumorigenesis model with biological replicates

Project description:The mechanistic links between transcription factors and the epigenetic landscape, which coordinate the deregulation of gene networks during cell transformation are largely unknown. We used an isogenic model of stepwise tumorigenic transformation of human primary cells to monitor the progressive deregulation of gene networks upon immortalization and oncogene-induced transformation. By combining transcriptome and epigenome data for each step during transformation and by integrating transcription factor (TF) - target gene associations, we identified 142 TFs and 24 chromatin remodelers/modifiers (CRMs), which are preferentially associated with specific co-expression paths that originate from deregulated gene programming during tumorigenesis. These TFs are involved in the regulation of divers processes, including cell differentiation, immune response and establishment/modification of the epigenome. Unexpectedly, the analysis of chromatin state dynamics revealed patterns that distinguish groups of genes, which are not only co-regulated but also functionally related. Further decortication of TF targets enabled us to define potential key regulators of cell transformation, which are engaged in RNA metabolism and chromatin remodelling. Our study suggests a direct implication of CRMs in oncogene-induced tumorigenesis and identifies new CRMs involved in this process. This is the first comprehensive view of gene regulatory networks that are altered during the process of stepwise human cellular tumorigenesis in a virtually isogenic system. Affymetrix SNP arrays (250K) were performed according to the manufacturer's directions on DNA extracted from BJ, BJEL and BJELM cells

Project description:The mechanistic links between transcription factors and the epigenetic landscape, which coordinate the deregulation of gene networks during cell transformation are largely unknown. We used an isogenic model of stepwise tumorigenic transformation of human primary cells to monitor the progressive deregulation of gene networks upon immortalization and oncogene-induced transformation. By combining transcriptome and epigenome data for each step during transformation and by integrating transcription factor (TF) - target gene associations, we identified 142 Tfs and 24 chromatin remodelers/modifiers (CRMs), which are preferentially associated with specific co-expression paths that originate from deregulated gene programming during tumorigenesis. These Tfs are involved in the regulation of divers processes, including cell differentiation, immune response and establishment/modification of the epigenome. Unexpectedly, the analysis of chromatin state dynamics revealed patterns that distinguish groups of genes, which are not only co-regulated but also functionally related. Further decortication of TF targets enabled us to define potential key regulators of cell transformation, which are engaged in RNA metabolism and chromatin remodelling. Our study suggests a direct implication of CRMs in oncogene-induced tumorigenesis and identifies new CRMs involved in this process. This is the first comprehensive view of gene regulatory networks that are altered during the process of stepwise human cellular tumorigenesis in a virtually isogenic system. Transcriptional activity in BJEL and BJELM cells has been evaluated and compared with that found in BJ cells; 2 biological replicates per cell line