Project description:Human pluripotent stem cells (hPSCs) provide a valuable platform for studies of human neuronal differentiation, but the mechanisms regulating the timing of this process remain poorly understood. This study compares two differentiation systems with distinct timing of differentiation, transcription factor (TF)-induced forward programming and stepwise cellular differentiation. Our analyses reveal that divergent cellular trajectories drive distinct neurogenesis timing. Multi-omic analysis identifies crucial gene regulatory networks (GRNs) that govern cell fate determination and timing control. Modulation of these GRNs modulates neurogenesis and timing of neuronal maturation. Specifically, OLIG family TFs, enriched in the TF-induced system, promoted cell cycle exit through NOTCH signaling regulation; conversely, ablation of these TFs delayed neurogenesis. In contrast, NEUROD2 overexpression accelerated neuronal maturation through precocious activation of maturation gene modules. Collectively, these findings illuminate characteristics of the cell-intrinsic mechanisms that govern timing of differentiation; the studies also offer a framework for investigation into, and the rational design of, timing-controlled in vitro differentiation strategies.

Project description:Human pluripotent stem cells (hPSCs) provide a valuable platform for studies of human neuronal differentiation, but the mechanisms regulating the timing of this process remain poorly understood. This study compares two differentiation systems with distinct timing of differentiation, transcription factor (TF)-induced forward programming and stepwise cellular differentiation. Our analyses reveal that divergent cellular trajectories drive distinct neurogenesis timing. Multi-omic analysis identifies crucial gene regulatory networks (GRNs) that govern cell fate determination and timing control. Modulation of these GRNs modulates neurogenesis and timing of neuronal maturation. Specifically, OLIG family TFs, enriched in the TF-induced system, promoted cell cycle exit through NOTCH signaling regulation; conversely, ablation of these TFs delayed neurogenesis. In contrast, NEUROD2 overexpression accelerated neuronal maturation through precocious activation of maturation gene modules. Collectively, these findings illuminate characteristics of the cell-intrinsic mechanisms that govern timing of differentiation; the studies also offer a framework for investigation into, and the rational design of, timing-controlled in vitro differentiation strategies.

Project description:Human pluripotent stem cells (hPSCs) provide a valuable platform for studies of human neuronal differentiation, but the mechanisms regulating the timing of this process remain poorly understood. This study compares two differentiation systems with distinct timing of differentiation, transcription factor (TF)-induced forward programming and stepwise cellular differentiation. Our analyses reveal that divergent cellular trajectories drive distinct neurogenesis timing. Multi-omic analysis identifies crucial gene regulatory networks (GRNs) that govern cell fate determination and timing control. Modulation of these GRNs modulates neurogenesis and timing of neuronal maturation. Specifically, OLIG family TFs, enriched in the TF-induced system, promoted cell cycle exit through NOTCH signaling regulation; conversely, ablation of these TFs delayed neurogenesis. In contrast, NEUROD2 overexpression accelerated neuronal maturation through precocious activation of maturation gene modules. Collectively, these findings illuminate characteristics of the cell-intrinsic mechanisms that govern timing of differentiation; the studies also offer a framework for investigation into, and the rational design of, timing-controlled in vitro differentiation strategies.

Project description:While changes in chromatin are integral to transcriptional reprogramming during cellular differentiation, it is currently unclear how chromatin modifications are targeted to specific loci. We developed a computational model on the premise that transcription factors (TFs) direct dynamic chromatin changes during cell fate decisions. When applied to a neurogenesis paradigm, this approach predicted the TF REST as a determinant of gain of Polycomb-mediated H3K27me3 in neuronal progenitor cells. We prove this prediction experimentally by showing that the absence of REST causes loss of H3K27me3 at target promoters in trans at the same cellular state. Moreover, promoter fragments containing a REST binding site are sufficient to recruit H3K27me3 in cis, while deletion of their REST site results in loss of H3K27me3. These findings illustrate that computational modeling can systematically identify TFs that regulate chromatin dynamics genome-wide. Local determination of Polycomb activity by REST exemplifies such TF based regulation of chromatin. Expression profiling of REST knock-out (RESTko) versus REST wildtype (RESTwt) or REST heterozygous knock-out (RESThet) cells at three stages of in vitro neuronal differentiation. RESTko and RESTwt/RESThet embryonic stem (ES) cells were differentiated to terminal neurons (TN) via a defined neuronal progenitor (NP) state. Three biological replicates (suffixes a to c).

Project description:Temporal data on gene expression and context-specific open chromatin states can improve identification of key transcription factors (TFs) and the gene regulatory networks (GRNs) controlling cellular differentiation. However, their integration remains challenging. Here, we delineate a general approach for data-driven and unbiased identification of key TFs and dynamic GRNs, called EPIC-DREM. We generated time-series transcriptomic and epigenomic profiles during differentiation of mouse multipotent bone marrow stromal cells (MSCs) towards adipocytes and osteoblasts. Using our novel approach we constructed time-resolved GRNs for both lineages and identifed the shared TFs involved in both differentiation processes. To take an alternative approach to prioritize the identified shared regulators, we mapped dynamic super-enhancers in both lineages and associated them to target genes with correlated expression profiles. The combination of the two approaches identified aryl hydrocarbon receptor (AHR) and Glis family zinc finger 1 (GLIS1) as mesenchymal key TFs controlled by dynamic MSC-specific super-enhancers that become repressed in both lineages. AHR and GLIS1 control differentiation-induced genes and we propose they function as guardians of mesenchymal multipotency.

Project description:Transcription factors (TFs) in concert with chromatin pathways stably reset transcriptional programs during differentiation. Yet we know little how local sites of chromatin reprogramming are specified and how the estimated 3000 TF encoded in mammalian genomes contribute to chromatin dynamics. To identify candidate TFs we developed an integrated computational approach (Epi-MARA) that models chromatin dynamics in terms of predicted transcription factor binding sites and show that it correctly predicts key TFs involved in epigenome reorganization. When applied to a time course of genome-wide H3 lysine 27 trimethylation (H3K27me3), a chromatin mark set by the Polycomb system, during neuronal differentiation of murine stem cells Epi-MARA predicted that the repressive transcription factor REST contributes to a gain of H3K27me3 at a subset of promoters during the transition from the stem to the progenitor state. To test this prediction we identified, genome-wide, the actual binding sites of REST and H3K27me3 during the differentiation in cells that are either wildtype or in which REST had been deleted. REST indeed localizes to a subset of sites that gain H3K27me3 in progenitors. Importantly, absence of REST in trans leads to a loss of H3K27me3 predominantly in the neuronal progenitor state and specifically at those regions where REST was bound. This function further requires REST binding sites in cis as their mutation leads to substantial loss of H3K27me3. Taken together we provide a novel approach to identify epigenome and TF crosstalk during cellular reprogramming and prove experimentally the prediction that REST acts as an important recruiter of Polycomb repression during early steps of neurogenesis. Dataset comprises of 15 ChIP-seq samples using chromatin from embryonic stem (ES) and neuronal progentor (NP) of wildtype and RESTko cells, which was immunoprecipitated, using antibodies against REST, H3K27me3, or Suz12

Project description:Diverse types of GABAergic projection neurons and interneurons of the telencephalon derive from progenitors in a ventral germinal zone, called the ganglionic eminence. Using single-cell transcriptomics, chromatin accessibility profiling, lineage tracing, birthdating, heterochronic transplantation, and perturbation sequencing in mouse embryos, we investigated how progenitor competence influences the maturation and differentiation of these neurons. We found that the progression of neurogenesis over developmental time shapes maturation competence in ganglionic eminence progenitors, influencing how they progress into mature states. In contrast, differentiation competence, which defines the ability to produce diverse transcriptomic identities, remains largely unaffected by the stages of neurogenesis. Chromatin remodeling alongside a NFIB-driven regulatory gene module influences maturation competence in late-born neurons. These findings provide key insights into how transcriptional programs and chromatin accessibility govern neuronal maturation and the diversification of GABAergic neuron subtypes during neurodevelopment.

Project description:Single cell RNA sequencing (scRNA-seq) is a widely used method for identifying cell types and trajectories in biologically heterogeneous samples, but is limited in its detection and quantification of lowly expressed genes. This results in missing important biological signals, such as the expression of key transcription factors (TFs) driving cellular differentiation. We show that targeted sequencing of ~1000 TFs (scCapture-seq) in iPSC-derived neuronal cultures greatly improves the biological information garnered from scRNA-seq. Increased TF resolution enhanced cell-type identification, developmental trajectories and gene regulatory networks. This allowed us to resolve differences amongst neuronal populations, which were generated in two different labs using the same differentiation protocol. ScCapture-seq improved TF gene-regulatory network inference and thus identified divergent patterns of neurogenesis into either excitatory cortical neurons or inhibitory interneurons. Furthermore, scCapture-seq revealed a role for of retinoic acid signalling in the developmental divergence between these different neuronal populations. Our results demonstrate that TF targeting improves the characterization of human cellular models and allows identification of the essential differences between cellular populations, which would otherwise be missed in traditional scRNA-seq. scCapture-seq TF targeting represents a cost-effective enhancement of scRNA-seq, which could be broadly applied to any cellular models to improve scRNA-seq resolution

Project description:Single cell RNA sequencing (scRNA-seq) is a widely used method for identifying cell types and trajectories in biologically heterogeneous samples, but is limited in its detection and quantification of lowly expressed genes. This results in missing important biological signals, such as the expression of key transcription factors (TFs) driving cellular differentiation. We show that targeted sequencing of ~1000 TFs (scCapture-seq) in iPSC-derived neuronal cultures greatly improves the biological information garnered from scRNA-seq. Increased TF resolution enhanced cell-type identification, developmental trajectories and gene regulatory networks. This allowed us to resolve differences amongst neuronal populations, which were generated in two different labs using the same differentiation protocol. ScCapture-seq improved TF gene-regulatory network inference and thus identified divergent patterns of neurogenesis into either excitatory cortical neurons or inhibitory interneurons. Furthermore, scCapture-seq revealed a role for of retinoic acid signalling in the developmental divergence between these different neuronal populations. Our results demonstrate that TF targeting improves the characterization of human cellular models and allows identification of the essential differences between cellular populations, which would otherwise be missed in traditional scRNA-seq. scCapture-seq TF targeting represents a cost-effective enhancement of scRNA-seq, which could be broadly applied to any cellular models to improve scRNA-seq resolution.

Project description:Single cell RNA sequencing (scRNA-seq) is a widely used method for identifying cell types and trajectories in biologically heterogeneous samples, but is limited in its detection and quantification of lowly expressed genes. This results in missing important biological signals, such as the expression of key transcription factors (TFs) driving cellular differentiation. We show that targeted sequencing of ~1000 TFs (scCapture-seq) in iPSC-derived neuronal cultures greatly improves the biological information garnered from scRNA-seq. Increased TF resolution enhanced cell-type identification, developmental trajectories and gene regulatory networks. This allowed us to resolve differences amongst neuronal populations, which were generated in two different labs using the same differentiation protocol. ScCapture-seq improved TF gene-regulatory network inference and thus identified divergent patterns of neurogenesis into either excitatory cortical neurons or inhibitory interneurons. Furthermore, scCapture-seq revealed a role for of retinoic acid signalling in the developmental divergence between these different neuronal populations. Our results demonstrate that TF targeting improves the characterization of human cellular models and allows identification of the essential differences between cellular populations, which would otherwise be missed in traditional scRNA-seq. scCapture-seq TF targeting represents a cost-effective enhancement of scRNA-seq, which could be broadly applied to any cellular models to improve scRNA-seq resolution