Project description:Decoding heterogeneity of pluripotent stem cell (PSC)-derived neural progeny is fundamental for revealing the origin of diverse progenitors, for defining their lineages, and for identifying fate determinants driving transition through distinct potencies. Here we prospectively isolated consecutively appearing PSC-derived primary progenitors based on their Notch activation state. We first isolate early neuroepithelial cells and show their broad Notch-dependent developmental and proliferative potential. Neuroepithelial cells further yield successive Notch-dependent functional primary progenitors, from early and mid neurogenic radial glia and their derived basal progenitors, to gliogenic radial glia and adult-like neural progenitors, together recapitulating hallmarks of neural stem cell (NSC) ontogeny. Gene expression profiling reveals dynamic stage specific transcriptional patterns that may link development of distinct progenitor identities through Notch activation. Our observations provide a platform for characterization and manipulation of distinct progenitor cell types amenable for developing streamlined neural lineage specification paradigms for modeling development in health and disease. Human embryonic stem cells (hESCs) H9 were differentiated into 5 distinct populations of neural precursor cells (NPCs) over a time course of 200 days. Each neural precursor populations was then sorted for HES5 expression based on a GFP-HES5 reporter. Both the HES5 positive and HES5 negative populations were then subjected to microarray profiling in singlicate, as well as the hESCs using GeneChipPrimeView Human Gene Expression Array
Project description:Decoding heterogeneity of pluripotent stem cell (PSC)-derived neural progeny is fundamental for revealing the origin of diverse progenitors, for defining their lineages, and for identifying fate determinants driving transition through distinct potencies. Here we prospectively isolated consecutively appearing PSC-derived primary progenitors based on their Notch activation state. We first isolate early neuroepithelial cells and show their broad Notch-dependent developmental and proliferative potential. Neuroepithelial cells further yield successive Notch-dependent functional primary progenitors, from early and mid neurogenic radial glia and their derived basal progenitors, to gliogenic radial glia and adult-like neural progenitors, together recapitulating hallmarks of neural stem cell (NSC) ontogeny. Gene expression profiling reveals dynamic stage specific transcriptional patterns that may link development of distinct progenitor identities through Notch activation. Our observations provide a platform for characterization and manipulation of distinct progenitor cell types amenable for developing streamlined neural lineage specification paradigms for modeling development in health and disease.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.
Project description:We report that Hedgehog signaling is a heterochronic pathway that determines the timing of the transition from specified cardiac progenitor to differentiated cardiomyocyte, a function distinct from its previously described roles affecting cellular patterning or proliferation. Hedgehog signaling was required to prevent premature differentiation and disruption of cardiac morphogenesis in vivo and the Hedgehog signaling transcription factor GLI1 was sufficient to delay differentiation in stem cell-derived cardiac progenitors in vitro. GLI1 directly activated a de novo progenitor-specific network in vitro that inhibited the induction of the cardiac differentiation program. The GLI1-driven gene regulatory network is sufficient to induce Hedgehog-naive in vitro cardiac progenitors to adopt an epigenomic state reminiscent of second heart field cardiac progenitors in vivo. A Hh-dependent GLI transcription factor switch functions as a differentiation timer, restricting activity of the progenitor network to the second heart field and permitting cardiomyocyte differentiation in the heart. GLI1 expression is broadly associated with the progenitor state, and its activity also delayed the differentiation of specified neural progenitors in vitro. We posit that Hedgehog signaling functions as a heterochronic regulator that transiently maintains diverse progenitor populations for complex organ development and that may explain diverse Hedgehog signaling-dependent phenomena.