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

Project description:Precise control of gene expression during development is orchestrated by transcription factors and co-regulators including chromatin modifiers. How particular chromatin modifying enzymes affect specific developmental processes is not well defined. Here we report that Gcn5, a HAT essential for embryonic development, is largely required for c-MYC target gene transcription downstream of FGF signaling in early embryoid bodies (EBs). Gcn5 null EBs display deficient activation of ERK and p38, disorganized cytoskeletal networks, and compromised capacity to differentiate toward mesodermal and endodermal lineages. These findings establish a regulatory role for Gcn5 in execution of a critical signaling pathway during early development.

Project description:Precise control of gene expression during development is orchestrated by transcription factors and co-regulators including chromatin modifiers. How particular chromatin modifying enzymes affect specific developmental processes is not well defined. Here we report that Gcn5, a HAT essential for embryonic development, is largely required for c-MYC target gene transcription downstream of FGF signaling in early embryoid bodies (EBs). Gcn5 null EBs display deficient activation of ERK and p38, disorganized cytoskeletal networks, and compromised capacity to differentiate toward mesodermal and endodermal lineages. These findings establish a regulatory role for Gcn5 in execution of a critical signaling pathway during early development.

Project description:Gcn5 regulates FGF signaling outputs through c-Myc during early differentiation of embryoid bodies

Project description:Gcn5 regulates FGF signaling outputs through c-Myc during early differentiation of embryoid bodies [ChIP-Seq]

Project description:Gcn5 regulates FGF signaling outputs through c-Myc during early differentiation of embryoid bodies [RNA-Seq]

Project description:Embryonic stem (ES) cells differentiating as aggregates self-organize dependent on Wnt signaling that is initially localized to discrete sites in the aggregate. As differentiation proceeds, Wnt signaling expands to most of the aggregates, thus resulting in widespread differentiation of mesendodermal progenitors. This process resembles primitive streak formation, but the lack of organized positional information makes the differentiating aggregates develop in a disorganized fashion. Here, we report that exogenous, cellular signaling sources can control the site where differentiation initiates in ES cell aggregates. Fibroblasts engineered to express cadherins are assembled with ES cells to form composite aggregates where the fibroblasts are positioned as a discrete pole. When engineered to express secreted Wnt agonists or antagonists, this pole functions to localize signaling in a way that polarizes the differentiating aggregates. The use of cell adhesion molecules to control morphology of developing stem cell aggregates should be widely applicable in tissue engineering.

Project description:Embryonic stem (ES) cells, when grown in suspension culture without feeders, spontaneously form round structures known as embryoid bodies. Given the appropriate conditions, these cells can differentiate over time into precursors of all three germ layers. Embryoid bodies, in a disorganized way, mimic early embryonic development to a certain extent and can be used as a synchronously differentiating large scale source of tissue for the study of biological determinants of early differentiation. Embryoid bodies have been used as a source for most early protocols that derive specific differentiated cell types from undifferentiated ES cells, although some protocols, notably those that derive neurons from ES cells, have moved on from EBs as a result of varying replicability and yield. We have decided to look at the transcriptomic profiles of embryoid bodies during the initial stages of embryoid body formation and differentiation, in order to pinpoint novel determinants of key developmental stages. Keywords: time course

Project description:One approach to cell differentiation is to use the natural capacity of pluripotent stem cells to form three germ layers via embryoid bodies (EB). However, unification of this process during in vitro culture remains challenging and many microenvironmental factors including the number of cells in the culture can influence differentiation patterns. The number of cells serves a crucial role as it determines access to nutrients, the distribution of oxygen concentration and cellular interactions, all of which influence the fate of the differentiated cells. The influence of EBs derived from human pluripotent cells on the chondrogenic potential of such cells is not well understood. For this reason, the present study sought to determine the effect of varying amounts of cells on the properties of EBs derived from human embryonic stem cells (BG01V cell line). In the present study, 500?2,000 cells per well were cultivated from 5 to 15 days in suspension cell culture. Expression of pluripotency genes and germ layer markers were evaluated in order to determine the EBs with the greatest and least mesodermal properties. Genes associated with pluripotency and chondrogenesis were also evaluated to assess the influence of suspension culture duration and EB size on chondrogenic differentiation. Immunofluorescence staining for pluripotent and chondrocyte?associated proteins confirmed successful differentiation into chondrocyte?like cells. Alcian blue staining confirmed deposition of proteoglycans. These results suggested that EBs formed in 500?cell wells possess the highest mesodermal and prochondrogenic properties. Differentiation of EBs into chondrocytes on day 5 in 500?cell wells was more efficient than in that observed in larger and older EBs.

Project description:Various scalable three-dimensional culture systems for regenerative medicine using human induced pluripotent stem cells (hiPSCs) have been developed to date. However, stable production of hiPSCs with homogeneous qualities still remains a challenge. Here, we describe a novel and simple embryoid body (EB) formation system using unique microfabricated culture vessels. Furthermore, this culture system is useful for high throughput EB formation and rapid generation of differentiated cells such as neural stem cells (NSCs) from hiPSCs. The period of NSC differentiation was significantly shortened under high EB density culture conditions. Simultaneous mass production of a pure population of NSCs was possible within 4 days. These results indicate that the novel culture system might not only become a unique tool to obtain new insights into developmental biology based on human stem cells, but also provide an important tractable platform for efficient and stable production of NSCs for clinical applications.