Sasai and colleagues pioneered an aggregate culture method, termed SFEBq (serum-free, floating embryoid body-like, quick aggregation), in which dissociated mouse embryonic stem cells (mESCs) were placed in nonadherent, round-bottom wells to undergo spontaneous neural differentiation (Eiraku et al., 2008). The cells aggregated into a spheroid and within 5 days
remarkably self-organized into a polarized neuroepithelium, with their apical ends facing an inner lumen, and a basal deposition of laminin around the outside. For promotion of rostral neuralization, the cells were treated with inhibitors of Wnt and Nodal signaling during the initial period of neural specification. Further culture (without Wnt inhibitor) allowed the cells to naturally adopt a dorsal telencephalic (pallial) fate, with the majority of cells expressing the telencephalic marker Foxg1/BF-1 and Epigenetics Compound Library supplier nearly all of those expressing the cortical selleck inhibitor marker Emx1 (Eiraku et al., 2008). The self-assembled neuroepithelia collapsed within days into smaller rosette structures, but the rosettes maintained some features of developing cortex, with apically polarized Pax6+ progenitor cells in the rosettes’ centers producing neuron subtypes in the same sequence that occurs in the embryonic cortex (Molyneaux et al., 2007). Production of layer I neurons (Reelin+) occurred first, subcortical
projection neurons (Tbr1+, Ctip2+) second, and callosal projection neurons (Brn2+, Satb2+, Cux1+) third (Eiraku et al., 2008). However, these neurons were disorganized and did not assume the “inside-out” laminar organization, achieved by embryonic cortex, that inversely corresponds to cellular birthdate (Angevine and Sidman, 1961, Rakic, 1974 and Takahashi
et al., 1999). The SFEBq rosettes apparently lack through the elements required for radial migration and column formation. When SFEBq-derived, GFP-labeled neurons were grafted en bloc into postnatal frontal mouse cortex, axonal projections were observed in the corpus callosum, striatum, thalamus, pyramidal tract, and pontine nuclear regions after 4 weeks, confirming that SFEBq cultures produced a broad spectrum of cortical neuron subtypes ( Eiraku et al., 2008). Going beyond simple cortical specification, Sasai’s group investigated methods for subregionalizing the SFEBq cultures with additional morphogen treatments—the only example so far of directed intra-pallial patterning in ESCs. Various manipulations of FGF, Wnt, and BMP pathway activity altered the cells’ pallial fates along rostral-caudal or medial-lateral axes, inducing regionally specific markers of rostral cortex, caudal cortex, olfactory bulb, cortical hem, or choroid plexus (Eiraku et al., 2008). Importantly, Sasai’s group has adapted the SFEBq method of excitatory neuron production for use with human ESCs (hESCs), including among other modifications a longer incubation period that reflects the protracted sequence of human development compared to the mouse (Eiraku et al.