Poor survival of human embryonic stem (hES) cells after cell dissociation is an obstacle to research, hindering manipulations such as subcloning. Here we show that application of a selective Rho-associated kinase (ROCK) inhibitor, Y-27632, to hES cells markedly diminishes dissociation-induced apoptosis, increases cloning efficiency (from approximately 1% to approximately 27%) and facilitates subcloning after gene transfer. Furthermore, dissociated hES cells treated with Y-27632 are protected from apoptosis even in serum-free suspension (SFEB) culture and form floating aggregates. We demonstrate that the protective ability of Y-27632 enables SFEB-cultured hES cells to survive and differentiate into Bf1(+) cortical and basal telencephalic progenitors, as do SFEB-cultured mouse ES cells.
In this report, we demonstrate that an optic cup structure can form by self-organization in human ESC culture. The human ESC-derived optic cup is much larger than the mouse ESC-derived one, presumably reflecting the species differences. The neural retina in human ESC culture is thick and spontaneously curves in an apically convex manner, which is not seen in mouse ESC culture. In addition, human ESC-derived neural retina grows into multilayered tissue containing both rods and cones, whereas cone differentiation is rare in mouse ESC culture. The accumulation of photoreceptors in human ESC culture can be greatly accelerated by Notch inhibition. In addition, we show that an optimized vitrification method enables en bloc cryopreservation of stratified neural retina of human origin. This storage method at an intermediate step during the time-consuming differentiation process provides a versatile solution for quality control in large-scale preparation of clinical-grade retinal tissues.
Self-Organized Formation of Polarized Cortical Tissues from ESCs and Its Active Manipulation by Extrinsic Signals
Here, we demonstrate self-organized formation of apico-basally polarized cortical tissues from ESCs using an efficient three-dimensional aggregation culture (SFEBq culture). The generated cortical neurons are functional, transplantable, and capable of forming proper long-range connections in vivo and in vitro. The regional identity of the generated pallial tissues can be selectively controlled (into olfactory bulb, rostral and caudal cortices, hem, and choroid plexus) by secreted patterning factors such as Fgf, Wnt, and BMP. In addition, the in vivo-mimicking birth order of distinct cortical neurons permits the selective generation of particular layer-specific neurons by timed induction of cell-cycle exit. Importantly, cortical tissues generated from mouse and human ESCs form a self-organized structure that includes four distinct zones (ventricular, early and late cortical-plate, and Cajal-Retzius cell zones) along the apico-basal direction. Thus, spatial and temporal aspects of early corticogenesis are recapitulated and can be manipulated in this ESC culture.
During cerebellar development, the main portion of the cerebellar plate neuroepithelium gives birth to Purkinje cells and interneurons, whereas the rhombic lip, the germinal zone at its dorsal edge, generates granule cells and cerebellar nuclei neurons. However, it remains elusive how these components cooperate to form the intricate cerebellar structure. Here, we found that a polarized cerebellar structure self-organizes in 3D human embryonic stem cell (ESC) culture. The self-organized neuroepithelium differentiates into electrophysiologically functional Purkinje cells. The addition of fibroblast growth factor 19 (FGF19) promotes spontaneous generation of dorsoventrally polarized neural-tube-like structures at the level of the cerebellum. Furthermore, addition of SDF1 and FGF19 promotes the generation of a continuous cerebellar plate neuroepithelium with rhombic-lip-like structure at one end and a three-layer cytoarchitecture similar to the embryonic cerebellum. Thus, human-ESC-derived cerebellar progenitors exhibit substantial self-organizing potential for generating a polarized structure reminiscent of the early human cerebellum at the first trimester.
Human embryonic stem cells (hESCs), unlike mouse ones (mESCs), are vulnerable to apoptosis upon dissociation. Here, we show that the apoptosis, which is of a nonanoikis type, is caused by ROCK-dependent hyperactivation of actomyosin and efficiently suppressed by the myosin inhibitor Blebbistatin. The actomyosin hyperactivation is triggered by the loss of E-cadherin-dependent intercellular contact and also observed in dissociated mouse epiblast-derived pluripotent cells but not in mESCs. We reveal that Abr, a unique Rho-GEF family factor containing a functional Rac-GAP domain, is an indispensable upstream regulator of the apoptosis and ROCK/myosin hyperactivation. Rho activation coupled with Rac inhibition is induced in hESCs upon dissociation, but not in Abr-depleted hESCs or mESCs. Furthermore, artificial Rho or ROCK activation with Rac inhibition restores the vulnerability of Abr-depleted hESCs to dissociation-induced apoptosis. Thus, the Abr-dependent "Rho-high/Rac-low" state plays a decisive role in initiating the dissociation-induced actomyosin hyperactivation and apoptosis in hESCs.
The adenohypophysis (anterior pituitary) is a major centre for systemic hormones. At present, no efficient stem-cell culture for its generation is available, partly because of insufficient knowledge about how the pituitary primordium (Rathke's pouch) is induced in the embryonic head ectoderm. Here we report efficient self-formation of three-dimensional adenohypophysis tissues in an aggregate culture of mouse embryonic stem (ES) cells. ES cells were stimulated to differentiate into non-neural head ectoderm and hypothalamic neuroectoderm in adjacent layers within the aggregate, and treated with hedgehog signalling. Self-organization of Rathke's-pouch-like three-dimensional structures occurred at the interface of these two epithelia, as seen in vivo, and various endocrine cells including corticotrophs and somatotrophs were subsequently produced. The corticotrophs efficiently secreted adrenocorticotropic hormone in response to corticotrophin releasing hormone and, when grafted in vivo, these cells rescued the systemic glucocorticoid level in hypopituitary mice. Thus, functional anterior pituitary tissue self-forms in ES cell culture, recapitulating local tissue interactions.
Minimization of exogenous signals in ES cell culture induces rostral hypothalamic differentiation
Embryonic stem (ES) cells differentiate into neuroectodermal progenitors when cultured as floating aggregates in serum-free conditions. Here, we show that strict removal of exogenous patterning factors during early differentiation steps induces efficient generation of rostral hypothalamic-like progenitors (Rax ؉ /Six3 ؉ /Vax1 ؉ ) in mouse ES cell-derived neuroectodermal cells. The use of growth factor-free chemically defined medium is critical and even the presence of exogenous insulin, which is commonly used in cell culture, strongly inhibits the differentiation via the Akt-dependent pathway. The ES cell-derived Rax ؉ progenitors generate Otp ؉ /Brn2 ؉ neuronal precursors (characteristic of rostral-dorsal hypothalamic neurons) and subsequently magnocellular vasopressinergic neurons that efficiently release the hormone upon stimulation. Differentiation markers of rostral-ventral hypothalamic precursors and neurons are induced from ES cell-derived Rax ؉ progenitors by treatment with Shh. Thus, in the absence of exogenous growth factors in medium, the ES cell-derived neuroectodermal cells spontaneously differentiate into rostral (particularly rostral-dorsal) hypothalamic-like progenitors, which generate characteristic hypothalamic neuroendocrine neurons in a stepwise fashion, as observed in vivo. These findings indicate that, instead of the addition of inductive signals, minimization of exogenous patterning signaling plays a key role in rostral hypothalamic specification of neural progenitors derived from pluripotent cells.chemically defined ͉ hypothalamus ͉ patterning ͉ vasopressin D ifferentiation culture of mouse ES (mES) cells is a versatile in vitro tool for understanding molecular and cellular controls in early mammalian neurogenesis (1-5). We previously established a mES cell culture system with reduced exogenous signals, namely, serum-free culture of embryoid body-like aggregates (SFEB culture) (4). In this method, ES cells are dissociated (to minimize possible effects of culture substrate matrix), reaggregated (over one day), and cultured as floating aggregates in serum-free medium containing knockout serum replacement (KSR) (6), but with no major exogenous inductive factors, such as Fgf, BMP, Wnt, or Nodal. SFEB-cultured mES cells spontaneously differentiate into neural progenitors that acquire a rostral forebrain fate and efficiently generate telencephalic progenitors positive for Bf1 (FoxG1; (7); see Fig. 1A). Efficient forebrain differentiation is also seen in SFEB-cultured human ES cells (8).In contrast to telencephalic development, relatively little has been known about regulatory signals for early diencephalic development, including the initial specification of the mammalian hypothalamic anlage (9, 10). In the present study, using a similar SFEB culture approach, we wished to steer ES cell differentiation into hypothalamic tissues, which arises from the rostral forebrain region adjacent to the embryonic telencephalon in vivo. However, we noticed at the beginning of this study that hypothalamic mark...
Recent reports on ES cell differentiation have suggested the possibility that information on in vivo neurogenesis might be systematically linked to stem cell technology (3, 4). However, it remains to be known whether ES cell-derived neural precursors generated in vitro can produce the full dorsal-ventral range of neuroectodermal derivatives in response to embryonic positional information. To address this question, we have tested in this study whether SDIA-treated ES cells have the competence of differentiating into the dorsal-(neural crest) and ventralmost (floor plate) cells under embryologically relevant conditions. Materials and MethodsCell Culture and Treatment with Patterning Factors. Mouse ES cells (EB5), primate ES cells (cynomolgus monkey-derived; purchased from Asahi Technoglass, Funabashi, Japan), and PA6 cells were maintained and used for induction as described (1, 2, 5). Human bone morphogenetic protein (BMP)4 and mouse were purchased from R&D Systems and freshly added at each medium change. The day on which ES cells are seeded on PA6 is defined as day 0.Immunocytochemistry, Statistics, and RT-PCR. Cells were fixed with 4% paraformaldehyde, and immunostaining was performed with secondary antibodies conjugated with FITC, cy3, or cy5. For statistics, Ϸ100 colonies were observed in each experiment, and three or more experiments were performed. P values for statistical significance (t test) are described in the corresponding figure legends. The values shown in graphs represent the mean Ϯ SD. RT-PCR was performed with ES cell colonies detached from feeder cells as described (1). The primary antibodies and primers used are described in Supporting Materials and Methods, which are published as supporting information on the PNAS web site, www.pnas.org.Colony Isolation and Axon Guidance Assays. The 3D collagen gel assay for axon guidance was performed by using isolated ES cell colonies (day 8; ref. 1) and the cerebellar plate region excised from embryonic day 13 Wistar rats as a responder (6). Results Positional Identity of Neural Tissues Induced from ES Cells by SDIA.We first examined the expression of rostral-caudal CNS markers by RT-PCR (Fig. 1A). SDIA-treated mouse ES cells express the forebrain markers Otx2 and Six3, the ventral diencephalon marker Rx, the ventral forebrain marker Nkx2.1, the midbrainhindbrain border marker En2, and the hindbrain marker Gbx2, but not the spinal cord markers Hoxb4 and b9 (lane 2). These results show that a majority of neural cells induced by SDIA express rostral neural markers. This idea is consistent with our previous report that dopaminergic neurons generated by the SDIA method are those of the midbrain type (1).We next attempted to alter the rostral-caudal identity of SDIA-induced neural cells by the caudalizing factor retinoic acid (RA; ref. 7). RA treatment (0.2 M all-trans RA; Fig. 1 A, lane 3) suppressed the forebrain markers Otx2, Six3, Rx, and Nkx2.1, whereas it induced the hindbrain marker Gbx2 and the spinal cord markers Hoxb4 and b9. RA treatment did not sign...
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