Abstract

Neocortical development involves ordered specification of forebrain cortical progenitors to various neuronal subtypes, ultimately forming the layered cortical structure. Modeling of this process using human pluripotent stem cells (hPSCs) would enable mechanistic studies of human neocortical development, while providing new avenues for exploration of developmental neocortical abnormalities. Here, we show that preserving hPSCs aggregates – allowing embryoid body formation – while adding basic fibroblast growth factor (bFGF) during neuroepithelial development generates neural rosettes showing dorsal forebrain identity, including Mash1+ dorsal telencephalic GABAergic progenitors. Structures that mirrored the organization of the cerebral cortex formed after rosettes were seeded and cultured for 3 weeks in the presence of FGF18, BDNF and NT3. Neurons migrated along radial glia scaffolding, with deep-layer CTIP2+ cortical neurons appearing after 1 week and upper-layer SATB2+ cortical neurons forming during the second and third weeks. At the end of differentiation, these structures contained both glutamatergic and GABAergic neurons, with glutamatergic neurons being most abundant. Thus, this differentiation protocol generated an hPSC-based model that exhibits temporal patterning and a neuronal subtype ratio similar to that of the developing human neocortex. This model was used to examine the effects of cocaine during neocorticogenesis. Cocaine caused premature neuronal differentiation and enhanced neurogenesis of various cortical neuronal subtypes. These cocaine-induced changes were inhibited by the cytochrome P450 inhibitor cimetidine. This in vitro model enables mechanistic studies of neocorticogenesis, and can be used to examine the mechanisms through which cocaine alters the development of the human neocortex.

Highlights

  • The cerebral cortex represents the most complex, and uniquely human, organ structure

  • The majority of our knowledge of the cerebral cortex has been gained through the use of animal models but, the neocortex is organized in all mammals, the complexity of human cerebral cortical development greatly exceeds that of any animal (Rakic, 2009; Hill and Walsh, 2005)

  • This study describes a model of human neocortical development, based on the use of human pluripotent stem cell aggregates without cell dissociation, and inclusion of key trophic factors

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Summary

Introduction

The cerebral cortex represents the most complex, and uniquely human, organ structure. The majority of our knowledge of the cerebral cortex has been gained through the use of animal models but, the neocortex is organized in all mammals, the complexity of human cerebral cortical development greatly exceeds that of any animal (Rakic, 2009; Hill and Walsh, 2005). One of the major areas of biomedical science for which the knowledge gained from animal models is still limited is the study of the normal and diseased cerebral cortex. This is because, similarities are shared among mammals, the complexity of the human cerebral cortex greatly exceeds that of any other animal. A reproducible in vitro model of human neocortical development could facilitate the development of new drugs for reversing or preventing disorders of the cerebral cortex

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