Modeling of early neural development in vitro by direct neurosphere formation culture of chimpanzee induced pluripotent stem cells.

Evolutionary developmental biology of our closest living relative, the chimpanzee (Pan troglodytes), is essential for understanding the origin of human traits. However, it is difficult to access developmental events in the chimpanzee in vivo because of technical and ethical restrictions. Induced pluripotent stem cells (iPSCs) offer an alternative in vitro model system to investigate developmental events by overcoming the limitations of in vivo study. Here, we generated chimpanzee iPSCs from adult skin fibroblasts and reconstructed early neural development using in vitro differentiation culture conditions. Chimpanzee iPSCs were established using straightforward methods, namely, lipofection of plasmid vectors carrying human reprogramming factors, combined with maintenance in a comprehensive feeder-free culture. Ultimately, direct neurosphere formation culture induced rapid and efficient differentiation of neural stem cells from chimpanzee iPSCs. Time course analysis of neurosphere formation demonstrated ontogenetic changes in gene expression profiles and developmental potency along an early neural development path from epiblasts to radial glia. Our iPSC culture system is a potent tool for investigating the molecular and cellular foundation underlying chimpanzee early neural development and better understanding of human brain evolution.

Reprogramming of chimpanzee fibroblasts into a multipotent cancerous but not fully pluripotent state by transducing iPSC factors in 2i/LIF culture.

To induce and maintain naïve pluripotency in mouse embryonic and induced pluripotent stem cells (ESCs/iPSCs), chemically defined N2B27 medium with PD0325901, CHIR99021, and leukemia inhibitory factor (2i/LIF) is a classic and simple condition. However, this method cannot be simply extrapolated to human ESCs/iPSCs that are principally stabilized in primed pluripotency and become primitive neuroepithelium-like cells in N2B27+2i/LIF culture. Here, we assessed iPSC reprogramming of fibroblasts from chimpanzee, our closest living relative, in N2B27+2i/LIF culture. Under this condition, chimpanzee cells formed alkaline phosphatase-positive dome-shaped colonies. The colony-forming cells could be stably expanded by serial passaging without a ROCK inhibitor. However, their gene expression was distinct from iPSCs and neuroepithelium. They expressed the OCT3/4 transgene and a subset of transcripts associated with pluripotency, mesenchymal-epithelial transition, and neural crest formation. These cells exhibited a differentiation potential into the three germ layers in vivo and in vitro. The current study demonstrated that iPSC reprogramming in N2B27+2i/LIF culture converted chimpanzee fibroblasts into a multipotent cancerous state with unique gene expression, but not fully pluripotent stem cells.