Marc Peschanski scite author profile

Specification of cell identity during development depends on exposure of cells to sequences of extrinsic cues delivered at precise times and concentrations. Identification of combinations of patterning molecules that control cell fate is essential for the effective use of human pluripotent stem cells (hPSCs) for basic and translational studies. Here we describe a scalable, automated approach to systematically test the combinatorial actions of small molecules for the targeted differentiation of hPSCs. Applied to the generation of neuronal subtypes, this analysis revealed an unappreciated role for canonical Wnt signaling in specifying motor neuron diversity from hPSCs and allowed us to define rapid (14 days), efficient procedures to generate spinal and cranial motor neurons as well as spinal interneurons and sensory neurons. Our systematic approach to improving hPSC-targeted differentiation should facilitate disease modeling studies and drug screening assays.

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Striatal progenitors derived from human ES cells mature into DARPP32 neuronsin vitroand in quinolinic acid-lesioned rats

Aubry¹,

Bugi²,

Lefort³

et al. 2008

Proc. Natl. Acad. Sci. U.S.A.

273

270

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Substitutive cell therapy using fetal striatal grafts has demonstrated preliminary clinical success in patients with Huntington's disease, but the logistics required for accessing fetal cells preclude its extension to the relevant population of patients. Human embryonic stem (hES) cells theoretically meet this challenge, because they can be expanded indefinitely and differentiated into any cell type. We have designed an in vitro protocol combining substrates, media, and cytokines to push hES cells along the neural lineage, up to postmitotic neurons expressing striatal markers. The therapeutic potential of such hES-derived cells was further substantiated by their in vivo differentiation into striatal neurons following xenotransplantation into adult rats. Our results open the way toward hES cell therapy for Huntington's disease. Long-term proliferation of human neural progenitors leads, however, to xenograft overgrowth in the rat brain, suggesting that the path to the clinic requires a way to switch them off after grafting.cell therapy ͉ Huntington's disease ͉ striatum ͉ cell differentiation ͉ overgrowth

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Motor and cognitive improvements in patients with Huntington's disease after neural transplantation

et al. 2000

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Transfer of a foreign gene into the brain using adenovirus vectors

et al. 1993

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The ability of a replication-deficient adenovirus vector to transfer a foreign gene into neural cells of adult rats in vivo has been analysed. A large number of neural cells (including neurons, astrocytes and ependymal cells) expressed an E. coli lacZ transgene for at least 45 days after inoculation of various brain areas. Injecting up to 3 x 10(5) pfu in 10 microliters did not result in any detectable cytopathic effects--these were only observed for very high titres of infection (> 10(7) pfu 10 microliters-1). Adenovirus vectors therefore appear to be a promising means for in vivo transfer of therapeutic genes into the central nervous system.

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Marc Peschanski

Combinatorial analysis of developmental cues efficiently converts human pluripotent stem cells into multiple neuronal subtypes

Striatal progenitors derived from human ES cells mature into DARPP32 neuronsin vitroand in quinolinic acid-lesioned rats

Motor and cognitive improvements in patients with Huntington's disease after neural transplantation

Transfer of a foreign gene into the brain using adenovirus vectors

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