Project description:Generation of autologous motor neurons holds a great promise for cell replacement therapy to treat spinal cord injury (SCI). Direct conversion allows the generation of target cell types from somatic cells, however, current protocols are not practicable for therapeutic purposes since converted cells are post-mitotic populations that are not readily scalable. Therefore, therapeutic effects of directly converted neurons have not been elucidated yet. Here, we show that human fibroblasts can be converted into induced motor neurons (iMNs) by sequential induction of OCT4 and LHX3. Our strategy enables large production of pure iMNs through self-renewing iMN-intermediate cell stage which is distinct from neural progenitors. iMNs exhibited the hallmarks of spinal motor neurons including cellular morphology, marker expression, electrophysiological property, synaptic activity, and formation of neuromuscular junctions. Remarkably, transplantation of iMNs showed therapeutic effects, promoting locomotor functional recovery in SCI model. Taken together, our advanced strategy will provide tools to acquire sufficient iMNs that may represent a promising cell source for personalized cell therapy.

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Project description:Promoting residential cells, particularly endogenous neural stem and progenitor cells (NSPCs), for tissue regeneration represents a potential strategy for the treatment of spinal cord injury (SCI). However, adult NSPCs differentiate mainly into glial cells and contribute to glial scar formation at the site of injury. Gsx1 is known to regulate the generation of excitatory and inhibitory interneurons during embryonic development of the spinal cord. Here we show that lentivirus-mediated expression of Gsx1 increases the number of NSPCs in a mouse model of lateral hemisection SCI during the acute stage. Subsequently, Gsx1 expression increases the generation of glutamatergic and cholinergic interneurons and decreases the generation of GABAergic interneurons in the chronic stage of SCI. Importantly, Gsx1 reduces reactive astrogliosis and glial scar formation, promotes 5-HT neuronal activity, and improves the locomotor function of the injured mice. Moreover, RNA-seq analysis reveals that Gsx1-induced transcriptome regulation correlates with NSPC signaling, NSPC activation, neuronal differentiation, and inhibition of astrogliosis and scar formation. Collectively, our study provides molecular insights for Gsx1-mediated functional recovery and identifies Gsx1 gene regulation as a potential application for injuries in the spinal cord and possibly other parts of the central nervous system.

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Project description:Generation of induced motor neurons (iMNs) from human fibroblasts facilitates locomotor recovery after spinal cord injury

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