Author:
Bergmann Tobias,Liu Yong,Skov Jonathan,Mogus Leo,Lee Julie,Pfisterer Ulrich,Handfield Louis-Francois,Asenjo-Martinez Andrea,Lisa-Vargas Irene,Seemann Stefan E.,Lee Jimmy Tsz Hang,Patikas Nikolaos,Kornum Birgitte Rahbek,Denham Mark,Hyttel Poul,Witter Menno P.,Gorodkin Jan,Pers Tune H.,Hemberg Martin,Khodosevich Konstantin,Hall Vanessa Jane
Abstract
Stellate cells are principal neurons in the entorhinal cortex that contribute to spatial processing. They also play a role in the context of Alzheimer’s disease as they accumulate Amyloid beta early in the disease. Producing human stellate cells from pluripotent stem cells would allow researchers to study early mechanisms of Alzheimer’s disease, however, no protocols currently exist for producing such cells. In order to develop novel stem cell protocols, we characterize at high resolution the development of the porcine medial entorhinal cortex by tracing neuronal and glial subtypes from mid-gestation to the adult brain to identify the transcriptomic profile of progenitor and adult stellate cells. Importantly, we could confirm the robustness of our data by extracting developmental factors from the identified intermediate stellate cell cluster and implemented these factors to generate putative intermediate stellate cells from human induced pluripotent stem cells. Six transcription factors identified from the stellate cell cluster including RUNX1T1, SOX5, FOXP1, MEF2C, TCF4, EYA2 were overexpressed using a forward programming approach to produce neurons expressing a unique combination of RELN, SATB2, LEF1 and BCL11B observed in stellate cells. Further analyses of the individual transcription factors led to the discovery that FOXP1 is critical in the reprogramming process and omission of RUNX1T1 and EYA2 enhances neuron conversion. Our findings contribute not only to the profiling of cell types within the developing and adult brain’s medial entorhinal cortex but also provides proof-of-concept for using scRNAseq data to produce entorhinal intermediate stellate cells from human pluripotent stem cells in-vitro.
Funder
Novo Nordisk Fonden
Lundbeckfonden
Innovationsfonden
Danmarks Frie Forskningsfond
Wellcome Trust
Chan Zuckerberg Initiative
Subject
Cell Biology,Developmental Biology
Cited by
2 articles.
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