| Autor: |
Sisi Chen, Jong H. Park, Jialong Jiang, Tiffany Tsou, Paul Rivaud, Matt Thomson |
| Rok vydání: |
2019 |
| Předmět: |
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| DOI: |
10.1101/2019.12.30.890087 |
| Popis: |
Stem and progenitor populations within developing embryos are diverse, composed of different subpopulations of precursor cells with varying developmental potential. How these different subpopulations are coordinately regulated by their signaling environments is not well understood. In this paper we develop a framework for controlling progenitor population structure in cell culture using high-throughput single cell mRNA-seq and computational analysis. We find that the natural transcriptional diversity of neural stem cell populations from the developing mouse brain collapses during in vitro culture. Cell populations are depleted of committed neuroblast progenitors and become dominated by a single pre-astrocytic cell population. By analyzing the response of neural stem cell populations to forty combinatorial signaling conditions, we demonstrate that signaling environments can restructure cell populations by modulating the relative abundance of pre-astrocytic and pre-neuronal subpopulations according to a simple log-linear model. Our work demonstrates that single-cell RNA-seq can be applied to learn how to modulate the diversity of stem cell populations, providing a new strategy for population-level stem cell control.HighlightsNatural progenitor diversity in the brain collapses during in vitro culture to a single progenitor typeLoss of progenitor diversity alters fate potential of cells during differentiationLarge scale single-cell signaling screen identifies signals that reshape population structure towards neuronal cell typesSignals regulate population structure according to a simple log-linear modelGRAPHICAL ABSTRACT |
| Databáze: |
OpenAIRE |
| Externí odkaz: |
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