Single-cell RNA sequencing of neonatal cortical astrocytes reveals versatile cell clusters during astrocyte-neuron conversion.

Abstract

Background: Astrocytes are extensively utilized as starting cells for neuronal conversion. Our previous study discovered that a portion of primary cultured mouse neonatal cortical astrocytes can be directly converted into neurons after exposure to a neurogenic induction condition. Recent in vivo studies have demonstrated astrocyte heterogeneity in terms of their developmental origin, molecular profile, physiology, and functional outputs. We hypothesized that the heterogeneity of primary astrocytes in our study could influence their conversion potential.

Methods and results: We performed single-cell RNA sequencing on cells harvested at key time points during in vitro astrocyte-to-neuron conversion, specifically on Day 1 and Day 9. Through single-cell RNA sequencing analysis, we identified several subpopulations of astrocytes, labeled as Astrocyte 1 to Astrocyte 3, based on distinct gene expression patterns. Pseudotime trajectory analysis predicted the existence of three distinct cell states throughout the conversion process. Astrocyte 3 exhibited a higher propensity for neuronal conversion, with proliferation genes like Mki67 being highly expressed. Additionally, several candidate genes were identified as potentially crucial in the conversion process. Astrocyte 3 is considered a unique subtype population of astrocytes.

Conclusions: Our investigation underscores the diversity of primary neonatal cortical astrocytes and provides critical insights into the potential for astrocyte-to-neuron conversion, which may be harnessed to enhance the efficiency of this astrocyte-neuron conversion process.