Abstract
Injury induces retinal Müller glia of cold-blooded, but not mammalian, vertebrates to regenerate neurons. To identify gene regulatory networks that control neuronal reprogramming in retinal glia, we comprehensively profiled injury-dependent changes in gene expression and chromatin accessibility in Müller glia from zebrafish, chick and mice using bulk RNA-Seq and ATAC-Seq, as well as single-cell RNA-Seq. Cross-species integrative analysis of these data, together with functional validation, identified evolutionarily conserved and species-specific gene networks controlling glial quiescence, gliosis and neurogenesis. In zebrafish and chick, transition from the resting state to gliosis is essential for initiation of retinal regeneration, while in mice a dedicated network suppresses neurogenic competence and restores quiescence. Selective disruption of NFI family transcription factors, which maintain and restore quiescence, enables Müller glia to proliferate and generate neurons in adult mice following retinal injury. These findings may aid in the design of cell-based therapies aimed at restoring retinal neurons lost to degenerative disease.
Summary sentence This study identifies gene regulatory networks controlling proliferative and neurogenic competence in retinal Müller glia.
Footnotes
RNA velocity data demonstrating that Muller glia transition through a gliotic state prior to full reprogramming. Loss of function data demonstrating that zebrafish transcription factors that are active during gliosis are necessary for full reprogramming. ScRNA-Seq and morphology data demonstrating that Nfia/b/x-deficient mouse Muller glia directly give rise to bipolar and amacrine neurons.
https://github.com/jiewwwang/Single-cell-retinal-regeneration.