Insm1a-mediated gene repression is essential for the formation and differentiation of Müller glia-derived progenitors in the injured retina

In zebrafish, retinal injury stimulates Müller glia (MG) reprograming, allowing them to generate multipotent progenitors that replace damaged cells and restore vision. Recent studies suggest that transcriptional repression may underlie these events. To identify transcriptional repressors, we compared the transcriptomes of MG and MG-derived progenitors and identified insm1a, a repressor exhibiting a biphasic pattern of expression that is essential for retina regeneration. Insm1a was found to suppress ascl1a and its own expression, and link injury-dependent ascl1a induction with the suppression of the Wnt inhibitor dickkopf (dkk), which is necessary for MG dedifferentiation. We also found that Insm1a was responsible for sculpting the zone of injury-responsive MG by suppressing h b-e g fa expression. Finally, we provide evidence that Insm1a stimulates progenitor cell-cycle exit by suppressing a genetic program driving progenitor proliferation. Our studies identify Insm1a as a key regulator of retina regeneration and provide a mechanistic understanding of how it contributes to multiple phases of this process. Goldman and colleagues report that the transcriptional repressor Insm1a is essential for retinal regeneration following injury in fish. Insm1a suppresses the expression of Ascl1a to promote Müller glial cells’ dedifferentiation at early stages of regeneration, and defines the regeneration zone by negatively regulating the expression of the heparin-binding EGF. It also halts the proliferation of retinal progenitors in the late stages of the process.