Cell Reports (Feb 2020)

STAT Signaling Modifies Ascl1 Chromatin Binding and Limits Neural Regeneration from Muller Glia in Adult Mouse Retina

  • Nikolas L. Jorstad,
  • Matthew S. Wilken,
  • Levi Todd,
  • Connor Finkbeiner,
  • Paul Nakamura,
  • Nicholas Radulovich,
  • Marcus J. Hooper,
  • Alex Chitsazan,
  • Brent A. Wilkerson,
  • Fred Rieke,
  • Thomas A. Reh

Journal volume & issue
Vol. 30, no. 7
pp. 2195 – 2208.e5

Abstract

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Summary: Müller glia (MG) serve as sources for retinal regeneration in non-mammalian vertebrates. We find that this process can be induced in mouse MG, after injury, by transgenic expression of the proneural transcription factor Ascl1 and the HDAC inhibitor TSA. However, new neurons are generated only from a subset of MG. Identifying factors that limit Ascl1-mediated MG reprogramming could make this process more efficient. In this study, we test whether injury-induced STAT activation hampers the ability of Ascl1 to reprogram MG into retinal neurons. Single-cell RNA-seq shows that progenitor-like cells derived from Ascl1-expressing MG have a higher level of STAT signaling than do those cells that become neurons. Ascl1-ChIPseq and ATAC-seq show that STAT potentially directs Ascl1 to developmentally inappropriate targets. Using a STAT inhibitor, in combination with our previously described reprogramming paradigm, we found a large increase in the ability of MG to generate neurons. : Müller glia (MG) are sources for retinal regeneration in non-mammalian vertebrates. In mice, neural regeneration requires reprogramming MG with Ascl1, but only a subset of the glia become neurons. Jorstad et al. show that STAT pathway activation limits reprogramming; inhibition of this pathway leads to more efficient regeneration. Keywords: neurogenesis, reprogramming, glia, Id3, Ascl1, proneural, ChIP-seq