Genome wide chromatin accessibility analysis reveals a role for CREB in retinal ganglion cells axon growth decline in development and regeneration after optic nerve injury [ATAC-seq]

CNS neurons lose their ability to grow and regenerate axons during development. This is the case for Retinal Ganglion Cells (RGCs) in the retina, which transmit visual information to the brain via axons projecting into the optic nerve. RGCs are unable to regenerate their axon after injury, and start a degeneration process that leads to cell death and loss of vision. To identifying molecular mechanisms that increase regeneration of RGC and may offer new treatment strategies for patients with glaucoma or other types of optic neuropathies, we focused on the identification of transcription factors and chromatin accessible sites that are enriched in RGC during developmental stages, in which axon growth capacity is robust. We find that stage-specific gene expression changes are correlated with temporal changes in promoter chromatin accessibility. We also find that Creb binding motifs are enriched in the differentially opened regions of the chromatin at embryonic developmental stage. Overexpression of active Creb promotes axon regeneration after optic nerve injury. Our results provide a map of the chromatin accessibility during RGC development and highlights that manipulating TF associated with developmental stages can stimulate axon growth in adulthood. For embryonic E21 day and postnatal P11 Retinal Ganglion Cell were isolated by immunopanning. After isolation, 300,000 RGCs were centrifugued and resuspended in Neurobasal/B27+ medium and 10% DMSO, to quick frozen at -80 °C. Samples were processed by UCSD Center of Epigenomic Technologies using their proprietary assay for Transposase-Accessible Chromatin coupled with high-throughput sequencing (ATAC-seq).