Project Summary Humans regenerate tissue of the brain and spinal cord poorly. Failure to regenerate missing or damaged cells impedes survival and recovery after neurodegenerative disease, stroke, traumatic or ischemic injury, or developmental error. Unlike humans, other animals can effectively repair dramatic injuries or damage within the central nervous system. Free-living freshwater flatworms called planarians possess extraordinary regenerative abilities, including flawless regeneration and replacement of all brain and nerve cord tissues. After tissue loss or damage, planarians remodel existing tissue and use adult pluripotent stem cells to replace diverse cell types, including dozens of types of neurons. Planarians create neurons in appropriate ratios and then repattern and reconnect neurons to targets to restore function. The long-term goal is to discover the molecular and cellular basis of robust neural regeneration using planarians. Toward that objective, the first specific aim is to identify and characterize factors important for regenerative neurogenesis from pluripotent stem cells, focusing first on regeneration of dopaminergic neurons. Four transcription factor-encoding genes important for regeneration and maintenance of dopaminergic neuron subtypes have already been discovered. The following specific aims will provide critical information about how environmental cues promote brain regeneration by pluripotent stem cells in vivo. The second specific aim is to test the hypothesis that neurogenesis is upregulated in planarians after injury, through wound-induced signaling mechanisms. The third specific aim is to test the hypothesis that planarian neurogenesis is driven by polarity cues so that new neurons of the correct types are created in the proper locations. The proposed work in this application is conceptually innovative because of the use of a highly regenerative model organism to explore regenerative neurogenesis and because of the development of new molecular and behavioral assays (e.g. DAP-Seq, live prey assays). The proposed research is significant because it will provide a foundational understanding of successful neural regeneration in response to injury, with a long-term goal of identifying pathways or molecular mechanisms that could be leveraged to improve human regenerative therapies.