Coordinated control of neuronal differentiation and wiring by a sustained code of transcription factors

The enormous diversity of cell types in nervous systems presents a challenge in identifying the genetic mechanisms that encode it. Here, we report that nearly 200 distinct neurons in the Drosophila visual system can each be defined by unique combinations of ∼10 transcription factors that are continuously expressed by them. We show that targeted modifications of this ‘selector’ code induce predictable conversions of cell fates between neurons in vivo . These conversions appear morphologically and transcriptionally complete, arguing for a conserved gene regulatory program that jointly instructs both the type-specific development and the terminal features of neurons. Cis-regulatory sequence analysis of open chromatin links one of these selectors to an upstream patterning gene in stem cells that specifies neuronal fates. Experimentally validated network models show that selectors interact with ecdysone signaling to regulate downstream effectors controlling brain wiring. Our results provide a generalizable framework of how specific fates are initiated and maintained in postmitotic neurons. ### Competing Interest Statement The authors have declared no competing interest.