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ABSTRACT Background The neural crest‐derived enteric nervous system (ENS) provides the intrinsic innervation of the gut with diverse neuronal subtypes and glial cells. The ENS regulates all essential gut functions, such as motility, nutrient uptake, immune response, and microbiota colonization. Deficits in ENS neuron numbers and composition cause debilitating gut dysfunction. Yet, few studies have identified genes that control neuronal differentiation and the generation of the diverse neuronal subtypes in the ENS. Methods Utilizing existing CRISPR/Cas9 genome editing technology in zebrafish, we have developed a rapid and scalable screening approach for identifying genes that regulate ENS neurogenesis. Key Results As a proof‐of‐concept, F0 guide RNA‐injected larvae (F0 crispants) targeting the known ENS regulator genes sox10 , ret , or phox2bb phenocopied known ENS phenotypes with high efficiency. We evaluated 10 transcription factor candidate genes as regulators of ENS neurogenesis and function. F0 crispants for five of the tested genes have fewer ENS neurons. Secondary assays in F0 crispants for a subset of the genes that had fewer neurons reveal no effect on enteric progenitor cell migration but differential changes in gut motility. Conclusions Our multistep, yet straightforward CRISPR screening approach in zebrafish tests the genetic basis of ENS developmental and disease gene functions that will facilitate the high‐throughput evaluation of candidate genes from transcriptomic, genome‐wide association, or other ENS‐omics studies. Such in vivo ENS F0 crispant screens will contribute to a better understanding of ENS neuronal development regulation in vertebrates and what goes awry in ENS disorders. 

The receptor tyrosine kinase Ret plays a critical role in regulating enteric nervous system (ENS) development. Ret is important for proliferation, migration, and survival of enteric progenitor cells (EPCs). Ret also promotes neuronal fate, but its role during neuronal differentiation and in the adult ENS is less well understood. Inactivating RET mutations are associated with ENS diseases, e.g., Hirschsprung Disease, in which distal bowel lacks ENS cells. Zebrafish is an established model system for studying ENS development and modeling human ENS diseases. One advantage of the zebrafish model system is that their embryos are transparent, allowing visualization of developmental phenotypes in live animals. However, we lack tools to monitor Ret expression in live zebrafish. Here, we developed a new BAC transgenic line that expresses GFP under the ret promoter. We find that EPCs and the majority of ENS neurons express ret:GFP during ENS development. In the adult ENS, GFP+ neurons are equally present in females and males. In homozygous mutants of ret and sox10—another important ENS developmental regulator gene—GFP+ ENS cells are absent. In summary, we characterize a ret:GFP transgenic line as a new tool to visualize and study the Ret signaling pathway from early development through adulthood.