Investigation of Enteric Nervous System Regeneration in Zebrafish Using a Cell Ablation System with Spatio-Temporal Control

This project aims to determine the regenerative capacity of the enteric nervous system (ENS) and identify the cellular and molecular mechanisms that control ENS regeneration. The ENS provides the intrinsic innervation of the gastrointestinal (GI) tract and controls all essential gut functions including motility. Deficits in ENS

neuron abundance are associated with a wide range of disorders characterized by GI dysfunction, debilitating symptoms, and reduced quality of life. To date, ENS disorders can only be treated symptomatically or by surgical removal of the affected area. A promising avenue to treat lost ENS cells is to stimulate local stem cells

to regenerate missing ENS neurons. However, there is a significant gap in knowledge regarding the signals and cell lineages necessary for successful ENS regeneration. To address this knowledge gap, we need to establish an experimentally tractable animal model system that displays robust ENS regeneration including

recovery of gut functions. In mammals, the ENS only partially reinnervates and recovers neurons after injury. Unlike mammals, the zebrafish ENS regenerates ENS injury after focal ablation of a small number of ENS neurons. However, whether zebrafish can repair extensive ENS injuries in all parts of the gut, and the extent of

functional recovery following regeneration is not known. Furthermore, we know very little about the molecular cues, cell biological processes, and cell lineage composition that underlie ENS regeneration. Thus, there is a critical need to establish the cellular and molecular mechanisms as well as the cell lineage decisions that

guide ENS regeneration in zebrafish. Establishing an animal model system of robust ENS regeneration will pave the way for our long-term goal to identify the genes and gene regulatory networks necessary and sufficient for successful ENS regeneration. This proposal tests the central hypothesis that the zebrafish gut

environment allows enteric stem cell activation to generate lost ENS neurons in two Aims: (1) establish the regenerative ability of the zebrafish ENS; (2) identify cell populations, spatio-temporal gene expression dynamics, and cell lineages that drive neuronal regeneration after cell ablation. Aim 1 utilizes a genetic-

chemical ablation system for precise spatio-temporal control of cell loss and high-resolution whole-gut imaging to analyze functional recovery. Aim 2 uses single-cell RNA-seq (scRNA-seq) to identify the cellular and molecular profiles of the cell types and lineages that drive the regenerative response. This proposal is

innovative, as it will capitalize on the precision of the genetic-chemical cell ablation system and the exceptional cellular and molecular resolution of scRNA-seq to establish an animal model system of robust ENS regeneration and thereby open new horizons for the study of nervous system regeneration. This work is

significant, as it will provide the necessary foundation for understanding which molecular cues and cellular responses promote ENS regeneration and how such factors can be applied to enhance human ENS regeneration to treat neurological diseases of the gut.