Zebrafish neural regeneration: mechanistic insights into human nervous system repair.

Abstract

The zebrafish (Danio rerio) is a powerful vertebrate model for studying neurodegenerative diseases and regenerative medicine due to its genetic similarity to humans and its unique ability to regenerate the central nervous system (CNS). This review synthesizes key findings on zebrafish neural regeneration across the retina, spinal cord, and brain, emphasizing translational relevance. Zebrafish effectively model disorders such as Alzheimer's, Parkinson's, amyotrophic lateral sclerosis, stroke, epilepsy, autism spectrum disorders, and CNS injuries. Unlike mammals, they restore damaged axons and recover function through a permissive extracellular matrix, transient inflammation, and glial plasticity. In the retina, Müller glia reprograms after injury to generate progenitors that replace lost neurons, regulated by Wnt/β-catenin, Shh, EGF, Hippo/YAP, and ROCK signaling. In the spinal cord, ependymo-radial glia forms a laminin- and fibronectin-rich "glial bridge," guided by FGF and CTGF signaling, supporting axon regrowth. In the brain, GFAP- and Olig2-positive radial glia drive neurogenesis within ventricular niches, integrating new neurons while maintaining circuit integrity. Regeneration involves transient Notch suppression, context-specific Wnt and FGF activation, and immune modulation without fibrosis. Advances in single-cell RNA sequencing, CRISPR-Cas9, lineage tracing, and multi-omics have identified injury-induced progenitor states, regulators (ascl1a, lin28, sox2, stat3), and epigenetic programs enabling regeneration. Emerging research on bioelectric signaling, microbiota-brain interactions, and lipid mediators further expands systemic understanding. Overall, zebrafish provide a unified model for decoding vertebrate CNS regeneration and guiding therapeutic strategies to restore neural repair in humans.